phy.c source code [Linux/drivers/net/ethernet/intel/e1000e/phy.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/ Copyright(c) 1999 - 2018 Intel Corporation. /
3
4	#include "e1000.h"
5	#include <linux/ethtool.h>
6
7	static s32 e1000_wait_autoneg(struct e1000_hw *hw);
8	static s32 e1000_access_phy_wakeup_reg_bm(struct e1000_hw *hw, u32 offset,
9	u16 *data, bool read, bool page_set);
10	static u32 e1000_get_phy_addr_for_hv_page(u32 page);
11	static s32 e1000_access_phy_debug_regs_hv(struct e1000_hw *hw, u32 offset,
12	u16 *data, bool read);
13
14	/ Cable length tables /
15	static const u16 e1000_m88_cable_length_table[] = {
16	`0`, `50`, `80`, `110`, `140`, `140`, E1000_CABLE_LENGTH_UNDEFINED
17	};
18
19	#define M88E1000_CABLE_LENGTH_TABLE_SIZE \
20	ARRAY_SIZE(e1000_m88_cable_length_table)
21
22	static const u16 e1000_igp_2_cable_length_table[] = {
23	`0`, `0`, `0`, `0`, `0`, `0`, `0`, `0`, `3`, `5`, `8`, `11`, `13`, `16`, `18`, `21`, `0`, `0`, `0`, `3`,
24	`6`, `10`, `13`, `16`, `19`, `23`, `26`, `29`, `32`, `35`, `38`, `41`, `6`, `10`, `14`, `18`, `22`,
25	`26`, `30`, `33`, `37`, `41`, `44`, `48`, `51`, `54`, `58`, `61`, `21`, `26`, `31`, `35`, `40`,
26	`44`, `49`, `53`, `57`, `61`, `65`, `68`, `72`, `75`, `79`, `82`, `40`, `45`, `51`, `56`, `61`,
27	`66`, `70`, `75`, `79`, `83`, `87`, `91`, `94`, `98`, `101`, `104`, `60`, `66`, `72`, `77`, `82`,
28	`87`, `92`, `96`, `100`, `104`, `108`, `111`, `114`, `117`, `119`, `121`, `83`, `89`, `95`,
29	`100`, `105`, `109`, `113`, `116`, `119`, `122`, `124`, `104`, `109`, `114`, `118`, `121`,
30	`124`
31	};
32
33	#define IGP02E1000_CABLE_LENGTH_TABLE_SIZE \
34	ARRAY_SIZE(e1000_igp_2_cable_length_table)
35
36	/**
37	* e1000e_check_reset_block_generic - Check if PHY reset is blocked
38	* @hw: pointer to the HW structure
39	*
40	* Read the PHY management control register and check whether a PHY reset
41	* is blocked. If a reset is not blocked return 0, otherwise
42	* return E1000_BLK_PHY_RESET (12).
43	**/
44	s32 e1000e_check_reset_block_generic(struct e1000_hw *hw)
45	{
46	u32 manc;
47
48	manc = er32(MANC);
49
50	return (manc & E1000_MANC_BLK_PHY_RST_ON_IDE) ? E1000_BLK_PHY_RESET : `0`;
51	}
52
53	/**
54	* e1000e_get_phy_id - Retrieve the PHY ID and revision
55	* @hw: pointer to the HW structure
56	*
57	* Reads the PHY registers and stores the PHY ID and possibly the PHY
58	* revision in the hardware structure.
59	**/
60	s32 e1000e_get_phy_id(struct e1000_hw *hw)
61	{
62	struct e1000_phy_info *phy = &hw->phy;
63	s32 ret_val = `0`;
64	u16 phy_id;
65	u16 retry_count = `0`;
66
67	if (!phy->ops.read_reg)
68	return `0`;
69
70	while (retry_count < `2`) {
71	ret_val = e1e_rphy(hw, MII_PHYSID1, data: &phy_id);
72	if (ret_val)
73	return ret_val;
74
75	phy->id = (u32)(phy_id << `16`);
76	usleep_range(min: `20`, max: `40`);
77	ret_val = e1e_rphy(hw, MII_PHYSID2, data: &phy_id);
78	if (ret_val)
79	return ret_val;
80
81	phy->id \|= (u32)(phy_id & PHY_REVISION_MASK);
82	phy->revision = (u32)(phy_id & ~PHY_REVISION_MASK);
83
84	if (phy->id != `0` && phy->id != PHY_REVISION_MASK)
85	return `0`;
86
87	retry_count++;
88	}
89
90	return `0`;
91	}
92
93	/**
94	* e1000e_phy_reset_dsp - Reset PHY DSP
95	* @hw: pointer to the HW structure
96	*
97	* Reset the digital signal processor.
98	**/
99	s32 e1000e_phy_reset_dsp(struct e1000_hw *hw)
100	{
101	s32 ret_val;
102
103	ret_val = e1e_wphy(hw, M88E1000_PHY_GEN_CONTROL, data: `0xC1`);
104	if (ret_val)
105	return ret_val;
106
107	return e1e_wphy(hw, M88E1000_PHY_GEN_CONTROL, data: `0`);
108	}
109
110	void e1000e_disable_phy_retry(struct e1000_hw *hw)
111	{
112	hw->phy.retry_enabled = false;
113	}
114
115	void e1000e_enable_phy_retry(struct e1000_hw *hw)
116	{
117	hw->phy.retry_enabled = true;
118	}
119
120	/**
121	* e1000e_read_phy_reg_mdic - Read MDI control register
122	* @hw: pointer to the HW structure
123	* @offset: register offset to be read
124	* @data: pointer to the read data
125	*
126	* Reads the MDI control register in the PHY at offset and stores the
127	* information read to data.
128	**/
129	s32 e1000e_read_phy_reg_mdic(struct e1000_hw hw, u32 offset, u16 data)
130	{
131	u32 i, mdic = `0`, retry_counter, retry_max;
132	struct e1000_phy_info *phy = &hw->phy;
133	bool success;
134
135	if (offset > MAX_PHY_REG_ADDRESS) {
136	e_dbg("PHY Address %d is out of range\n", offset);
137	return -E1000_ERR_PARAM;
138	}
139
140	retry_max = phy->retry_enabled ? phy->retry_count : `0`;
141
142	/ Set up Op-code, Phy Address, and register offset in the MDI*
143	* Control register. The MAC will take care of interfacing with the
144	* PHY to retrieve the desired data.
145	*/
146	for (retry_counter = `0`; retry_counter <= retry_max; retry_counter++) {
147	success = true;
148
149	mdic = ((offset << E1000_MDIC_REG_SHIFT) \|
150	(phy->addr << E1000_MDIC_PHY_SHIFT) \|
151	(E1000_MDIC_OP_READ));
152
153	ew32(MDIC, mdic);
154
155	/ Poll the ready bit to see if the MDI read completed*
156	* Increasing the time out as testing showed failures with
157	* the lower time out
158	*/
159	for (i = `0`; i < (E1000_GEN_POLL_TIMEOUT * `3`); i++) {
160	udelay(usec: `50`);
161	mdic = er32(MDIC);
162	if (mdic & E1000_MDIC_READY)
163	break;
164	}
165	if (!(mdic & E1000_MDIC_READY)) {
166	e_dbg("MDI Read PHY Reg Address %d did not complete\n",
167	offset);
168	success = false;
169	}
170	if (mdic & E1000_MDIC_ERROR) {
171	e_dbg("MDI Read PHY Reg Address %d Error\n", offset);
172	success = false;
173	}
174	if (FIELD_GET(E1000_MDIC_REG_MASK, mdic) != offset) {
175	e_dbg("MDI Read offset error - requested %d, returned %d\n",
176	offset, FIELD_GET(E1000_MDIC_REG_MASK, mdic));
177	success = false;
178	}
179
180	/ Allow some time after each MDIC transaction to avoid*
181	* reading duplicate data in the next MDIC transaction.
182	*/
183	if (hw->mac.type == e1000_pch2lan)
184	udelay(usec: `100`);
185
186	if (success) {
187	*data = (u16)mdic;
188	return `0`;
189	}
190
191	if (retry_counter != retry_max) {
192	e_dbg("Perform retry on PHY transaction...\n");
193	mdelay(`10`);
194	}
195	}
196
197	return -E1000_ERR_PHY;
198	}
199
200	/**
201	* e1000e_write_phy_reg_mdic - Write MDI control register
202	* @hw: pointer to the HW structure
203	* @offset: register offset to write to
204	* @data: data to write to register at offset
205	*
206	* Writes data to MDI control register in the PHY at offset.
207	**/
208	s32 e1000e_write_phy_reg_mdic(struct e1000_hw *hw, u32 offset, u16 data)
209	{
210	u32 i, mdic = `0`, retry_counter, retry_max;
211	struct e1000_phy_info *phy = &hw->phy;
212	bool success;
213
214	if (offset > MAX_PHY_REG_ADDRESS) {
215	e_dbg("PHY Address %d is out of range\n", offset);
216	return -E1000_ERR_PARAM;
217	}
218
219	retry_max = phy->retry_enabled ? phy->retry_count : `0`;
220
221	/ Set up Op-code, Phy Address, and register offset in the MDI*
222	* Control register. The MAC will take care of interfacing with the
223	* PHY to retrieve the desired data.
224	*/
225	for (retry_counter = `0`; retry_counter <= retry_max; retry_counter++) {
226	success = true;
227
228	mdic = (((u32)data) \|
229	(offset << E1000_MDIC_REG_SHIFT) \|
230	(phy->addr << E1000_MDIC_PHY_SHIFT) \|
231	(E1000_MDIC_OP_WRITE));
232
233	ew32(MDIC, mdic);
234
235	/ Poll the ready bit to see if the MDI read completed*
236	* Increasing the time out as testing showed failures with
237	* the lower time out
238	*/
239	for (i = `0`; i < (E1000_GEN_POLL_TIMEOUT * `3`); i++) {
240	udelay(usec: `50`);
241	mdic = er32(MDIC);
242	if (mdic & E1000_MDIC_READY)
243	break;
244	}
245	if (!(mdic & E1000_MDIC_READY)) {
246	e_dbg("MDI Write PHY Reg Address %d did not complete\n",
247	offset);
248	success = false;
249	}
250	if (mdic & E1000_MDIC_ERROR) {
251	e_dbg("MDI Write PHY Reg Address %d Error\n", offset);
252	success = false;
253	}
254	if (FIELD_GET(E1000_MDIC_REG_MASK, mdic) != offset) {
255	e_dbg("MDI Write offset error - requested %d, returned %d\n",
256	offset, FIELD_GET(E1000_MDIC_REG_MASK, mdic));
257	success = false;
258	}
259
260	/ Allow some time after each MDIC transaction to avoid*
261	* reading duplicate data in the next MDIC transaction.
262	*/
263	if (hw->mac.type == e1000_pch2lan)
264	udelay(usec: `100`);
265
266	if (success)
267	return `0`;
268
269	if (retry_counter != retry_max) {
270	e_dbg("Perform retry on PHY transaction...\n");
271	mdelay(`10`);
272	}
273	}
274
275	return -E1000_ERR_PHY;
276	}
277
278	/**
279	* e1000e_read_phy_reg_m88 - Read m88 PHY register
280	* @hw: pointer to the HW structure
281	* @offset: register offset to be read
282	* @data: pointer to the read data
283	*
284	* Acquires semaphore, if necessary, then reads the PHY register at offset
285	* and storing the retrieved information in data. Release any acquired
286	* semaphores before exiting.
287	**/
288	s32 e1000e_read_phy_reg_m88(struct e1000_hw hw, u32 offset, u16 data)
289	{
290	s32 ret_val;
291
292	ret_val = hw->phy.ops.acquire(hw);
293	if (ret_val)
294	return ret_val;
295
296	ret_val = e1000e_read_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
297	data);
298
299	hw->phy.ops.release(hw);
300
301	return ret_val;
302	}
303
304	/**
305	* e1000e_write_phy_reg_m88 - Write m88 PHY register
306	* @hw: pointer to the HW structure
307	* @offset: register offset to write to
308	* @data: data to write at register offset
309	*
310	* Acquires semaphore, if necessary, then writes the data to PHY register
311	* at the offset. Release any acquired semaphores before exiting.
312	**/
313	s32 e1000e_write_phy_reg_m88(struct e1000_hw *hw, u32 offset, u16 data)
314	{
315	s32 ret_val;
316
317	ret_val = hw->phy.ops.acquire(hw);
318	if (ret_val)
319	return ret_val;
320
321	ret_val = e1000e_write_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
322	data);
323
324	hw->phy.ops.release(hw);
325
326	return ret_val;
327	}
328
329	/**
330	* e1000_set_page_igp - Set page as on IGP-like PHY(s)
331	* @hw: pointer to the HW structure
332	* @page: page to set (shifted left when necessary)
333	*
334	* Sets PHY page required for PHY register access. Assumes semaphore is
335	* already acquired. Note, this function sets phy.addr to 1 so the caller
336	* must set it appropriately (if necessary) after this function returns.
337	**/
338	s32 e1000_set_page_igp(struct e1000_hw *hw, u16 page)
339	{
340	e_dbg("Setting page 0x%x\n", page);
341
342	hw->phy.addr = `1`;
343
344	return e1000e_write_phy_reg_mdic(hw, IGP01E1000_PHY_PAGE_SELECT, data: page);
345	}
346
347	/**
348	* __e1000e_read_phy_reg_igp - Read igp PHY register
349	* @hw: pointer to the HW structure
350	* @offset: register offset to be read
351	* @data: pointer to the read data
352	* @locked: semaphore has already been acquired or not
353	*
354	* Acquires semaphore, if necessary, then reads the PHY register at offset
355	* and stores the retrieved information in data. Release any acquired
356	* semaphores before exiting.
357	**/
358	static s32 __e1000e_read_phy_reg_igp(struct e1000_hw hw, u32 offset, u16 data,
359	bool locked)
360	{
361	s32 ret_val = `0`;
362
363	if (!locked) {
364	if (!hw->phy.ops.acquire)
365	return `0`;
366
367	ret_val = hw->phy.ops.acquire(hw);
368	if (ret_val)
369	return ret_val;
370	}
371
372	if (offset > MAX_PHY_MULTI_PAGE_REG)
373	ret_val = e1000e_write_phy_reg_mdic(hw,
374	IGP01E1000_PHY_PAGE_SELECT,
375	data: (u16)offset);
376	if (!ret_val)
377	ret_val = e1000e_read_phy_reg_mdic(hw,
378	MAX_PHY_REG_ADDRESS & offset,
379	data);
380	if (!locked)
381	hw->phy.ops.release(hw);
382
383	return ret_val;
384	}
385
386	/**
387	* e1000e_read_phy_reg_igp - Read igp PHY register
388	* @hw: pointer to the HW structure
389	* @offset: register offset to be read
390	* @data: pointer to the read data
391	*
392	* Acquires semaphore then reads the PHY register at offset and stores the
393	* retrieved information in data.
394	* Release the acquired semaphore before exiting.
395	**/
396	s32 e1000e_read_phy_reg_igp(struct e1000_hw hw, u32 offset, u16 data)
397	{
398	return __e1000e_read_phy_reg_igp(hw, offset, data, locked: false);
399	}
400
401	/**
402	* e1000e_read_phy_reg_igp_locked - Read igp PHY register
403	* @hw: pointer to the HW structure
404	* @offset: register offset to be read
405	* @data: pointer to the read data
406	*
407	* Reads the PHY register at offset and stores the retrieved information
408	* in data. Assumes semaphore already acquired.
409	**/
410	s32 e1000e_read_phy_reg_igp_locked(struct e1000_hw hw, u32 offset, u16 data)
411	{
412	return __e1000e_read_phy_reg_igp(hw, offset, data, locked: true);
413	}
414
415	/**
416	* __e1000e_write_phy_reg_igp - Write igp PHY register
417	* @hw: pointer to the HW structure
418	* @offset: register offset to write to
419	* @data: data to write at register offset
420	* @locked: semaphore has already been acquired or not
421	*
422	* Acquires semaphore, if necessary, then writes the data to PHY register
423	* at the offset. Release any acquired semaphores before exiting.
424	**/
425	static s32 __e1000e_write_phy_reg_igp(struct e1000_hw *hw, u32 offset, u16 data,
426	bool locked)
427	{
428	s32 ret_val = `0`;
429
430	if (!locked) {
431	if (!hw->phy.ops.acquire)
432	return `0`;
433
434	ret_val = hw->phy.ops.acquire(hw);
435	if (ret_val)
436	return ret_val;
437	}
438
439	if (offset > MAX_PHY_MULTI_PAGE_REG)
440	ret_val = e1000e_write_phy_reg_mdic(hw,
441	IGP01E1000_PHY_PAGE_SELECT,
442	data: (u16)offset);
443	if (!ret_val)
444	ret_val = e1000e_write_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS &
445	offset, data);
446	if (!locked)
447	hw->phy.ops.release(hw);
448
449	return ret_val;
450	}
451
452	/**
453	* e1000e_write_phy_reg_igp - Write igp PHY register
454	* @hw: pointer to the HW structure
455	* @offset: register offset to write to
456	* @data: data to write at register offset
457	*
458	* Acquires semaphore then writes the data to PHY register
459	* at the offset. Release any acquired semaphores before exiting.
460	**/
461	s32 e1000e_write_phy_reg_igp(struct e1000_hw *hw, u32 offset, u16 data)
462	{
463	return __e1000e_write_phy_reg_igp(hw, offset, data, locked: false);
464	}
465
466	/**
467	* e1000e_write_phy_reg_igp_locked - Write igp PHY register
468	* @hw: pointer to the HW structure
469	* @offset: register offset to write to
470	* @data: data to write at register offset
471	*
472	* Writes the data to PHY register at the offset.
473	* Assumes semaphore already acquired.
474	**/
475	s32 e1000e_write_phy_reg_igp_locked(struct e1000_hw *hw, u32 offset, u16 data)
476	{
477	return __e1000e_write_phy_reg_igp(hw, offset, data, locked: true);
478	}
479
480	/**
481	* __e1000_read_kmrn_reg - Read kumeran register
482	* @hw: pointer to the HW structure
483	* @offset: register offset to be read
484	* @data: pointer to the read data
485	* @locked: semaphore has already been acquired or not
486	*
487	* Acquires semaphore, if necessary. Then reads the PHY register at offset
488	* using the kumeran interface. The information retrieved is stored in data.
489	* Release any acquired semaphores before exiting.
490	**/
491	static s32 __e1000_read_kmrn_reg(struct e1000_hw hw, u32 offset, u16 data,
492	bool locked)
493	{
494	u32 kmrnctrlsta;
495
496	if (!locked) {
497	s32 ret_val = `0`;
498
499	if (!hw->phy.ops.acquire)
500	return `0`;
501
502	ret_val = hw->phy.ops.acquire(hw);
503	if (ret_val)
504	return ret_val;
505	}
506
507	kmrnctrlsta = FIELD_PREP(E1000_KMRNCTRLSTA_OFFSET, offset) \|
508	E1000_KMRNCTRLSTA_REN;
509	ew32(KMRNCTRLSTA, kmrnctrlsta);
510	e1e_flush();
511
512	udelay(usec: `2`);
513
514	kmrnctrlsta = er32(KMRNCTRLSTA);
515	*data = (u16)kmrnctrlsta;
516
517	if (!locked)
518	hw->phy.ops.release(hw);
519
520	return `0`;
521	}
522
523	/**
524	* e1000e_read_kmrn_reg - Read kumeran register
525	* @hw: pointer to the HW structure
526	* @offset: register offset to be read
527	* @data: pointer to the read data
528	*
529	* Acquires semaphore then reads the PHY register at offset using the
530	* kumeran interface. The information retrieved is stored in data.
531	* Release the acquired semaphore before exiting.
532	**/
533	s32 e1000e_read_kmrn_reg(struct e1000_hw hw, u32 offset, u16 data)
534	{
535	return __e1000_read_kmrn_reg(hw, offset, data, locked: false);
536	}
537
538	/**
539	* e1000e_read_kmrn_reg_locked - Read kumeran register
540	* @hw: pointer to the HW structure
541	* @offset: register offset to be read
542	* @data: pointer to the read data
543	*
544	* Reads the PHY register at offset using the kumeran interface. The
545	* information retrieved is stored in data.
546	* Assumes semaphore already acquired.
547	**/
548	s32 e1000e_read_kmrn_reg_locked(struct e1000_hw hw, u32 offset, u16 data)
549	{
550	return __e1000_read_kmrn_reg(hw, offset, data, locked: true);
551	}
552
553	/**
554	* __e1000_write_kmrn_reg - Write kumeran register
555	* @hw: pointer to the HW structure
556	* @offset: register offset to write to
557	* @data: data to write at register offset
558	* @locked: semaphore has already been acquired or not
559	*
560	* Acquires semaphore, if necessary. Then write the data to PHY register
561	* at the offset using the kumeran interface. Release any acquired semaphores
562	* before exiting.
563	**/
564	static s32 __e1000_write_kmrn_reg(struct e1000_hw *hw, u32 offset, u16 data,
565	bool locked)
566	{
567	u32 kmrnctrlsta;
568
569	if (!locked) {
570	s32 ret_val = `0`;
571
572	if (!hw->phy.ops.acquire)
573	return `0`;
574
575	ret_val = hw->phy.ops.acquire(hw);
576	if (ret_val)
577	return ret_val;
578	}
579
580	kmrnctrlsta = FIELD_PREP(E1000_KMRNCTRLSTA_OFFSET, offset) \| data;
581	ew32(KMRNCTRLSTA, kmrnctrlsta);
582	e1e_flush();
583
584	udelay(usec: `2`);
585
586	if (!locked)
587	hw->phy.ops.release(hw);
588
589	return `0`;
590	}
591
592	/**
593	* e1000e_write_kmrn_reg - Write kumeran register
594	* @hw: pointer to the HW structure
595	* @offset: register offset to write to
596	* @data: data to write at register offset
597	*
598	* Acquires semaphore then writes the data to the PHY register at the offset
599	* using the kumeran interface. Release the acquired semaphore before exiting.
600	**/
601	s32 e1000e_write_kmrn_reg(struct e1000_hw *hw, u32 offset, u16 data)
602	{
603	return __e1000_write_kmrn_reg(hw, offset, data, locked: false);
604	}
605
606	/**
607	* e1000e_write_kmrn_reg_locked - Write kumeran register
608	* @hw: pointer to the HW structure
609	* @offset: register offset to write to
610	* @data: data to write at register offset
611	*
612	* Write the data to PHY register at the offset using the kumeran interface.
613	* Assumes semaphore already acquired.
614	**/
615	s32 e1000e_write_kmrn_reg_locked(struct e1000_hw *hw, u32 offset, u16 data)
616	{
617	return __e1000_write_kmrn_reg(hw, offset, data, locked: true);
618	}
619
620	/**
621	* e1000_set_master_slave_mode - Setup PHY for Master/slave mode
622	* @hw: pointer to the HW structure
623	*
624	* Sets up Master/slave mode
625	**/
626	static s32 e1000_set_master_slave_mode(struct e1000_hw *hw)
627	{
628	s32 ret_val;
629	u16 phy_data;
630
631	/ Resolve Master/Slave mode /
632	ret_val = e1e_rphy(hw, MII_CTRL1000, data: &phy_data);
633	if (ret_val)
634	return ret_val;
635
636	/ load defaults for future use /
637	hw->phy.original_ms_type = (phy_data & CTL1000_ENABLE_MASTER) ?
638	((phy_data & CTL1000_AS_MASTER) ?
639	e1000_ms_force_master : e1000_ms_force_slave) : e1000_ms_auto;
640
641	switch (hw->phy.ms_type) {
642	case e1000_ms_force_master:
643	phy_data \|= (CTL1000_ENABLE_MASTER \| CTL1000_AS_MASTER);
644	break;
645	case e1000_ms_force_slave:
646	phy_data \|= CTL1000_ENABLE_MASTER;
647	phy_data &= ~(CTL1000_AS_MASTER);
648	break;
649	case e1000_ms_auto:
650	phy_data &= ~CTL1000_ENABLE_MASTER;
651	fallthrough;
652	default:
653	break;
654	}
655
656	return e1e_wphy(hw, MII_CTRL1000, data: phy_data);
657	}
658
659	/**
660	* e1000_copper_link_setup_82577 - Setup 82577 PHY for copper link
661	* @hw: pointer to the HW structure
662	*
663	* Sets up Carrier-sense on Transmit and downshift values.
664	**/
665	s32 e1000_copper_link_setup_82577(struct e1000_hw *hw)
666	{
667	s32 ret_val;
668	u16 phy_data;
669
670	/ Enable CRS on Tx. This must be set for half-duplex operation. /
671	ret_val = e1e_rphy(hw, I82577_CFG_REG, data: &phy_data);
672	if (ret_val)
673	return ret_val;
674
675	phy_data \|= I82577_CFG_ASSERT_CRS_ON_TX;
676
677	/ Enable downshift /
678	phy_data \|= I82577_CFG_ENABLE_DOWNSHIFT;
679
680	ret_val = e1e_wphy(hw, I82577_CFG_REG, data: phy_data);
681	if (ret_val)
682	return ret_val;
683
684	/ Set MDI/MDIX mode /
685	ret_val = e1e_rphy(hw, I82577_PHY_CTRL_2, data: &phy_data);
686	if (ret_val)
687	return ret_val;
688	phy_data &= ~I82577_PHY_CTRL2_MDIX_CFG_MASK;
689	/ Options:*
690	* 0 - Auto (default)
691	* 1 - MDI mode
692	* 2 - MDI-X mode
693	*/
694	switch (hw->phy.mdix) {
695	case `1`:
696	break;
697	case `2`:
698	phy_data \|= I82577_PHY_CTRL2_MANUAL_MDIX;
699	break;
700	case `0`:
701	default:
702	phy_data \|= I82577_PHY_CTRL2_AUTO_MDI_MDIX;
703	break;
704	}
705	ret_val = e1e_wphy(hw, I82577_PHY_CTRL_2, data: phy_data);
706	if (ret_val)
707	return ret_val;
708
709	return e1000_set_master_slave_mode(hw);
710	}
711
712	/**
713	* e1000e_copper_link_setup_m88 - Setup m88 PHY's for copper link
714	* @hw: pointer to the HW structure
715	*
716	* Sets up MDI/MDI-X and polarity for m88 PHY's. If necessary, transmit clock
717	* and downshift values are set also.
718	**/
719	s32 e1000e_copper_link_setup_m88(struct e1000_hw *hw)
720	{
721	struct e1000_phy_info *phy = &hw->phy;
722	s32 ret_val;
723	u16 phy_data;
724
725	/ Enable CRS on Tx. This must be set for half-duplex operation. /
726	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_CTRL, data: &phy_data);
727	if (ret_val)
728	return ret_val;
729
730	/ For BM PHY this bit is downshift enable /
731	if (phy->type != e1000_phy_bm)
732	phy_data \|= M88E1000_PSCR_ASSERT_CRS_ON_TX;
733
734	/ Options:*
735	* MDI/MDI-X = 0 (default)
736	* 0 - Auto for all speeds
737	* 1 - MDI mode
738	* 2 - MDI-X mode
739	* 3 - Auto for 1000Base-T only (MDI-X for 10/100Base-T modes)
740	*/
741	phy_data &= ~M88E1000_PSCR_AUTO_X_MODE;
742
743	switch (phy->mdix) {
744	case `1`:
745	phy_data \|= M88E1000_PSCR_MDI_MANUAL_MODE;
746	break;
747	case `2`:
748	phy_data \|= M88E1000_PSCR_MDIX_MANUAL_MODE;
749	break;
750	case `3`:
751	phy_data \|= M88E1000_PSCR_AUTO_X_1000T;
752	break;
753	case `0`:
754	default:
755	phy_data \|= M88E1000_PSCR_AUTO_X_MODE;
756	break;
757	}
758
759	/ Options:*
760	* disable_polarity_correction = 0 (default)
761	* Automatic Correction for Reversed Cable Polarity
762	* 0 - Disabled
763	* 1 - Enabled
764	*/
765	phy_data &= ~M88E1000_PSCR_POLARITY_REVERSAL;
766	if (phy->disable_polarity_correction)
767	phy_data \|= M88E1000_PSCR_POLARITY_REVERSAL;
768
769	/ Enable downshift on BM (disabled by default) /
770	if (phy->type == e1000_phy_bm) {
771	/ For 82574/82583, first disable then enable downshift /
772	if (phy->id == BME1000_E_PHY_ID_R2) {
773	phy_data &= ~BME1000_PSCR_ENABLE_DOWNSHIFT;
774	ret_val = e1e_wphy(hw, M88E1000_PHY_SPEC_CTRL,
775	data: phy_data);
776	if (ret_val)
777	return ret_val;
778	/ Commit the changes. /
779	ret_val = phy->ops.commit(hw);
780	if (ret_val) {
781	e_dbg("Error committing the PHY changes\n");
782	return ret_val;
783	}
784	}
785
786	phy_data \|= BME1000_PSCR_ENABLE_DOWNSHIFT;
787	}
788
789	ret_val = e1e_wphy(hw, M88E1000_PHY_SPEC_CTRL, data: phy_data);
790	if (ret_val)
791	return ret_val;
792
793	if ((phy->type == e1000_phy_m88) &&
794	(phy->revision < E1000_REVISION_4) &&
795	(phy->id != BME1000_E_PHY_ID_R2)) {
796	/ Force TX_CLK in the Extended PHY Specific Control Register*
797	* to 25MHz clock.
798	*/
799	ret_val = e1e_rphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: &phy_data);
800	if (ret_val)
801	return ret_val;
802
803	phy_data \|= M88E1000_EPSCR_TX_CLK_25;
804
805	if ((phy->revision == `2`) && (phy->id == M88E1111_I_PHY_ID)) {
806	/ 82573L PHY - set the downshift counter to 5x. /
807	phy_data &= ~M88EC018_EPSCR_DOWNSHIFT_COUNTER_MASK;
808	phy_data \|= M88EC018_EPSCR_DOWNSHIFT_COUNTER_5X;
809	} else {
810	/ Configure Master and Slave downshift values /
811	phy_data &= ~(M88E1000_EPSCR_MASTER_DOWNSHIFT_MASK \|
812	M88E1000_EPSCR_SLAVE_DOWNSHIFT_MASK);
813	phy_data \|= (M88E1000_EPSCR_MASTER_DOWNSHIFT_1X \|
814	M88E1000_EPSCR_SLAVE_DOWNSHIFT_1X);
815	}
816	ret_val = e1e_wphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: phy_data);
817	if (ret_val)
818	return ret_val;
819	}
820
821	if ((phy->type == e1000_phy_bm) && (phy->id == BME1000_E_PHY_ID_R2)) {
822	/ Set PHY page 0, register 29 to 0x0003 /
823	ret_val = e1e_wphy(hw, offset: `29`, data: `0x0003`);
824	if (ret_val)
825	return ret_val;
826
827	/ Set PHY page 0, register 30 to 0x0000 /
828	ret_val = e1e_wphy(hw, offset: `30`, data: `0x0000`);
829	if (ret_val)
830	return ret_val;
831	}
832
833	/ Commit the changes. /
834	if (phy->ops.commit) {
835	ret_val = phy->ops.commit(hw);
836	if (ret_val) {
837	e_dbg("Error committing the PHY changes\n");
838	return ret_val;
839	}
840	}
841
842	if (phy->type == e1000_phy_82578) {
843	ret_val = e1e_rphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: &phy_data);
844	if (ret_val)
845	return ret_val;
846
847	/ 82578 PHY - set the downshift count to 1x. /
848	phy_data \|= I82578_EPSCR_DOWNSHIFT_ENABLE;
849	phy_data &= ~I82578_EPSCR_DOWNSHIFT_COUNTER_MASK;
850	ret_val = e1e_wphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: phy_data);
851	if (ret_val)
852	return ret_val;
853	}
854
855	return `0`;
856	}
857
858	/**
859	* e1000e_copper_link_setup_igp - Setup igp PHY's for copper link
860	* @hw: pointer to the HW structure
861	*
862	* Sets up LPLU, MDI/MDI-X, polarity, Smartspeed and Master/Slave config for
863	* igp PHY's.
864	**/
865	s32 e1000e_copper_link_setup_igp(struct e1000_hw *hw)
866	{
867	struct e1000_phy_info *phy = &hw->phy;
868	s32 ret_val;
869	u16 data;
870
871	ret_val = e1000_phy_hw_reset(hw);
872	if (ret_val) {
873	e_dbg("Error resetting the PHY.\n");
874	return ret_val;
875	}
876
877	/ Wait 100ms for MAC to configure PHY from NVM settings, to avoid*
878	* timeout issues when LFS is enabled.
879	*/
880	msleep(msecs: `100`);
881
882	/ disable lplu d0 during driver init /
883	if (hw->phy.ops.set_d0_lplu_state) {
884	ret_val = hw->phy.ops.set_d0_lplu_state(hw, false);
885	if (ret_val) {
886	e_dbg("Error Disabling LPLU D0\n");
887	return ret_val;
888	}
889	}
890	/ Configure mdi-mdix settings /
891	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CTRL, data: &data);
892	if (ret_val)
893	return ret_val;
894
895	data &= ~IGP01E1000_PSCR_AUTO_MDIX;
896
897	switch (phy->mdix) {
898	case `1`:
899	data &= ~IGP01E1000_PSCR_FORCE_MDI_MDIX;
900	break;
901	case `2`:
902	data \|= IGP01E1000_PSCR_FORCE_MDI_MDIX;
903	break;
904	case `0`:
905	default:
906	data \|= IGP01E1000_PSCR_AUTO_MDIX;
907	break;
908	}
909	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CTRL, data);
910	if (ret_val)
911	return ret_val;
912
913	/ set auto-master slave resolution settings /
914	if (hw->mac.autoneg) {
915	/ when autonegotiation advertisement is only 1000Mbps then we*
916	* should disable SmartSpeed and enable Auto MasterSlave
917	* resolution as hardware default.
918	*/
919	if (phy->autoneg_advertised == ADVERTISE_1000_FULL) {
920	/ Disable SmartSpeed /
921	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CONFIG,
922	data: &data);
923	if (ret_val)
924	return ret_val;
925
926	data &= ~IGP01E1000_PSCFR_SMART_SPEED;
927	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CONFIG,
928	data);
929	if (ret_val)
930	return ret_val;
931
932	/ Set auto Master/Slave resolution process /
933	ret_val = e1e_rphy(hw, MII_CTRL1000, data: &data);
934	if (ret_val)
935	return ret_val;
936
937	data &= ~CTL1000_ENABLE_MASTER;
938	ret_val = e1e_wphy(hw, MII_CTRL1000, data);
939	if (ret_val)
940	return ret_val;
941	}
942
943	ret_val = e1000_set_master_slave_mode(hw);
944	}
945
946	return ret_val;
947	}
948
949	/**
950	* e1000_phy_setup_autoneg - Configure PHY for auto-negotiation
951	* @hw: pointer to the HW structure
952	*
953	* Reads the MII auto-neg advertisement register and/or the 1000T control
954	* register and if the PHY is already setup for auto-negotiation, then
955	* return successful. Otherwise, setup advertisement and flow control to
956	* the appropriate values for the wanted auto-negotiation.
957	**/
958	static s32 e1000_phy_setup_autoneg(struct e1000_hw *hw)
959	{
960	struct e1000_phy_info *phy = &hw->phy;
961	s32 ret_val;
962	u16 mii_autoneg_adv_reg;
963	u16 mii_1000t_ctrl_reg = `0`;
964
965	phy->autoneg_advertised &= phy->autoneg_mask;
966
967	/ Read the MII Auto-Neg Advertisement Register (Address 4). /
968	ret_val = e1e_rphy(hw, MII_ADVERTISE, data: &mii_autoneg_adv_reg);
969	if (ret_val)
970	return ret_val;
971
972	if (phy->autoneg_mask & ADVERTISE_1000_FULL) {
973	/ Read the MII 1000Base-T Control Register (Address 9). /
974	ret_val = e1e_rphy(hw, MII_CTRL1000, data: &mii_1000t_ctrl_reg);
975	if (ret_val)
976	return ret_val;
977	}
978
979	/ Need to parse both autoneg_advertised and fc and set up*
980	* the appropriate PHY registers. First we will parse for
981	* autoneg_advertised software override. Since we can advertise
982	* a plethora of combinations, we need to check each bit
983	* individually.
984	*/
985
986	/ First we clear all the 10/100 mb speed bits in the Auto-Neg*
987	* Advertisement Register (Address 4) and the 1000 mb speed bits in
988	* the 1000Base-T Control Register (Address 9).
989	*/
990	mii_autoneg_adv_reg &= ~(ADVERTISE_100FULL \|
991	ADVERTISE_100HALF \|
992	ADVERTISE_10FULL \| ADVERTISE_10HALF);
993	mii_1000t_ctrl_reg &= ~(ADVERTISE_1000HALF \| ADVERTISE_1000FULL);
994
995	e_dbg("autoneg_advertised %x\n", phy->autoneg_advertised);
996
997	/ Do we want to advertise 10 Mb Half Duplex? /
998	if (phy->autoneg_advertised & ADVERTISE_10_HALF) {
999	e_dbg("Advertise 10mb Half duplex\n");
1000	mii_autoneg_adv_reg \|= ADVERTISE_10HALF;
1001	}
1002
1003	/ Do we want to advertise 10 Mb Full Duplex? /
1004	if (phy->autoneg_advertised & ADVERTISE_10_FULL) {
1005	e_dbg("Advertise 10mb Full duplex\n");
1006	mii_autoneg_adv_reg \|= ADVERTISE_10FULL;
1007	}
1008
1009	/ Do we want to advertise 100 Mb Half Duplex? /
1010	if (phy->autoneg_advertised & ADVERTISE_100_HALF) {
1011	e_dbg("Advertise 100mb Half duplex\n");
1012	mii_autoneg_adv_reg \|= ADVERTISE_100HALF;
1013	}
1014
1015	/ Do we want to advertise 100 Mb Full Duplex? /
1016	if (phy->autoneg_advertised & ADVERTISE_100_FULL) {
1017	e_dbg("Advertise 100mb Full duplex\n");
1018	mii_autoneg_adv_reg \|= ADVERTISE_100FULL;
1019	}
1020
1021	/ We do not allow the Phy to advertise 1000 Mb Half Duplex /
1022	if (phy->autoneg_advertised & ADVERTISE_1000_HALF)
1023	e_dbg("Advertise 1000mb Half duplex request denied!\n");
1024
1025	/ Do we want to advertise 1000 Mb Full Duplex? /
1026	if (phy->autoneg_advertised & ADVERTISE_1000_FULL) {
1027	e_dbg("Advertise 1000mb Full duplex\n");
1028	mii_1000t_ctrl_reg \|= ADVERTISE_1000FULL;
1029	}
1030
1031	/ Check for a software override of the flow control settings, and*
1032	* setup the PHY advertisement registers accordingly. If
1033	* auto-negotiation is enabled, then software will have to set the
1034	* "PAUSE" bits to the correct value in the Auto-Negotiation
1035	* Advertisement Register (MII_ADVERTISE) and re-start auto-
1036	* negotiation.
1037	*
1038	* The possible values of the "fc" parameter are:
1039	* 0: Flow control is completely disabled
1040	* 1: Rx flow control is enabled (we can receive pause frames
1041	* but not send pause frames).
1042	* 2: Tx flow control is enabled (we can send pause frames
1043	* but we do not support receiving pause frames).
1044	* 3: Both Rx and Tx flow control (symmetric) are enabled.
1045	* other: No software override. The flow control configuration
1046	* in the EEPROM is used.
1047	*/
1048	switch (hw->fc.current_mode) {
1049	case e1000_fc_none:
1050	/ Flow control (Rx & Tx) is completely disabled by a*
1051	* software over-ride.
1052	*/
1053	mii_autoneg_adv_reg &=
1054	~(ADVERTISE_PAUSE_ASYM \| ADVERTISE_PAUSE_CAP);
1055	phy->autoneg_advertised &=
1056	~(ADVERTISED_Pause \| ADVERTISED_Asym_Pause);
1057	break;
1058	case e1000_fc_rx_pause:
1059	/ Rx Flow control is enabled, and Tx Flow control is*
1060	* disabled, by a software over-ride.
1061	*
1062	* Since there really isn't a way to advertise that we are
1063	* capable of Rx Pause ONLY, we will advertise that we
1064	* support both symmetric and asymmetric Rx PAUSE. Later
1065	* (in e1000e_config_fc_after_link_up) we will disable the
1066	* hw's ability to send PAUSE frames.
1067	*/
1068	mii_autoneg_adv_reg \|=
1069	(ADVERTISE_PAUSE_ASYM \| ADVERTISE_PAUSE_CAP);
1070	phy->autoneg_advertised \|=
1071	(ADVERTISED_Pause \| ADVERTISED_Asym_Pause);
1072	break;
1073	case e1000_fc_tx_pause:
1074	/ Tx Flow control is enabled, and Rx Flow control is*
1075	* disabled, by a software over-ride.
1076	*/
1077	mii_autoneg_adv_reg \|= ADVERTISE_PAUSE_ASYM;
1078	mii_autoneg_adv_reg &= ~ADVERTISE_PAUSE_CAP;
1079	phy->autoneg_advertised \|= ADVERTISED_Asym_Pause;
1080	phy->autoneg_advertised &= ~ADVERTISED_Pause;
1081	break;
1082	case e1000_fc_full:
1083	/ Flow control (both Rx and Tx) is enabled by a software*
1084	* over-ride.
1085	*/
1086	mii_autoneg_adv_reg \|=
1087	(ADVERTISE_PAUSE_ASYM \| ADVERTISE_PAUSE_CAP);
1088	phy->autoneg_advertised \|=
1089	(ADVERTISED_Pause \| ADVERTISED_Asym_Pause);
1090	break;
1091	default:
1092	e_dbg("Flow control param set incorrectly\n");
1093	return -E1000_ERR_CONFIG;
1094	}
1095
1096	ret_val = e1e_wphy(hw, MII_ADVERTISE, data: mii_autoneg_adv_reg);
1097	if (ret_val)
1098	return ret_val;
1099
1100	e_dbg("Auto-Neg Advertising %x\n", mii_autoneg_adv_reg);
1101
1102	if (phy->autoneg_mask & ADVERTISE_1000_FULL)
1103	ret_val = e1e_wphy(hw, MII_CTRL1000, data: mii_1000t_ctrl_reg);
1104
1105	return ret_val;
1106	}
1107
1108	/**
1109	* e1000_copper_link_autoneg - Setup/Enable autoneg for copper link
1110	* @hw: pointer to the HW structure
1111	*
1112	* Performs initial bounds checking on autoneg advertisement parameter, then
1113	* configure to advertise the full capability. Setup the PHY to autoneg
1114	* and restart the negotiation process between the link partner. If
1115	* autoneg_wait_to_complete, then wait for autoneg to complete before exiting.
1116	**/
1117	static s32 e1000_copper_link_autoneg(struct e1000_hw *hw)
1118	{
1119	struct e1000_phy_info *phy = &hw->phy;
1120	s32 ret_val;
1121	u16 phy_ctrl;
1122
1123	/ Perform some bounds checking on the autoneg advertisement*
1124	* parameter.
1125	*/
1126	phy->autoneg_advertised &= phy->autoneg_mask;
1127
1128	/ If autoneg_advertised is zero, we assume it was not defaulted*
1129	* by the calling code so we set to advertise full capability.
1130	*/
1131	if (!phy->autoneg_advertised)
1132	phy->autoneg_advertised = phy->autoneg_mask;
1133
1134	e_dbg("Reconfiguring auto-neg advertisement params\n");
1135	ret_val = e1000_phy_setup_autoneg(hw);
1136	if (ret_val) {
1137	e_dbg("Error Setting up Auto-Negotiation\n");
1138	return ret_val;
1139	}
1140	e_dbg("Restarting Auto-Neg\n");
1141
1142	/ Restart auto-negotiation by setting the Auto Neg Enable bit and*
1143	* the Auto Neg Restart bit in the PHY control register.
1144	*/
1145	ret_val = e1e_rphy(hw, MII_BMCR, data: &phy_ctrl);
1146	if (ret_val)
1147	return ret_val;
1148
1149	phy_ctrl \|= (BMCR_ANENABLE \| BMCR_ANRESTART);
1150	ret_val = e1e_wphy(hw, MII_BMCR, data: phy_ctrl);
1151	if (ret_val)
1152	return ret_val;
1153
1154	/ Does the user want to wait for Auto-Neg to complete here, or*
1155	* check at a later time (for example, callback routine).
1156	*/
1157	if (phy->autoneg_wait_to_complete) {
1158	ret_val = e1000_wait_autoneg(hw);
1159	if (ret_val) {
1160	e_dbg("Error while waiting for autoneg to complete\n");
1161	return ret_val;
1162	}
1163	}
1164
1165	hw->mac.get_link_status = true;
1166
1167	return ret_val;
1168	}
1169
1170	/**
1171	* e1000e_setup_copper_link - Configure copper link settings
1172	* @hw: pointer to the HW structure
1173	*
1174	* Calls the appropriate function to configure the link for auto-neg or forced
1175	* speed and duplex. Then we check for link, once link is established calls
1176	* to configure collision distance and flow control are called. If link is
1177	* not established, we return -E1000_ERR_PHY (-2).
1178	**/
1179	s32 e1000e_setup_copper_link(struct e1000_hw *hw)
1180	{
1181	s32 ret_val;
1182	bool link;
1183
1184	if (hw->mac.autoneg) {
1185	/ Setup autoneg and flow control advertisement and perform*
1186	* autonegotiation.
1187	*/
1188	ret_val = e1000_copper_link_autoneg(hw);
1189	if (ret_val)
1190	return ret_val;
1191	} else {
1192	/ PHY will be set to 10H, 10F, 100H or 100F*
1193	* depending on user settings.
1194	*/
1195	e_dbg("Forcing Speed and Duplex\n");
1196	ret_val = hw->phy.ops.force_speed_duplex(hw);
1197	if (ret_val) {
1198	e_dbg("Error Forcing Speed and Duplex\n");
1199	return ret_val;
1200	}
1201	}
1202
1203	/ Check link status. Wait up to 100 microseconds for link to become*
1204	* valid.
1205	*/
1206	ret_val = e1000e_phy_has_link_generic(hw, COPPER_LINK_UP_LIMIT, usec_interval: `10`,
1207	success: &link);
1208	if (ret_val)
1209	return ret_val;
1210
1211	if (link) {
1212	e_dbg("Valid link established!!!\n");
1213	hw->mac.ops.config_collision_dist(hw);
1214	ret_val = e1000e_config_fc_after_link_up(hw);
1215	} else {
1216	e_dbg("Unable to establish link!!!\n");
1217	}
1218
1219	return ret_val;
1220	}
1221
1222	/**
1223	* e1000e_phy_force_speed_duplex_igp - Force speed/duplex for igp PHY
1224	* @hw: pointer to the HW structure
1225	*
1226	* Calls the PHY setup function to force speed and duplex. Clears the
1227	* auto-crossover to force MDI manually. Waits for link and returns
1228	* successful if link up is successful, else -E1000_ERR_PHY (-2).
1229	**/
1230	s32 e1000e_phy_force_speed_duplex_igp(struct e1000_hw *hw)
1231	{
1232	struct e1000_phy_info *phy = &hw->phy;
1233	s32 ret_val;
1234	u16 phy_data;
1235	bool link;
1236
1237	ret_val = e1e_rphy(hw, MII_BMCR, data: &phy_data);
1238	if (ret_val)
1239	return ret_val;
1240
1241	e1000e_phy_force_speed_duplex_setup(hw, phy_ctrl: &phy_data);
1242
1243	ret_val = e1e_wphy(hw, MII_BMCR, data: phy_data);
1244	if (ret_val)
1245	return ret_val;
1246
1247	/ Clear Auto-Crossover to force MDI manually. IGP requires MDI*
1248	* forced whenever speed and duplex are forced.
1249	*/
1250	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CTRL, data: &phy_data);
1251	if (ret_val)
1252	return ret_val;
1253
1254	phy_data &= ~IGP01E1000_PSCR_AUTO_MDIX;
1255	phy_data &= ~IGP01E1000_PSCR_FORCE_MDI_MDIX;
1256
1257	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CTRL, data: phy_data);
1258	if (ret_val)
1259	return ret_val;
1260
1261	e_dbg("IGP PSCR: %X\n", phy_data);
1262
1263	udelay(usec: `1`);
1264
1265	if (phy->autoneg_wait_to_complete) {
1266	e_dbg("Waiting for forced speed/duplex link on IGP phy.\n");
1267
1268	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1269	usec_interval: `100000`, success: &link);
1270	if (ret_val)
1271	return ret_val;
1272
1273	if (!link)
1274	e_dbg("Link taking longer than expected.\n");
1275
1276	/ Try once more /
1277	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1278	usec_interval: `100000`, success: &link);
1279	}
1280
1281	return ret_val;
1282	}
1283
1284	/**
1285	* e1000e_phy_force_speed_duplex_m88 - Force speed/duplex for m88 PHY
1286	* @hw: pointer to the HW structure
1287	*
1288	* Calls the PHY setup function to force speed and duplex. Clears the
1289	* auto-crossover to force MDI manually. Resets the PHY to commit the
1290	* changes. If time expires while waiting for link up, we reset the DSP.
1291	* After reset, TX_CLK and CRS on Tx must be set. Return successful upon
1292	* successful completion, else return corresponding error code.
1293	**/
1294	s32 e1000e_phy_force_speed_duplex_m88(struct e1000_hw *hw)
1295	{
1296	struct e1000_phy_info *phy = &hw->phy;
1297	s32 ret_val;
1298	u16 phy_data;
1299	bool link;
1300
1301	/ Clear Auto-Crossover to force MDI manually. M88E1000 requires MDI*
1302	* forced whenever speed and duplex are forced.
1303	*/
1304	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_CTRL, data: &phy_data);
1305	if (ret_val)
1306	return ret_val;
1307
1308	phy_data &= ~M88E1000_PSCR_AUTO_X_MODE;
1309	ret_val = e1e_wphy(hw, M88E1000_PHY_SPEC_CTRL, data: phy_data);
1310	if (ret_val)
1311	return ret_val;
1312
1313	e_dbg("M88E1000 PSCR: %X\n", phy_data);
1314
1315	ret_val = e1e_rphy(hw, MII_BMCR, data: &phy_data);
1316	if (ret_val)
1317	return ret_val;
1318
1319	e1000e_phy_force_speed_duplex_setup(hw, phy_ctrl: &phy_data);
1320
1321	ret_val = e1e_wphy(hw, MII_BMCR, data: phy_data);
1322	if (ret_val)
1323	return ret_val;
1324
1325	/ Reset the phy to commit changes. /
1326	if (hw->phy.ops.commit) {
1327	ret_val = hw->phy.ops.commit(hw);
1328	if (ret_val)
1329	return ret_val;
1330	}
1331
1332	if (phy->autoneg_wait_to_complete) {
1333	e_dbg("Waiting for forced speed/duplex link on M88 phy.\n");
1334
1335	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1336	usec_interval: `100000`, success: &link);
1337	if (ret_val)
1338	return ret_val;
1339
1340	if (!link) {
1341	if (hw->phy.type != e1000_phy_m88) {
1342	e_dbg("Link taking longer than expected.\n");
1343	} else {
1344	/ We didn't get link.*
1345	* Reset the DSP and cross our fingers.
1346	*/
1347	ret_val = e1e_wphy(hw, M88E1000_PHY_PAGE_SELECT,
1348	data: `0x001d`);
1349	if (ret_val)
1350	return ret_val;
1351	ret_val = e1000e_phy_reset_dsp(hw);
1352	if (ret_val)
1353	return ret_val;
1354	}
1355	}
1356
1357	/ Try once more /
1358	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1359	usec_interval: `100000`, success: &link);
1360	if (ret_val)
1361	return ret_val;
1362	}
1363
1364	if (hw->phy.type != e1000_phy_m88)
1365	return `0`;
1366
1367	ret_val = e1e_rphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: &phy_data);
1368	if (ret_val)
1369	return ret_val;
1370
1371	/ Resetting the phy means we need to re-force TX_CLK in the*
1372	* Extended PHY Specific Control Register to 25MHz clock from
1373	* the reset value of 2.5MHz.
1374	*/
1375	phy_data \|= M88E1000_EPSCR_TX_CLK_25;
1376	ret_val = e1e_wphy(hw, M88E1000_EXT_PHY_SPEC_CTRL, data: phy_data);
1377	if (ret_val)
1378	return ret_val;
1379
1380	/ In addition, we must re-enable CRS on Tx for both half and full*
1381	* duplex.
1382	*/
1383	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_CTRL, data: &phy_data);
1384	if (ret_val)
1385	return ret_val;
1386
1387	phy_data \|= M88E1000_PSCR_ASSERT_CRS_ON_TX;
1388	ret_val = e1e_wphy(hw, M88E1000_PHY_SPEC_CTRL, data: phy_data);
1389
1390	return ret_val;
1391	}
1392
1393	/**
1394	* e1000_phy_force_speed_duplex_ife - Force PHY speed & duplex
1395	* @hw: pointer to the HW structure
1396	*
1397	* Forces the speed and duplex settings of the PHY.
1398	* This is a function pointer entry point only called by
1399	* PHY setup routines.
1400	**/
1401	s32 e1000_phy_force_speed_duplex_ife(struct e1000_hw *hw)
1402	{
1403	struct e1000_phy_info *phy = &hw->phy;
1404	s32 ret_val;
1405	u16 data;
1406	bool link;
1407
1408	ret_val = e1e_rphy(hw, MII_BMCR, data: &data);
1409	if (ret_val)
1410	return ret_val;
1411
1412	e1000e_phy_force_speed_duplex_setup(hw, phy_ctrl: &data);
1413
1414	ret_val = e1e_wphy(hw, MII_BMCR, data);
1415	if (ret_val)
1416	return ret_val;
1417
1418	/ Disable MDI-X support for 10/100 /
1419	ret_val = e1e_rphy(hw, IFE_PHY_MDIX_CONTROL, data: &data);
1420	if (ret_val)
1421	return ret_val;
1422
1423	data &= ~IFE_PMC_AUTO_MDIX;
1424	data &= ~IFE_PMC_FORCE_MDIX;
1425
1426	ret_val = e1e_wphy(hw, IFE_PHY_MDIX_CONTROL, data);
1427	if (ret_val)
1428	return ret_val;
1429
1430	e_dbg("IFE PMC: %X\n", data);
1431
1432	udelay(usec: `1`);
1433
1434	if (phy->autoneg_wait_to_complete) {
1435	e_dbg("Waiting for forced speed/duplex link on IFE phy.\n");
1436
1437	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1438	usec_interval: `100000`, success: &link);
1439	if (ret_val)
1440	return ret_val;
1441
1442	if (!link)
1443	e_dbg("Link taking longer than expected.\n");
1444
1445	/ Try once more /
1446	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
1447	usec_interval: `100000`, success: &link);
1448	if (ret_val)
1449	return ret_val;
1450	}
1451
1452	return `0`;
1453	}
1454
1455	/**
1456	* e1000e_phy_force_speed_duplex_setup - Configure forced PHY speed/duplex
1457	* @hw: pointer to the HW structure
1458	* @phy_ctrl: pointer to current value of MII_BMCR
1459	*
1460	* Forces speed and duplex on the PHY by doing the following: disable flow
1461	* control, force speed/duplex on the MAC, disable auto speed detection,
1462	* disable auto-negotiation, configure duplex, configure speed, configure
1463	* the collision distance, write configuration to CTRL register. The
1464	* caller must write to the MII_BMCR register for these settings to
1465	* take affect.
1466	**/
1467	void e1000e_phy_force_speed_duplex_setup(struct e1000_hw hw, u16 phy_ctrl)
1468	{
1469	struct e1000_mac_info *mac = &hw->mac;
1470	u32 ctrl;
1471
1472	/ Turn off flow control when forcing speed/duplex /
1473	hw->fc.current_mode = e1000_fc_none;
1474
1475	/ Force speed/duplex on the mac /
1476	ctrl = er32(CTRL);
1477	ctrl \|= (E1000_CTRL_FRCSPD \| E1000_CTRL_FRCDPX);
1478	ctrl &= ~E1000_CTRL_SPD_SEL;
1479
1480	/ Disable Auto Speed Detection /
1481	ctrl &= ~E1000_CTRL_ASDE;
1482
1483	/ Disable autoneg on the phy /
1484	*phy_ctrl &= ~BMCR_ANENABLE;
1485
1486	/ Forcing Full or Half Duplex? /
1487	if (mac->forced_speed_duplex & E1000_ALL_HALF_DUPLEX) {
1488	ctrl &= ~E1000_CTRL_FD;
1489	*phy_ctrl &= ~BMCR_FULLDPLX;
1490	e_dbg("Half Duplex\n");
1491	} else {
1492	ctrl \|= E1000_CTRL_FD;
1493	*phy_ctrl \|= BMCR_FULLDPLX;
1494	e_dbg("Full Duplex\n");
1495	}
1496
1497	/ Forcing 10mb or 100mb? /
1498	if (mac->forced_speed_duplex & E1000_ALL_100_SPEED) {
1499	ctrl \|= E1000_CTRL_SPD_100;
1500	*phy_ctrl \|= BMCR_SPEED100;
1501	*phy_ctrl &= ~BMCR_SPEED1000;
1502	e_dbg("Forcing 100mb\n");
1503	} else {
1504	ctrl &= ~(E1000_CTRL_SPD_1000 \| E1000_CTRL_SPD_100);
1505	*phy_ctrl &= ~(BMCR_SPEED1000 \| BMCR_SPEED100);
1506	e_dbg("Forcing 10mb\n");
1507	}
1508
1509	hw->mac.ops.config_collision_dist(hw);
1510
1511	ew32(CTRL, ctrl);
1512	}
1513
1514	/**
1515	* e1000e_set_d3_lplu_state - Sets low power link up state for D3
1516	* @hw: pointer to the HW structure
1517	* @active: boolean used to enable/disable lplu
1518	*
1519	* Success returns 0, Failure returns 1
1520	*
1521	* The low power link up (lplu) state is set to the power management level D3
1522	* and SmartSpeed is disabled when active is true, else clear lplu for D3
1523	* and enable Smartspeed. LPLU and Smartspeed are mutually exclusive. LPLU
1524	* is used during Dx states where the power conservation is most important.
1525	* During driver activity, SmartSpeed should be enabled so performance is
1526	* maintained.
1527	**/
1528	s32 e1000e_set_d3_lplu_state(struct e1000_hw *hw, bool active)
1529	{
1530	struct e1000_phy_info *phy = &hw->phy;
1531	s32 ret_val;
1532	u16 data;
1533
1534	ret_val = e1e_rphy(hw, IGP02E1000_PHY_POWER_MGMT, data: &data);
1535	if (ret_val)
1536	return ret_val;
1537
1538	if (!active) {
1539	data &= ~IGP02E1000_PM_D3_LPLU;
1540	ret_val = e1e_wphy(hw, IGP02E1000_PHY_POWER_MGMT, data);
1541	if (ret_val)
1542	return ret_val;
1543	/ LPLU and SmartSpeed are mutually exclusive. LPLU is used*
1544	* during Dx states where the power conservation is most
1545	* important. During driver activity we should enable
1546	* SmartSpeed, so performance is maintained.
1547	*/
1548	if (phy->smart_speed == e1000_smart_speed_on) {
1549	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CONFIG,
1550	data: &data);
1551	if (ret_val)
1552	return ret_val;
1553
1554	data \|= IGP01E1000_PSCFR_SMART_SPEED;
1555	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CONFIG,
1556	data);
1557	if (ret_val)
1558	return ret_val;
1559	} else if (phy->smart_speed == e1000_smart_speed_off) {
1560	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CONFIG,
1561	data: &data);
1562	if (ret_val)
1563	return ret_val;
1564
1565	data &= ~IGP01E1000_PSCFR_SMART_SPEED;
1566	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CONFIG,
1567	data);
1568	if (ret_val)
1569	return ret_val;
1570	}
1571	} else if ((phy->autoneg_advertised == E1000_ALL_SPEED_DUPLEX) \|\|
1572	(phy->autoneg_advertised == E1000_ALL_NOT_GIG) \|\|
1573	(phy->autoneg_advertised == E1000_ALL_10_SPEED)) {
1574	data \|= IGP02E1000_PM_D3_LPLU;
1575	ret_val = e1e_wphy(hw, IGP02E1000_PHY_POWER_MGMT, data);
1576	if (ret_val)
1577	return ret_val;
1578
1579	/ When LPLU is enabled, we should disable SmartSpeed /
1580	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_CONFIG, data: &data);
1581	if (ret_val)
1582	return ret_val;
1583
1584	data &= ~IGP01E1000_PSCFR_SMART_SPEED;
1585	ret_val = e1e_wphy(hw, IGP01E1000_PHY_PORT_CONFIG, data);
1586	}
1587
1588	return ret_val;
1589	}
1590
1591	/**
1592	* e1000e_check_downshift - Checks whether a downshift in speed occurred
1593	* @hw: pointer to the HW structure
1594	*
1595	* Success returns 0, Failure returns 1
1596	*
1597	* A downshift is detected by querying the PHY link health.
1598	**/
1599	s32 e1000e_check_downshift(struct e1000_hw *hw)
1600	{
1601	struct e1000_phy_info *phy = &hw->phy;
1602	s32 ret_val;
1603	u16 phy_data, offset, mask;
1604
1605	switch (phy->type) {
1606	case e1000_phy_m88:
1607	case e1000_phy_gg82563:
1608	case e1000_phy_bm:
1609	case e1000_phy_82578:
1610	offset = M88E1000_PHY_SPEC_STATUS;
1611	mask = M88E1000_PSSR_DOWNSHIFT;
1612	break;
1613	case e1000_phy_igp_2:
1614	case e1000_phy_igp_3:
1615	offset = IGP01E1000_PHY_LINK_HEALTH;
1616	mask = IGP01E1000_PLHR_SS_DOWNGRADE;
1617	break;
1618	default:
1619	/ speed downshift not supported /
1620	phy->speed_downgraded = false;
1621	return `0`;
1622	}
1623
1624	ret_val = e1e_rphy(hw, offset, data: &phy_data);
1625
1626	if (!ret_val)
1627	phy->speed_downgraded = !!(phy_data & mask);
1628
1629	return ret_val;
1630	}
1631
1632	/**
1633	* e1000_check_polarity_m88 - Checks the polarity.
1634	* @hw: pointer to the HW structure
1635	*
1636	* Success returns 0, Failure returns -E1000_ERR_PHY (-2)
1637	*
1638	* Polarity is determined based on the PHY specific status register.
1639	**/
1640	s32 e1000_check_polarity_m88(struct e1000_hw *hw)
1641	{
1642	struct e1000_phy_info *phy = &hw->phy;
1643	s32 ret_val;
1644	u16 data;
1645
1646	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_STATUS, data: &data);
1647
1648	if (!ret_val)
1649	phy->cable_polarity = ((data & M88E1000_PSSR_REV_POLARITY)
1650	? e1000_rev_polarity_reversed
1651	: e1000_rev_polarity_normal);
1652
1653	return ret_val;
1654	}
1655
1656	/**
1657	* e1000_check_polarity_igp - Checks the polarity.
1658	* @hw: pointer to the HW structure
1659	*
1660	* Success returns 0, Failure returns -E1000_ERR_PHY (-2)
1661	*
1662	* Polarity is determined based on the PHY port status register, and the
1663	* current speed (since there is no polarity at 100Mbps).
1664	**/
1665	s32 e1000_check_polarity_igp(struct e1000_hw *hw)
1666	{
1667	struct e1000_phy_info *phy = &hw->phy;
1668	s32 ret_val;
1669	u16 data, offset, mask;
1670
1671	/ Polarity is determined based on the speed of*
1672	* our connection.
1673	*/
1674	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_STATUS, data: &data);
1675	if (ret_val)
1676	return ret_val;
1677
1678	if ((data & IGP01E1000_PSSR_SPEED_MASK) ==
1679	IGP01E1000_PSSR_SPEED_1000MBPS) {
1680	offset = IGP01E1000_PHY_PCS_INIT_REG;
1681	mask = IGP01E1000_PHY_POLARITY_MASK;
1682	} else {
1683	/ This really only applies to 10Mbps since*
1684	* there is no polarity for 100Mbps (always 0).
1685	*/
1686	offset = IGP01E1000_PHY_PORT_STATUS;
1687	mask = IGP01E1000_PSSR_POLARITY_REVERSED;
1688	}
1689
1690	ret_val = e1e_rphy(hw, offset, data: &data);
1691
1692	if (!ret_val)
1693	phy->cable_polarity = ((data & mask)
1694	? e1000_rev_polarity_reversed
1695	: e1000_rev_polarity_normal);
1696
1697	return ret_val;
1698	}
1699
1700	/**
1701	* e1000_check_polarity_ife - Check cable polarity for IFE PHY
1702	* @hw: pointer to the HW structure
1703	*
1704	* Polarity is determined on the polarity reversal feature being enabled.
1705	**/
1706	s32 e1000_check_polarity_ife(struct e1000_hw *hw)
1707	{
1708	struct e1000_phy_info *phy = &hw->phy;
1709	s32 ret_val;
1710	u16 phy_data, offset, mask;
1711
1712	/ Polarity is determined based on the reversal feature being enabled.*
1713	*/
1714	if (phy->polarity_correction) {
1715	offset = IFE_PHY_EXTENDED_STATUS_CONTROL;
1716	mask = IFE_PESC_POLARITY_REVERSED;
1717	} else {
1718	offset = IFE_PHY_SPECIAL_CONTROL;
1719	mask = IFE_PSC_FORCE_POLARITY;
1720	}
1721
1722	ret_val = e1e_rphy(hw, offset, data: &phy_data);
1723
1724	if (!ret_val)
1725	phy->cable_polarity = ((phy_data & mask)
1726	? e1000_rev_polarity_reversed
1727	: e1000_rev_polarity_normal);
1728
1729	return ret_val;
1730	}
1731
1732	/**
1733	* e1000_wait_autoneg - Wait for auto-neg completion
1734	* @hw: pointer to the HW structure
1735	*
1736	* Waits for auto-negotiation to complete or for the auto-negotiation time
1737	* limit to expire, which ever happens first.
1738	**/
1739	static s32 e1000_wait_autoneg(struct e1000_hw *hw)
1740	{
1741	s32 ret_val = `0`;
1742	u16 i, phy_status;
1743
1744	/ Break after autoneg completes or PHY_AUTO_NEG_LIMIT expires. /
1745	for (i = PHY_AUTO_NEG_LIMIT; i > `0`; i--) {
1746	ret_val = e1e_rphy(hw, MII_BMSR, data: &phy_status);
1747	if (ret_val)
1748	break;
1749	ret_val = e1e_rphy(hw, MII_BMSR, data: &phy_status);
1750	if (ret_val)
1751	break;
1752	if (phy_status & BMSR_ANEGCOMPLETE)
1753	break;
1754	msleep(msecs: `100`);
1755	}
1756
1757	/ PHY_AUTO_NEG_TIME expiration doesn't guarantee auto-negotiation*
1758	* has completed.
1759	*/
1760	return ret_val;
1761	}
1762
1763	/**
1764	* e1000e_phy_has_link_generic - Polls PHY for link
1765	* @hw: pointer to the HW structure
1766	* @iterations: number of times to poll for link
1767	* @usec_interval: delay between polling attempts
1768	* @success: pointer to whether polling was successful or not
1769	*
1770	* Polls the PHY status register for link, 'iterations' number of times.
1771	**/
1772	s32 e1000e_phy_has_link_generic(struct e1000_hw *hw, u32 iterations,
1773	u32 usec_interval, bool *success)
1774	{
1775	s32 ret_val = `0`;
1776	u16 i, phy_status;
1777
1778	*success = false;
1779	for (i = `0`; i < iterations; i++) {
1780	/ Some PHYs require the MII_BMSR register to be read*
1781	* twice due to the link bit being sticky. No harm doing
1782	* it across the board.
1783	*/
1784	ret_val = e1e_rphy(hw, MII_BMSR, data: &phy_status);
1785	if (ret_val) {
1786	/ If the first read fails, another entity may have*
1787	* ownership of the resources, wait and try again to
1788	* see if they have relinquished the resources yet.
1789	*/
1790	if (usec_interval >= `1000`)
1791	msleep(msecs: usec_interval / `1000`);
1792	else
1793	udelay(usec: usec_interval);
1794	}
1795	ret_val = e1e_rphy(hw, MII_BMSR, data: &phy_status);
1796	if (ret_val)
1797	break;
1798	if (phy_status & BMSR_LSTATUS) {
1799	*success = true;
1800	break;
1801	}
1802	if (usec_interval >= `1000`)
1803	msleep(msecs: usec_interval / `1000`);
1804	else
1805	udelay(usec: usec_interval);
1806	}
1807
1808	return ret_val;
1809	}
1810
1811	/**
1812	* e1000e_get_cable_length_m88 - Determine cable length for m88 PHY
1813	* @hw: pointer to the HW structure
1814	*
1815	* Reads the PHY specific status register to retrieve the cable length
1816	* information. The cable length is determined by averaging the minimum and
1817	* maximum values to get the "average" cable length. The m88 PHY has four
1818	* possible cable length values, which are:
1819	* Register Value Cable Length
1820	* 0 < 50 meters
1821	* 1 50 - 80 meters
1822	* 2 80 - 110 meters
1823	* 3 110 - 140 meters
1824	* 4 > 140 meters
1825	**/
1826	s32 e1000e_get_cable_length_m88(struct e1000_hw *hw)
1827	{
1828	struct e1000_phy_info *phy = &hw->phy;
1829	s32 ret_val;
1830	u16 phy_data, index;
1831
1832	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_STATUS, data: &phy_data);
1833	if (ret_val)
1834	return ret_val;
1835
1836	index = FIELD_GET(M88E1000_PSSR_CABLE_LENGTH, phy_data);
1837
1838	if (index >= M88E1000_CABLE_LENGTH_TABLE_SIZE - `1`)
1839	return -E1000_ERR_PHY;
1840
1841	phy->min_cable_length = e1000_m88_cable_length_table[index];
1842	phy->max_cable_length = e1000_m88_cable_length_table[index + `1`];
1843
1844	phy->cable_length = (phy->min_cable_length + phy->max_cable_length) / `2`;
1845
1846	return `0`;
1847	}
1848
1849	/**
1850	* e1000e_get_cable_length_igp_2 - Determine cable length for igp2 PHY
1851	* @hw: pointer to the HW structure
1852	*
1853	* The automatic gain control (agc) normalizes the amplitude of the
1854	* received signal, adjusting for the attenuation produced by the
1855	* cable. By reading the AGC registers, which represent the
1856	* combination of coarse and fine gain value, the value can be put
1857	* into a lookup table to obtain the approximate cable length
1858	* for each channel.
1859	**/
1860	s32 e1000e_get_cable_length_igp_2(struct e1000_hw *hw)
1861	{
1862	struct e1000_phy_info *phy = &hw->phy;
1863	s32 ret_val;
1864	u16 phy_data, i, agc_value = `0`;
1865	u16 cur_agc_index, max_agc_index = `0`;
1866	u16 min_agc_index = IGP02E1000_CABLE_LENGTH_TABLE_SIZE - `1`;
1867	static const u16 agc_reg_array[IGP02E1000_PHY_CHANNEL_NUM] = {
1868	IGP02E1000_PHY_AGC_A,
1869	IGP02E1000_PHY_AGC_B,
1870	IGP02E1000_PHY_AGC_C,
1871	IGP02E1000_PHY_AGC_D
1872	};
1873
1874	/ Read the AGC registers for all channels /
1875	for (i = `0`; i < IGP02E1000_PHY_CHANNEL_NUM; i++) {
1876	ret_val = e1e_rphy(hw, offset: agc_reg_array[i], data: &phy_data);
1877	if (ret_val)
1878	return ret_val;
1879
1880	/ Getting bits 15:9, which represent the combination of*
1881	* coarse and fine gain values. The result is a number
1882	* that can be put into the lookup table to obtain the
1883	* approximate cable length.
1884	*/
1885	cur_agc_index = ((phy_data >> IGP02E1000_AGC_LENGTH_SHIFT) &
1886	IGP02E1000_AGC_LENGTH_MASK);
1887
1888	/ Array index bound check. /
1889	if ((cur_agc_index >= IGP02E1000_CABLE_LENGTH_TABLE_SIZE) \|\|
1890	(cur_agc_index == `0`))
1891	return -E1000_ERR_PHY;
1892
1893	/ Remove min & max AGC values from calculation. /
1894	if (e1000_igp_2_cable_length_table[min_agc_index] >
1895	e1000_igp_2_cable_length_table[cur_agc_index])
1896	min_agc_index = cur_agc_index;
1897	if (e1000_igp_2_cable_length_table[max_agc_index] <
1898	e1000_igp_2_cable_length_table[cur_agc_index])
1899	max_agc_index = cur_agc_index;
1900
1901	agc_value += e1000_igp_2_cable_length_table[cur_agc_index];
1902	}
1903
1904	agc_value -= (e1000_igp_2_cable_length_table[min_agc_index] +
1905	e1000_igp_2_cable_length_table[max_agc_index]);
1906	agc_value /= (IGP02E1000_PHY_CHANNEL_NUM - `2`);
1907
1908	/ Calculate cable length with the error range of +/- 10 meters. /
1909	phy->min_cable_length = (((agc_value - IGP02E1000_AGC_RANGE) > `0`) ?
1910	(agc_value - IGP02E1000_AGC_RANGE) : `0`);
1911	phy->max_cable_length = agc_value + IGP02E1000_AGC_RANGE;
1912
1913	phy->cable_length = (phy->min_cable_length + phy->max_cable_length) / `2`;
1914
1915	return `0`;
1916	}
1917
1918	/**
1919	* e1000e_get_phy_info_m88 - Retrieve PHY information
1920	* @hw: pointer to the HW structure
1921	*
1922	* Valid for only copper links. Read the PHY status register (sticky read)
1923	* to verify that link is up. Read the PHY special control register to
1924	* determine the polarity and 10base-T extended distance. Read the PHY
1925	* special status register to determine MDI/MDIx and current speed. If
1926	* speed is 1000, then determine cable length, local and remote receiver.
1927	**/
1928	s32 e1000e_get_phy_info_m88(struct e1000_hw *hw)
1929	{
1930	struct e1000_phy_info *phy = &hw->phy;
1931	s32 ret_val;
1932	u16 phy_data;
1933	bool link;
1934
1935	if (phy->media_type != e1000_media_type_copper) {
1936	e_dbg("Phy info is only valid for copper media\n");
1937	return -E1000_ERR_CONFIG;
1938	}
1939
1940	ret_val = e1000e_phy_has_link_generic(hw, iterations: `1`, usec_interval: `0`, success: &link);
1941	if (ret_val)
1942	return ret_val;
1943
1944	if (!link) {
1945	e_dbg("Phy info is only valid if link is up\n");
1946	return -E1000_ERR_CONFIG;
1947	}
1948
1949	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_CTRL, data: &phy_data);
1950	if (ret_val)
1951	return ret_val;
1952
1953	phy->polarity_correction = !!(phy_data &
1954	M88E1000_PSCR_POLARITY_REVERSAL);
1955
1956	ret_val = e1000_check_polarity_m88(hw);
1957	if (ret_val)
1958	return ret_val;
1959
1960	ret_val = e1e_rphy(hw, M88E1000_PHY_SPEC_STATUS, data: &phy_data);
1961	if (ret_val)
1962	return ret_val;
1963
1964	phy->is_mdix = !!(phy_data & M88E1000_PSSR_MDIX);
1965
1966	if ((phy_data & M88E1000_PSSR_SPEED) == M88E1000_PSSR_1000MBS) {
1967	ret_val = hw->phy.ops.get_cable_length(hw);
1968	if (ret_val)
1969	return ret_val;
1970
1971	ret_val = e1e_rphy(hw, MII_STAT1000, data: &phy_data);
1972	if (ret_val)
1973	return ret_val;
1974
1975	phy->local_rx = (phy_data & LPA_1000LOCALRXOK)
1976	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
1977
1978	phy->remote_rx = (phy_data & LPA_1000REMRXOK)
1979	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
1980	} else {
1981	/ Set values to "undefined" /
1982	phy->cable_length = E1000_CABLE_LENGTH_UNDEFINED;
1983	phy->local_rx = e1000_1000t_rx_status_undefined;
1984	phy->remote_rx = e1000_1000t_rx_status_undefined;
1985	}
1986
1987	return ret_val;
1988	}
1989
1990	/**
1991	* e1000e_get_phy_info_igp - Retrieve igp PHY information
1992	* @hw: pointer to the HW structure
1993	*
1994	* Read PHY status to determine if link is up. If link is up, then
1995	* set/determine 10base-T extended distance and polarity correction. Read
1996	* PHY port status to determine MDI/MDIx and speed. Based on the speed,
1997	* determine on the cable length, local and remote receiver.
1998	**/
1999	s32 e1000e_get_phy_info_igp(struct e1000_hw *hw)
2000	{
2001	struct e1000_phy_info *phy = &hw->phy;
2002	s32 ret_val;
2003	u16 data;
2004	bool link;
2005
2006	ret_val = e1000e_phy_has_link_generic(hw, iterations: `1`, usec_interval: `0`, success: &link);
2007	if (ret_val)
2008	return ret_val;
2009
2010	if (!link) {
2011	e_dbg("Phy info is only valid if link is up\n");
2012	return -E1000_ERR_CONFIG;
2013	}
2014
2015	phy->polarity_correction = true;
2016
2017	ret_val = e1000_check_polarity_igp(hw);
2018	if (ret_val)
2019	return ret_val;
2020
2021	ret_val = e1e_rphy(hw, IGP01E1000_PHY_PORT_STATUS, data: &data);
2022	if (ret_val)
2023	return ret_val;
2024
2025	phy->is_mdix = !!(data & IGP01E1000_PSSR_MDIX);
2026
2027	if ((data & IGP01E1000_PSSR_SPEED_MASK) ==
2028	IGP01E1000_PSSR_SPEED_1000MBPS) {
2029	ret_val = phy->ops.get_cable_length(hw);
2030	if (ret_val)
2031	return ret_val;
2032
2033	ret_val = e1e_rphy(hw, MII_STAT1000, data: &data);
2034	if (ret_val)
2035	return ret_val;
2036
2037	phy->local_rx = (data & LPA_1000LOCALRXOK)
2038	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
2039
2040	phy->remote_rx = (data & LPA_1000REMRXOK)
2041	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
2042	} else {
2043	phy->cable_length = E1000_CABLE_LENGTH_UNDEFINED;
2044	phy->local_rx = e1000_1000t_rx_status_undefined;
2045	phy->remote_rx = e1000_1000t_rx_status_undefined;
2046	}
2047
2048	return ret_val;
2049	}
2050
2051	/**
2052	* e1000_get_phy_info_ife - Retrieves various IFE PHY states
2053	* @hw: pointer to the HW structure
2054	*
2055	* Populates "phy" structure with various feature states.
2056	**/
2057	s32 e1000_get_phy_info_ife(struct e1000_hw *hw)
2058	{
2059	struct e1000_phy_info *phy = &hw->phy;
2060	s32 ret_val;
2061	u16 data;
2062	bool link;
2063
2064	ret_val = e1000e_phy_has_link_generic(hw, iterations: `1`, usec_interval: `0`, success: &link);
2065	if (ret_val)
2066	return ret_val;
2067
2068	if (!link) {
2069	e_dbg("Phy info is only valid if link is up\n");
2070	return -E1000_ERR_CONFIG;
2071	}
2072
2073	ret_val = e1e_rphy(hw, IFE_PHY_SPECIAL_CONTROL, data: &data);
2074	if (ret_val)
2075	return ret_val;
2076	phy->polarity_correction = !(data & IFE_PSC_AUTO_POLARITY_DISABLE);
2077
2078	if (phy->polarity_correction) {
2079	ret_val = e1000_check_polarity_ife(hw);
2080	if (ret_val)
2081	return ret_val;
2082	} else {
2083	/ Polarity is forced /
2084	phy->cable_polarity = ((data & IFE_PSC_FORCE_POLARITY)
2085	? e1000_rev_polarity_reversed
2086	: e1000_rev_polarity_normal);
2087	}
2088
2089	ret_val = e1e_rphy(hw, IFE_PHY_MDIX_CONTROL, data: &data);
2090	if (ret_val)
2091	return ret_val;
2092
2093	phy->is_mdix = !!(data & IFE_PMC_MDIX_STATUS);
2094
2095	/ The following parameters are undefined for 10/100 operation. /
2096	phy->cable_length = E1000_CABLE_LENGTH_UNDEFINED;
2097	phy->local_rx = e1000_1000t_rx_status_undefined;
2098	phy->remote_rx = e1000_1000t_rx_status_undefined;
2099
2100	return `0`;
2101	}
2102
2103	/**
2104	* e1000e_phy_sw_reset - PHY software reset
2105	* @hw: pointer to the HW structure
2106	*
2107	* Does a software reset of the PHY by reading the PHY control register and
2108	* setting/write the control register reset bit to the PHY.
2109	**/
2110	s32 e1000e_phy_sw_reset(struct e1000_hw *hw)
2111	{
2112	s32 ret_val;
2113	u16 phy_ctrl;
2114
2115	ret_val = e1e_rphy(hw, MII_BMCR, data: &phy_ctrl);
2116	if (ret_val)
2117	return ret_val;
2118
2119	phy_ctrl \|= BMCR_RESET;
2120	ret_val = e1e_wphy(hw, MII_BMCR, data: phy_ctrl);
2121	if (ret_val)
2122	return ret_val;
2123
2124	udelay(usec: `1`);
2125
2126	return ret_val;
2127	}
2128
2129	/**
2130	* e1000e_phy_hw_reset_generic - PHY hardware reset
2131	* @hw: pointer to the HW structure
2132	*
2133	* Verify the reset block is not blocking us from resetting. Acquire
2134	* semaphore (if necessary) and read/set/write the device control reset
2135	* bit in the PHY. Wait the appropriate delay time for the device to
2136	* reset and release the semaphore (if necessary).
2137	**/
2138	s32 e1000e_phy_hw_reset_generic(struct e1000_hw *hw)
2139	{
2140	struct e1000_phy_info *phy = &hw->phy;
2141	s32 ret_val;
2142	u32 ctrl;
2143
2144	if (phy->ops.check_reset_block) {
2145	ret_val = phy->ops.check_reset_block(hw);
2146	if (ret_val)
2147	return `0`;
2148	}
2149
2150	ret_val = phy->ops.acquire(hw);
2151	if (ret_val)
2152	return ret_val;
2153
2154	ctrl = er32(CTRL);
2155	ew32(CTRL, ctrl \| E1000_CTRL_PHY_RST);
2156	e1e_flush();
2157
2158	udelay(usec: phy->reset_delay_us);
2159
2160	ew32(CTRL, ctrl);
2161	e1e_flush();
2162
2163	usleep_range(min: `150`, max: `300`);
2164
2165	phy->ops.release(hw);
2166
2167	return phy->ops.get_cfg_done(hw);
2168	}
2169
2170	/**
2171	* e1000e_get_cfg_done_generic - Generic configuration done
2172	* @hw: pointer to the HW structure
2173	*
2174	* Generic function to wait 10 milli-seconds for configuration to complete
2175	* and return success.
2176	**/
2177	s32 e1000e_get_cfg_done_generic(struct e1000_hw __always_unused *hw)
2178	{
2179	mdelay(`10`);
2180
2181	return `0`;
2182	}
2183
2184	/**
2185	* e1000e_phy_init_script_igp3 - Inits the IGP3 PHY
2186	* @hw: pointer to the HW structure
2187	*
2188	* Initializes a Intel Gigabit PHY3 when an EEPROM is not present.
2189	**/
2190	s32 e1000e_phy_init_script_igp3(struct e1000_hw *hw)
2191	{
2192	e_dbg("Running IGP 3 PHY init script\n");
2193
2194	/ PHY init IGP 3 /
2195	/ Enable rise/fall, 10-mode work in class-A /
2196	e1e_wphy(hw, offset: `0x2F5B`, data: `0x9018`);
2197	/ Remove all caps from Replica path filter /
2198	e1e_wphy(hw, offset: `0x2F52`, data: `0x0000`);
2199	/ Bias trimming for ADC, AFE and Driver (Default) /
2200	e1e_wphy(hw, offset: `0x2FB1`, data: `0x8B24`);
2201	/ Increase Hybrid poly bias /
2202	e1e_wphy(hw, offset: `0x2FB2`, data: `0xF8F0`);
2203	/ Add 4% to Tx amplitude in Gig mode /
2204	e1e_wphy(hw, offset: `0x2010`, data: `0x10B0`);
2205	/ Disable trimming (TTT) /
2206	e1e_wphy(hw, offset: `0x2011`, data: `0x0000`);
2207	/ Poly DC correction to 94.6% + 2% for all channels /
2208	e1e_wphy(hw, offset: `0x20DD`, data: `0x249A`);
2209	/ ABS DC correction to 95.9% /
2210	e1e_wphy(hw, offset: `0x20DE`, data: `0x00D3`);
2211	/ BG temp curve trim /
2212	e1e_wphy(hw, offset: `0x28B4`, data: `0x04CE`);
2213	/ Increasing ADC OPAMP stage 1 currents to max /
2214	e1e_wphy(hw, offset: `0x2F70`, data: `0x29E4`);
2215	/ Force 1000 ( required for enabling PHY regs configuration) /
2216	e1e_wphy(hw, offset: `0x0000`, data: `0x0140`);
2217	/ Set upd_freq to 6 /
2218	e1e_wphy(hw, offset: `0x1F30`, data: `0x1606`);
2219	/ Disable NPDFE /
2220	e1e_wphy(hw, offset: `0x1F31`, data: `0xB814`);
2221	/ Disable adaptive fixed FFE (Default) /
2222	e1e_wphy(hw, offset: `0x1F35`, data: `0x002A`);
2223	/ Enable FFE hysteresis /
2224	e1e_wphy(hw, offset: `0x1F3E`, data: `0x0067`);
2225	/ Fixed FFE for short cable lengths /
2226	e1e_wphy(hw, offset: `0x1F54`, data: `0x0065`);
2227	/ Fixed FFE for medium cable lengths /
2228	e1e_wphy(hw, offset: `0x1F55`, data: `0x002A`);
2229	/ Fixed FFE for long cable lengths /
2230	e1e_wphy(hw, offset: `0x1F56`, data: `0x002A`);
2231	/ Enable Adaptive Clip Threshold /
2232	e1e_wphy(hw, offset: `0x1F72`, data: `0x3FB0`);
2233	/ AHT reset limit to 1 /
2234	e1e_wphy(hw, offset: `0x1F76`, data: `0xC0FF`);
2235	/ Set AHT master delay to 127 msec /
2236	e1e_wphy(hw, offset: `0x1F77`, data: `0x1DEC`);
2237	/ Set scan bits for AHT /
2238	e1e_wphy(hw, offset: `0x1F78`, data: `0xF9EF`);
2239	/ Set AHT Preset bits /
2240	e1e_wphy(hw, offset: `0x1F79`, data: `0x0210`);
2241	/ Change integ_factor of channel A to 3 /
2242	e1e_wphy(hw, offset: `0x1895`, data: `0x0003`);
2243	/ Change prop_factor of channels BCD to 8 /
2244	e1e_wphy(hw, offset: `0x1796`, data: `0x0008`);
2245	/ Change cg_icount + enable integbp for channels BCD /
2246	e1e_wphy(hw, offset: `0x1798`, data: `0xD008`);
2247	/ Change cg_icount + enable integbp + change prop_factor_master*
2248	* to 8 for channel A
2249	*/
2250	e1e_wphy(hw, offset: `0x1898`, data: `0xD918`);
2251	/ Disable AHT in Slave mode on channel A /
2252	e1e_wphy(hw, offset: `0x187A`, data: `0x0800`);
2253	/ Enable LPLU and disable AN to 1000 in non-D0a states,*
2254	* Enable SPD+B2B
2255	*/
2256	e1e_wphy(hw, offset: `0x0019`, data: `0x008D`);
2257	/ Enable restart AN on an1000_dis change /
2258	e1e_wphy(hw, offset: `0x001B`, data: `0x2080`);
2259	/ Enable wh_fifo read clock in 10/100 modes /
2260	e1e_wphy(hw, offset: `0x0014`, data: `0x0045`);
2261	/ Restart AN, Speed selection is 1000 /
2262	e1e_wphy(hw, offset: `0x0000`, data: `0x1340`);
2263
2264	return `0`;
2265	}
2266
2267	/**
2268	* e1000e_get_phy_type_from_id - Get PHY type from id
2269	* @phy_id: phy_id read from the phy
2270	*
2271	* Returns the phy type from the id.
2272	**/
2273	enum e1000_phy_type e1000e_get_phy_type_from_id(u32 phy_id)
2274	{
2275	enum e1000_phy_type phy_type = e1000_phy_unknown;
2276
2277	switch (phy_id) {
2278	case M88E1000_I_PHY_ID:
2279	case M88E1000_E_PHY_ID:
2280	case M88E1111_I_PHY_ID:
2281	case M88E1011_I_PHY_ID:
2282	phy_type = e1000_phy_m88;
2283	break;
2284	case IGP01E1000_I_PHY_ID: / IGP 1 & 2 share this /
2285	phy_type = e1000_phy_igp_2;
2286	break;
2287	case GG82563_E_PHY_ID:
2288	phy_type = e1000_phy_gg82563;
2289	break;
2290	case IGP03E1000_E_PHY_ID:
2291	phy_type = e1000_phy_igp_3;
2292	break;
2293	case IFE_E_PHY_ID:
2294	case IFE_PLUS_E_PHY_ID:
2295	case IFE_C_E_PHY_ID:
2296	phy_type = e1000_phy_ife;
2297	break;
2298	case BME1000_E_PHY_ID:
2299	case BME1000_E_PHY_ID_R2:
2300	phy_type = e1000_phy_bm;
2301	break;
2302	case I82578_E_PHY_ID:
2303	phy_type = e1000_phy_82578;
2304	break;
2305	case I82577_E_PHY_ID:
2306	phy_type = e1000_phy_82577;
2307	break;
2308	case I82579_E_PHY_ID:
2309	phy_type = e1000_phy_82579;
2310	break;
2311	case I217_E_PHY_ID:
2312	phy_type = e1000_phy_i217;
2313	break;
2314	default:
2315	phy_type = e1000_phy_unknown;
2316	break;
2317	}
2318	return phy_type;
2319	}
2320
2321	/**
2322	* e1000e_determine_phy_address - Determines PHY address.
2323	* @hw: pointer to the HW structure
2324	*
2325	* This uses a trial and error method to loop through possible PHY
2326	* addresses. It tests each by reading the PHY ID registers and
2327	* checking for a match.
2328	**/
2329	s32 e1000e_determine_phy_address(struct e1000_hw *hw)
2330	{
2331	u32 phy_addr = `0`;
2332	u32 i;
2333	enum e1000_phy_type phy_type = e1000_phy_unknown;
2334
2335	hw->phy.id = phy_type;
2336
2337	for (phy_addr = `0`; phy_addr < E1000_MAX_PHY_ADDR; phy_addr++) {
2338	hw->phy.addr = phy_addr;
2339	i = `0`;
2340
2341	do {
2342	e1000e_get_phy_id(hw);
2343	phy_type = e1000e_get_phy_type_from_id(phy_id: hw->phy.id);
2344
2345	/ If phy_type is valid, break - we found our*
2346	* PHY address
2347	*/
2348	if (phy_type != e1000_phy_unknown)
2349	return `0`;
2350
2351	usleep_range(min: `1000`, max: `2000`);
2352	i++;
2353	} while (i < `10`);
2354	}
2355
2356	return -E1000_ERR_PHY_TYPE;
2357	}
2358
2359	/**
2360	* e1000_get_phy_addr_for_bm_page - Retrieve PHY page address
2361	* @page: page to access
2362	* @reg: register to check
2363	*
2364	* Returns the phy address for the page requested.
2365	**/
2366	static u32 e1000_get_phy_addr_for_bm_page(u32 page, u32 reg)
2367	{
2368	u32 phy_addr = `2`;
2369
2370	if ((page >= `768`) \|\| (page == `0` && reg == `25`) \|\| (reg == `31`))
2371	phy_addr = `1`;
2372
2373	return phy_addr;
2374	}
2375
2376	/**
2377	* e1000e_write_phy_reg_bm - Write BM PHY register
2378	* @hw: pointer to the HW structure
2379	* @offset: register offset to write to
2380	* @data: data to write at register offset
2381	*
2382	* Acquires semaphore, if necessary, then writes the data to PHY register
2383	* at the offset. Release any acquired semaphores before exiting.
2384	**/
2385	s32 e1000e_write_phy_reg_bm(struct e1000_hw *hw, u32 offset, u16 data)
2386	{
2387	s32 ret_val;
2388	u32 page = offset >> IGP_PAGE_SHIFT;
2389
2390	ret_val = hw->phy.ops.acquire(hw);
2391	if (ret_val)
2392	return ret_val;
2393
2394	/ Page 800 works differently than the rest so it has its own func /
2395	if (page == BM_WUC_PAGE) {
2396	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data: &data,
2397	read: false, page_set: false);
2398	goto release;
2399	}
2400
2401	hw->phy.addr = e1000_get_phy_addr_for_bm_page(page, reg: offset);
2402
2403	if (offset > MAX_PHY_MULTI_PAGE_REG) {
2404	u32 page_shift, page_select;
2405
2406	/ Page select is register 31 for phy address 1 and 22 for*
2407	* phy address 2 and 3. Page select is shifted only for
2408	* phy address 1.
2409	*/
2410	if (hw->phy.addr == `1`) {
2411	page_shift = IGP_PAGE_SHIFT;
2412	page_select = IGP01E1000_PHY_PAGE_SELECT;
2413	} else {
2414	page_shift = `0`;
2415	page_select = BM_PHY_PAGE_SELECT;
2416	}
2417
2418	/ Page is shifted left, PHY expects (page x 32) /
2419	ret_val = e1000e_write_phy_reg_mdic(hw, offset: page_select,
2420	data: (page << page_shift));
2421	if (ret_val)
2422	goto release;
2423	}
2424
2425	ret_val = e1000e_write_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
2426	data);
2427
2428	release:
2429	hw->phy.ops.release(hw);
2430	return ret_val;
2431	}
2432
2433	/**
2434	* e1000e_read_phy_reg_bm - Read BM PHY register
2435	* @hw: pointer to the HW structure
2436	* @offset: register offset to be read
2437	* @data: pointer to the read data
2438	*
2439	* Acquires semaphore, if necessary, then reads the PHY register at offset
2440	* and storing the retrieved information in data. Release any acquired
2441	* semaphores before exiting.
2442	**/
2443	s32 e1000e_read_phy_reg_bm(struct e1000_hw hw, u32 offset, u16 data)
2444	{
2445	s32 ret_val;
2446	u32 page = offset >> IGP_PAGE_SHIFT;
2447
2448	ret_val = hw->phy.ops.acquire(hw);
2449	if (ret_val)
2450	return ret_val;
2451
2452	/ Page 800 works differently than the rest so it has its own func /
2453	if (page == BM_WUC_PAGE) {
2454	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data,
2455	read: true, page_set: false);
2456	goto release;
2457	}
2458
2459	hw->phy.addr = e1000_get_phy_addr_for_bm_page(page, reg: offset);
2460
2461	if (offset > MAX_PHY_MULTI_PAGE_REG) {
2462	u32 page_shift, page_select;
2463
2464	/ Page select is register 31 for phy address 1 and 22 for*
2465	* phy address 2 and 3. Page select is shifted only for
2466	* phy address 1.
2467	*/
2468	if (hw->phy.addr == `1`) {
2469	page_shift = IGP_PAGE_SHIFT;
2470	page_select = IGP01E1000_PHY_PAGE_SELECT;
2471	} else {
2472	page_shift = `0`;
2473	page_select = BM_PHY_PAGE_SELECT;
2474	}
2475
2476	/ Page is shifted left, PHY expects (page x 32) /
2477	ret_val = e1000e_write_phy_reg_mdic(hw, offset: page_select,
2478	data: (page << page_shift));
2479	if (ret_val)
2480	goto release;
2481	}
2482
2483	ret_val = e1000e_read_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
2484	data);
2485	release:
2486	hw->phy.ops.release(hw);
2487	return ret_val;
2488	}
2489
2490	/**
2491	* e1000e_read_phy_reg_bm2 - Read BM PHY register
2492	* @hw: pointer to the HW structure
2493	* @offset: register offset to be read
2494	* @data: pointer to the read data
2495	*
2496	* Acquires semaphore, if necessary, then reads the PHY register at offset
2497	* and storing the retrieved information in data. Release any acquired
2498	* semaphores before exiting.
2499	**/
2500	s32 e1000e_read_phy_reg_bm2(struct e1000_hw hw, u32 offset, u16 data)
2501	{
2502	s32 ret_val;
2503	u16 page = (u16)(offset >> IGP_PAGE_SHIFT);
2504
2505	ret_val = hw->phy.ops.acquire(hw);
2506	if (ret_val)
2507	return ret_val;
2508
2509	/ Page 800 works differently than the rest so it has its own func /
2510	if (page == BM_WUC_PAGE) {
2511	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data,
2512	read: true, page_set: false);
2513	goto release;
2514	}
2515
2516	hw->phy.addr = `1`;
2517
2518	if (offset > MAX_PHY_MULTI_PAGE_REG) {
2519	/ Page is shifted left, PHY expects (page x 32) /
2520	ret_val = e1000e_write_phy_reg_mdic(hw, BM_PHY_PAGE_SELECT,
2521	data: page);
2522
2523	if (ret_val)
2524	goto release;
2525	}
2526
2527	ret_val = e1000e_read_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
2528	data);
2529	release:
2530	hw->phy.ops.release(hw);
2531	return ret_val;
2532	}
2533
2534	/**
2535	* e1000e_write_phy_reg_bm2 - Write BM PHY register
2536	* @hw: pointer to the HW structure
2537	* @offset: register offset to write to
2538	* @data: data to write at register offset
2539	*
2540	* Acquires semaphore, if necessary, then writes the data to PHY register
2541	* at the offset. Release any acquired semaphores before exiting.
2542	**/
2543	s32 e1000e_write_phy_reg_bm2(struct e1000_hw *hw, u32 offset, u16 data)
2544	{
2545	s32 ret_val;
2546	u16 page = (u16)(offset >> IGP_PAGE_SHIFT);
2547
2548	ret_val = hw->phy.ops.acquire(hw);
2549	if (ret_val)
2550	return ret_val;
2551
2552	/ Page 800 works differently than the rest so it has its own func /
2553	if (page == BM_WUC_PAGE) {
2554	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data: &data,
2555	read: false, page_set: false);
2556	goto release;
2557	}
2558
2559	hw->phy.addr = `1`;
2560
2561	if (offset > MAX_PHY_MULTI_PAGE_REG) {
2562	/ Page is shifted left, PHY expects (page x 32) /
2563	ret_val = e1000e_write_phy_reg_mdic(hw, BM_PHY_PAGE_SELECT,
2564	data: page);
2565
2566	if (ret_val)
2567	goto release;
2568	}
2569
2570	ret_val = e1000e_write_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & offset,
2571	data);
2572
2573	release:
2574	hw->phy.ops.release(hw);
2575	return ret_val;
2576	}
2577
2578	/**
2579	* e1000_enable_phy_wakeup_reg_access_bm - enable access to BM wakeup registers
2580	* @hw: pointer to the HW structure
2581	* @phy_reg: pointer to store original contents of BM_WUC_ENABLE_REG
2582	*
2583	* Assumes semaphore already acquired and phy_reg points to a valid memory
2584	* address to store contents of the BM_WUC_ENABLE_REG register.
2585	**/
2586	s32 e1000_enable_phy_wakeup_reg_access_bm(struct e1000_hw hw, u16 phy_reg)
2587	{
2588	s32 ret_val;
2589	u16 temp;
2590
2591	/ All page select, port ctrl and wakeup registers use phy address 1 /
2592	hw->phy.addr = `1`;
2593
2594	/ Select Port Control Registers page /
2595	ret_val = e1000_set_page_igp(hw, page: (BM_PORT_CTRL_PAGE << IGP_PAGE_SHIFT));
2596	if (ret_val) {
2597	e_dbg("Could not set Port Control page\n");
2598	return ret_val;
2599	}
2600
2601	ret_val = e1000e_read_phy_reg_mdic(hw, BM_WUC_ENABLE_REG, data: phy_reg);
2602	if (ret_val) {
2603	e_dbg("Could not read PHY register %d.%d\n",
2604	BM_PORT_CTRL_PAGE, BM_WUC_ENABLE_REG);
2605	return ret_val;
2606	}
2607
2608	/ Enable both PHY wakeup mode and Wakeup register page writes.*
2609	* Prevent a power state change by disabling ME and Host PHY wakeup.
2610	*/
2611	temp = *phy_reg;
2612	temp \|= BM_WUC_ENABLE_BIT;
2613	temp &= ~(BM_WUC_ME_WU_BIT \| BM_WUC_HOST_WU_BIT);
2614
2615	ret_val = e1000e_write_phy_reg_mdic(hw, BM_WUC_ENABLE_REG, data: temp);
2616	if (ret_val) {
2617	e_dbg("Could not write PHY register %d.%d\n",
2618	BM_PORT_CTRL_PAGE, BM_WUC_ENABLE_REG);
2619	return ret_val;
2620	}
2621
2622	/ Select Host Wakeup Registers page - caller now able to write*
2623	* registers on the Wakeup registers page
2624	*/
2625	return e1000_set_page_igp(hw, page: (BM_WUC_PAGE << IGP_PAGE_SHIFT));
2626	}
2627
2628	/**
2629	* e1000_disable_phy_wakeup_reg_access_bm - disable access to BM wakeup regs
2630	* @hw: pointer to the HW structure
2631	* @phy_reg: pointer to original contents of BM_WUC_ENABLE_REG
2632	*
2633	* Restore BM_WUC_ENABLE_REG to its original value.
2634	*
2635	* Assumes semaphore already acquired and *phy_reg is the contents of the
2636	* BM_WUC_ENABLE_REG before register(s) on BM_WUC_PAGE were accessed by
2637	* caller.
2638	**/
2639	s32 e1000_disable_phy_wakeup_reg_access_bm(struct e1000_hw hw, u16 phy_reg)
2640	{
2641	s32 ret_val;
2642
2643	/ Select Port Control Registers page /
2644	ret_val = e1000_set_page_igp(hw, page: (BM_PORT_CTRL_PAGE << IGP_PAGE_SHIFT));
2645	if (ret_val) {
2646	e_dbg("Could not set Port Control page\n");
2647	return ret_val;
2648	}
2649
2650	/ Restore 769.17 to its original value /
2651	ret_val = e1000e_write_phy_reg_mdic(hw, BM_WUC_ENABLE_REG, data: *phy_reg);
2652	if (ret_val)
2653	e_dbg("Could not restore PHY register %d.%d\n",
2654	BM_PORT_CTRL_PAGE, BM_WUC_ENABLE_REG);
2655
2656	return ret_val;
2657	}
2658
2659	/**
2660	* e1000_access_phy_wakeup_reg_bm - Read/write BM PHY wakeup register
2661	* @hw: pointer to the HW structure
2662	* @offset: register offset to be read or written
2663	* @data: pointer to the data to read or write
2664	* @read: determines if operation is read or write
2665	* @page_set: BM_WUC_PAGE already set and access enabled
2666	*
2667	* Read the PHY register at offset and store the retrieved information in
2668	* data, or write data to PHY register at offset. Note the procedure to
2669	* access the PHY wakeup registers is different than reading the other PHY
2670	* registers. It works as such:
2671	* 1) Set 769.17.2 (page 769, register 17, bit 2) = 1
2672	* 2) Set page to 800 for host (801 if we were manageability)
2673	* 3) Write the address using the address opcode (0x11)
2674	* 4) Read or write the data using the data opcode (0x12)
2675	* 5) Restore 769.17.2 to its original value
2676	*
2677	* Steps 1 and 2 are done by e1000_enable_phy_wakeup_reg_access_bm() and
2678	* step 5 is done by e1000_disable_phy_wakeup_reg_access_bm().
2679	*
2680	* Assumes semaphore is already acquired. When page_set==true, assumes
2681	* the PHY page is set to BM_WUC_PAGE (i.e. a function in the call stack
2682	* is responsible for calls to e1000_[enable\|disable]_phy_wakeup_reg_bm()).
2683	**/
2684	static s32 e1000_access_phy_wakeup_reg_bm(struct e1000_hw *hw, u32 offset,
2685	u16 *data, bool read, bool page_set)
2686	{
2687	s32 ret_val;
2688	u16 reg = BM_PHY_REG_NUM(offset);
2689	u16 page = BM_PHY_REG_PAGE(offset);
2690	u16 phy_reg = `0`;
2691
2692	/ Gig must be disabled for MDIO accesses to Host Wakeup reg page /
2693	if ((hw->mac.type == e1000_pchlan) &&
2694	(!(er32(PHY_CTRL) & E1000_PHY_CTRL_GBE_DISABLE)))
2695	e_dbg("Attempting to access page %d while gig enabled.\n",
2696	page);
2697
2698	if (!page_set) {
2699	/ Enable access to PHY wakeup registers /
2700	ret_val = e1000_enable_phy_wakeup_reg_access_bm(hw, phy_reg: &phy_reg);
2701	if (ret_val) {
2702	e_dbg("Could not enable PHY wakeup reg access\n");
2703	return ret_val;
2704	}
2705	}
2706
2707	e_dbg("Accessing PHY page %d reg 0x%x\n", page, reg);
2708
2709	/ Write the Wakeup register page offset value using opcode 0x11 /
2710	ret_val = e1000e_write_phy_reg_mdic(hw, BM_WUC_ADDRESS_OPCODE, data: reg);
2711	if (ret_val) {
2712	e_dbg("Could not write address opcode to page %d\n", page);
2713	return ret_val;
2714	}
2715
2716	if (read) {
2717	/ Read the Wakeup register page value using opcode 0x12 /
2718	ret_val = e1000e_read_phy_reg_mdic(hw, BM_WUC_DATA_OPCODE,
2719	data);
2720	} else {
2721	/ Write the Wakeup register page value using opcode 0x12 /
2722	ret_val = e1000e_write_phy_reg_mdic(hw, BM_WUC_DATA_OPCODE,
2723	data: *data);
2724	}
2725
2726	if (ret_val) {
2727	e_dbg("Could not access PHY reg %d.%d\n", page, reg);
2728	return ret_val;
2729	}
2730
2731	if (!page_set)
2732	ret_val = e1000_disable_phy_wakeup_reg_access_bm(hw, phy_reg: &phy_reg);
2733
2734	return ret_val;
2735	}
2736
2737	/**
2738	* e1000_power_up_phy_copper - Restore copper link in case of PHY power down
2739	* @hw: pointer to the HW structure
2740	*
2741	* In the case of a PHY power down to save power, or to turn off link during a
2742	* driver unload, or wake on lan is not enabled, restore the link to previous
2743	* settings.
2744	**/
2745	void e1000_power_up_phy_copper(struct e1000_hw *hw)
2746	{
2747	u16 mii_reg = `0`;
2748	int ret;
2749
2750	/ The PHY will retain its settings across a power down/up cycle /
2751	ret = e1e_rphy(hw, MII_BMCR, data: &mii_reg);
2752	if (ret) {
2753	e_dbg("Error reading PHY register\n");
2754	return;
2755	}
2756	mii_reg &= ~BMCR_PDOWN;
2757	e1e_wphy(hw, MII_BMCR, data: mii_reg);
2758	}
2759
2760	/**
2761	* e1000_power_down_phy_copper - Restore copper link in case of PHY power down
2762	* @hw: pointer to the HW structure
2763	*
2764	* In the case of a PHY power down to save power, or to turn off link during a
2765	* driver unload, or wake on lan is not enabled, restore the link to previous
2766	* settings.
2767	**/
2768	void e1000_power_down_phy_copper(struct e1000_hw *hw)
2769	{
2770	u16 mii_reg = `0`;
2771	int ret;
2772
2773	/ The PHY will retain its settings across a power down/up cycle /
2774	ret = e1e_rphy(hw, MII_BMCR, data: &mii_reg);
2775	if (ret) {
2776	e_dbg("Error reading PHY register\n");
2777	return;
2778	}
2779	mii_reg \|= BMCR_PDOWN;
2780	e1e_wphy(hw, MII_BMCR, data: mii_reg);
2781	usleep_range(min: `1000`, max: `2000`);
2782	}
2783
2784	/**
2785	* __e1000_read_phy_reg_hv - Read HV PHY register
2786	* @hw: pointer to the HW structure
2787	* @offset: register offset to be read
2788	* @data: pointer to the read data
2789	* @locked: semaphore has already been acquired or not
2790	* @page_set: BM_WUC_PAGE already set and access enabled
2791	*
2792	* Acquires semaphore, if necessary, then reads the PHY register at offset
2793	* and stores the retrieved information in data. Release any acquired
2794	* semaphore before exiting.
2795	**/
2796	static s32 __e1000_read_phy_reg_hv(struct e1000_hw hw, u32 offset, u16 data,
2797	bool locked, bool page_set)
2798	{
2799	s32 ret_val;
2800	u16 page = BM_PHY_REG_PAGE(offset);
2801	u16 reg = BM_PHY_REG_NUM(offset);
2802	u32 phy_addr = hw->phy.addr = e1000_get_phy_addr_for_hv_page(page);
2803
2804	if (!locked) {
2805	ret_val = hw->phy.ops.acquire(hw);
2806	if (ret_val)
2807	return ret_val;
2808	}
2809
2810	/ Page 800 works differently than the rest so it has its own func /
2811	if (page == BM_WUC_PAGE) {
2812	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data,
2813	read: true, page_set);
2814	goto out;
2815	}
2816
2817	if (page > `0` && page < HV_INTC_FC_PAGE_START) {
2818	ret_val = e1000_access_phy_debug_regs_hv(hw, offset,
2819	data, read: true);
2820	goto out;
2821	}
2822
2823	if (!page_set) {
2824	if (page == HV_INTC_FC_PAGE_START)
2825	page = `0`;
2826
2827	if (reg > MAX_PHY_MULTI_PAGE_REG) {
2828	/ Page is shifted left, PHY expects (page x 32) /
2829	ret_val = e1000_set_page_igp(hw,
2830	page: (page << IGP_PAGE_SHIFT));
2831
2832	hw->phy.addr = phy_addr;
2833
2834	if (ret_val)
2835	goto out;
2836	}
2837	}
2838
2839	e_dbg("reading PHY page %d (or 0x%x shifted) reg 0x%x\n", page,
2840	page << IGP_PAGE_SHIFT, reg);
2841
2842	ret_val = e1000e_read_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & reg, data);
2843	out:
2844	if (!locked)
2845	hw->phy.ops.release(hw);
2846
2847	return ret_val;
2848	}
2849
2850	/**
2851	* e1000_read_phy_reg_hv - Read HV PHY register
2852	* @hw: pointer to the HW structure
2853	* @offset: register offset to be read
2854	* @data: pointer to the read data
2855	*
2856	* Acquires semaphore then reads the PHY register at offset and stores
2857	* the retrieved information in data. Release the acquired semaphore
2858	* before exiting.
2859	**/
2860	s32 e1000_read_phy_reg_hv(struct e1000_hw hw, u32 offset, u16 data)
2861	{
2862	return __e1000_read_phy_reg_hv(hw, offset, data, locked: false, page_set: false);
2863	}
2864
2865	/**
2866	* e1000_read_phy_reg_hv_locked - Read HV PHY register
2867	* @hw: pointer to the HW structure
2868	* @offset: register offset to be read
2869	* @data: pointer to the read data
2870	*
2871	* Reads the PHY register at offset and stores the retrieved information
2872	* in data. Assumes semaphore already acquired.
2873	**/
2874	s32 e1000_read_phy_reg_hv_locked(struct e1000_hw hw, u32 offset, u16 data)
2875	{
2876	return __e1000_read_phy_reg_hv(hw, offset, data, locked: true, page_set: false);
2877	}
2878
2879	/**
2880	* e1000_read_phy_reg_page_hv - Read HV PHY register
2881	* @hw: pointer to the HW structure
2882	* @offset: register offset to write to
2883	* @data: data to write at register offset
2884	*
2885	* Reads the PHY register at offset and stores the retrieved information
2886	* in data. Assumes semaphore already acquired and page already set.
2887	**/
2888	s32 e1000_read_phy_reg_page_hv(struct e1000_hw hw, u32 offset, u16 data)
2889	{
2890	return __e1000_read_phy_reg_hv(hw, offset, data, locked: true, page_set: true);
2891	}
2892
2893	/**
2894	* __e1000_write_phy_reg_hv - Write HV PHY register
2895	* @hw: pointer to the HW structure
2896	* @offset: register offset to write to
2897	* @data: data to write at register offset
2898	* @locked: semaphore has already been acquired or not
2899	* @page_set: BM_WUC_PAGE already set and access enabled
2900	*
2901	* Acquires semaphore, if necessary, then writes the data to PHY register
2902	* at the offset. Release any acquired semaphores before exiting.
2903	**/
2904	static s32 __e1000_write_phy_reg_hv(struct e1000_hw *hw, u32 offset, u16 data,
2905	bool locked, bool page_set)
2906	{
2907	s32 ret_val;
2908	u16 page = BM_PHY_REG_PAGE(offset);
2909	u16 reg = BM_PHY_REG_NUM(offset);
2910	u32 phy_addr = hw->phy.addr = e1000_get_phy_addr_for_hv_page(page);
2911
2912	if (!locked) {
2913	ret_val = hw->phy.ops.acquire(hw);
2914	if (ret_val)
2915	return ret_val;
2916	}
2917
2918	/ Page 800 works differently than the rest so it has its own func /
2919	if (page == BM_WUC_PAGE) {
2920	ret_val = e1000_access_phy_wakeup_reg_bm(hw, offset, data: &data,
2921	read: false, page_set);
2922	goto out;
2923	}
2924
2925	if (page > `0` && page < HV_INTC_FC_PAGE_START) {
2926	ret_val = e1000_access_phy_debug_regs_hv(hw, offset,
2927	data: &data, read: false);
2928	goto out;
2929	}
2930
2931	if (!page_set) {
2932	if (page == HV_INTC_FC_PAGE_START)
2933	page = `0`;
2934
2935	/ Workaround MDIO accesses being disabled after entering IEEE*
2936	* Power Down (when bit 11 of the PHY Control register is set)
2937	*/
2938	if ((hw->phy.type == e1000_phy_82578) &&
2939	(hw->phy.revision >= `1`) &&
2940	(hw->phy.addr == `2`) &&
2941	!(MAX_PHY_REG_ADDRESS & reg) && (data & BIT(`11`))) {
2942	u16 data2 = `0x7EFF`;
2943
2944	ret_val = e1000_access_phy_debug_regs_hv(hw,
2945	BIT(`6`) \| `0x3`,
2946	data: &data2, read: false);
2947	if (ret_val)
2948	goto out;
2949	}
2950
2951	if (reg > MAX_PHY_MULTI_PAGE_REG) {
2952	/ Page is shifted left, PHY expects (page x 32) /
2953	ret_val = e1000_set_page_igp(hw,
2954	page: (page << IGP_PAGE_SHIFT));
2955
2956	hw->phy.addr = phy_addr;
2957
2958	if (ret_val)
2959	goto out;
2960	}
2961	}
2962
2963	e_dbg("writing PHY page %d (or 0x%x shifted) reg 0x%x\n", page,
2964	page << IGP_PAGE_SHIFT, reg);
2965
2966	ret_val = e1000e_write_phy_reg_mdic(hw, MAX_PHY_REG_ADDRESS & reg,
2967	data);
2968
2969	out:
2970	if (!locked)
2971	hw->phy.ops.release(hw);
2972
2973	return ret_val;
2974	}
2975
2976	/**
2977	* e1000_write_phy_reg_hv - Write HV PHY register
2978	* @hw: pointer to the HW structure
2979	* @offset: register offset to write to
2980	* @data: data to write at register offset
2981	*
2982	* Acquires semaphore then writes the data to PHY register at the offset.
2983	* Release the acquired semaphores before exiting.
2984	**/
2985	s32 e1000_write_phy_reg_hv(struct e1000_hw *hw, u32 offset, u16 data)
2986	{
2987	return __e1000_write_phy_reg_hv(hw, offset, data, locked: false, page_set: false);
2988	}
2989
2990	/**
2991	* e1000_write_phy_reg_hv_locked - Write HV PHY register
2992	* @hw: pointer to the HW structure
2993	* @offset: register offset to write to
2994	* @data: data to write at register offset
2995	*
2996	* Writes the data to PHY register at the offset. Assumes semaphore
2997	* already acquired.
2998	**/
2999	s32 e1000_write_phy_reg_hv_locked(struct e1000_hw *hw, u32 offset, u16 data)
3000	{
3001	return __e1000_write_phy_reg_hv(hw, offset, data, locked: true, page_set: false);
3002	}
3003
3004	/**
3005	* e1000_write_phy_reg_page_hv - Write HV PHY register
3006	* @hw: pointer to the HW structure
3007	* @offset: register offset to write to
3008	* @data: data to write at register offset
3009	*
3010	* Writes the data to PHY register at the offset. Assumes semaphore
3011	* already acquired and page already set.
3012	**/
3013	s32 e1000_write_phy_reg_page_hv(struct e1000_hw *hw, u32 offset, u16 data)
3014	{
3015	return __e1000_write_phy_reg_hv(hw, offset, data, locked: true, page_set: true);
3016	}
3017
3018	/**
3019	* e1000_get_phy_addr_for_hv_page - Get PHY address based on page
3020	* @page: page to be accessed
3021	**/
3022	static u32 e1000_get_phy_addr_for_hv_page(u32 page)
3023	{
3024	u32 phy_addr = `2`;
3025
3026	if (page >= HV_INTC_FC_PAGE_START)
3027	phy_addr = `1`;
3028
3029	return phy_addr;
3030	}
3031
3032	/**
3033	* e1000_access_phy_debug_regs_hv - Read HV PHY vendor specific high registers
3034	* @hw: pointer to the HW structure
3035	* @offset: register offset to be read or written
3036	* @data: pointer to the data to be read or written
3037	* @read: determines if operation is read or write
3038	*
3039	* Reads the PHY register at offset and stores the retrieved information
3040	* in data. Assumes semaphore already acquired. Note that the procedure
3041	* to access these regs uses the address port and data port to read/write.
3042	* These accesses done with PHY address 2 and without using pages.
3043	**/
3044	static s32 e1000_access_phy_debug_regs_hv(struct e1000_hw *hw, u32 offset,
3045	u16 *data, bool read)
3046	{
3047	s32 ret_val;
3048	u32 addr_reg;
3049	u32 data_reg;
3050
3051	/ This takes care of the difference with desktop vs mobile phy /
3052	addr_reg = ((hw->phy.type == e1000_phy_82578) ?
3053	I82578_ADDR_REG : I82577_ADDR_REG);
3054	data_reg = addr_reg + `1`;
3055
3056	/ All operations in this function are phy address 2 /
3057	hw->phy.addr = `2`;
3058
3059	/ masking with 0x3F to remove the page from offset /
3060	ret_val = e1000e_write_phy_reg_mdic(hw, offset: addr_reg, data: (u16)offset & `0x3F`);
3061	if (ret_val) {
3062	e_dbg("Could not write the Address Offset port register\n");
3063	return ret_val;
3064	}
3065
3066	/ Read or write the data value next /
3067	if (read)
3068	ret_val = e1000e_read_phy_reg_mdic(hw, offset: data_reg, data);
3069	else
3070	ret_val = e1000e_write_phy_reg_mdic(hw, offset: data_reg, data: *data);
3071
3072	if (ret_val)
3073	e_dbg("Could not access the Data port register\n");
3074
3075	return ret_val;
3076	}
3077
3078	/**
3079	* e1000_link_stall_workaround_hv - Si workaround
3080	* @hw: pointer to the HW structure
3081	*
3082	* This function works around a Si bug where the link partner can get
3083	* a link up indication before the PHY does. If small packets are sent
3084	* by the link partner they can be placed in the packet buffer without
3085	* being properly accounted for by the PHY and will stall preventing
3086	* further packets from being received. The workaround is to clear the
3087	* packet buffer after the PHY detects link up.
3088	**/
3089	s32 e1000_link_stall_workaround_hv(struct e1000_hw *hw)
3090	{
3091	s32 ret_val = `0`;
3092	u16 data;
3093
3094	if (hw->phy.type != e1000_phy_82578)
3095	return `0`;
3096
3097	/ Do not apply workaround if in PHY loopback bit 14 set /
3098	ret_val = e1e_rphy(hw, MII_BMCR, data: &data);
3099	if (ret_val) {
3100	e_dbg("Error reading PHY register\n");
3101	return ret_val;
3102	}
3103	if (data & BMCR_LOOPBACK)
3104	return `0`;
3105
3106	/ check if link is up and at 1Gbps /
3107	ret_val = e1e_rphy(hw, BM_CS_STATUS, data: &data);
3108	if (ret_val)
3109	return ret_val;
3110
3111	data &= (BM_CS_STATUS_LINK_UP \| BM_CS_STATUS_RESOLVED \|
3112	BM_CS_STATUS_SPEED_MASK);
3113
3114	if (data != (BM_CS_STATUS_LINK_UP \| BM_CS_STATUS_RESOLVED \|
3115	BM_CS_STATUS_SPEED_1000))
3116	return `0`;
3117
3118	msleep(msecs: `200`);
3119
3120	/ flush the packets in the fifo buffer /
3121	ret_val = e1e_wphy(hw, HV_MUX_DATA_CTRL,
3122	data: (HV_MUX_DATA_CTRL_GEN_TO_MAC \|
3123	HV_MUX_DATA_CTRL_FORCE_SPEED));
3124	if (ret_val)
3125	return ret_val;
3126
3127	return e1e_wphy(hw, HV_MUX_DATA_CTRL, HV_MUX_DATA_CTRL_GEN_TO_MAC);
3128	}
3129
3130	/**
3131	* e1000_check_polarity_82577 - Checks the polarity.
3132	* @hw: pointer to the HW structure
3133	*
3134	* Success returns 0, Failure returns -E1000_ERR_PHY (-2)
3135	*
3136	* Polarity is determined based on the PHY specific status register.
3137	**/
3138	s32 e1000_check_polarity_82577(struct e1000_hw *hw)
3139	{
3140	struct e1000_phy_info *phy = &hw->phy;
3141	s32 ret_val;
3142	u16 data;
3143
3144	ret_val = e1e_rphy(hw, I82577_PHY_STATUS_2, data: &data);
3145
3146	if (!ret_val)
3147	phy->cable_polarity = ((data & I82577_PHY_STATUS2_REV_POLARITY)
3148	? e1000_rev_polarity_reversed
3149	: e1000_rev_polarity_normal);
3150
3151	return ret_val;
3152	}
3153
3154	/**
3155	* e1000_phy_force_speed_duplex_82577 - Force speed/duplex for I82577 PHY
3156	* @hw: pointer to the HW structure
3157	*
3158	* Calls the PHY setup function to force speed and duplex.
3159	**/
3160	s32 e1000_phy_force_speed_duplex_82577(struct e1000_hw *hw)
3161	{
3162	struct e1000_phy_info *phy = &hw->phy;
3163	s32 ret_val;
3164	u16 phy_data;
3165	bool link;
3166
3167	ret_val = e1e_rphy(hw, MII_BMCR, data: &phy_data);
3168	if (ret_val)
3169	return ret_val;
3170
3171	e1000e_phy_force_speed_duplex_setup(hw, phy_ctrl: &phy_data);
3172
3173	ret_val = e1e_wphy(hw, MII_BMCR, data: phy_data);
3174	if (ret_val)
3175	return ret_val;
3176
3177	udelay(usec: `1`);
3178
3179	if (phy->autoneg_wait_to_complete) {
3180	e_dbg("Waiting for forced speed/duplex link on 82577 phy\n");
3181
3182	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
3183	usec_interval: `100000`, success: &link);
3184	if (ret_val)
3185	return ret_val;
3186
3187	if (!link)
3188	e_dbg("Link taking longer than expected.\n");
3189
3190	/ Try once more /
3191	ret_val = e1000e_phy_has_link_generic(hw, PHY_FORCE_LIMIT,
3192	usec_interval: `100000`, success: &link);
3193	}
3194
3195	return ret_val;
3196	}
3197
3198	/**
3199	* e1000_get_phy_info_82577 - Retrieve I82577 PHY information
3200	* @hw: pointer to the HW structure
3201	*
3202	* Read PHY status to determine if link is up. If link is up, then
3203	* set/determine 10base-T extended distance and polarity correction. Read
3204	* PHY port status to determine MDI/MDIx and speed. Based on the speed,
3205	* determine on the cable length, local and remote receiver.
3206	**/
3207	s32 e1000_get_phy_info_82577(struct e1000_hw *hw)
3208	{
3209	struct e1000_phy_info *phy = &hw->phy;
3210	s32 ret_val;
3211	u16 data;
3212	bool link;
3213
3214	ret_val = e1000e_phy_has_link_generic(hw, iterations: `1`, usec_interval: `0`, success: &link);
3215	if (ret_val)
3216	return ret_val;
3217
3218	if (!link) {
3219	e_dbg("Phy info is only valid if link is up\n");
3220	return -E1000_ERR_CONFIG;
3221	}
3222
3223	phy->polarity_correction = true;
3224
3225	ret_val = e1000_check_polarity_82577(hw);
3226	if (ret_val)
3227	return ret_val;
3228
3229	ret_val = e1e_rphy(hw, I82577_PHY_STATUS_2, data: &data);
3230	if (ret_val)
3231	return ret_val;
3232
3233	phy->is_mdix = !!(data & I82577_PHY_STATUS2_MDIX);
3234
3235	if ((data & I82577_PHY_STATUS2_SPEED_MASK) ==
3236	I82577_PHY_STATUS2_SPEED_1000MBPS) {
3237	ret_val = hw->phy.ops.get_cable_length(hw);
3238	if (ret_val)
3239	return ret_val;
3240
3241	ret_val = e1e_rphy(hw, MII_STAT1000, data: &data);
3242	if (ret_val)
3243	return ret_val;
3244
3245	phy->local_rx = (data & LPA_1000LOCALRXOK)
3246	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
3247
3248	phy->remote_rx = (data & LPA_1000REMRXOK)
3249	? e1000_1000t_rx_status_ok : e1000_1000t_rx_status_not_ok;
3250	} else {
3251	phy->cable_length = E1000_CABLE_LENGTH_UNDEFINED;
3252	phy->local_rx = e1000_1000t_rx_status_undefined;
3253	phy->remote_rx = e1000_1000t_rx_status_undefined;
3254	}
3255
3256	return `0`;
3257	}
3258
3259	/**
3260	* e1000_get_cable_length_82577 - Determine cable length for 82577 PHY
3261	* @hw: pointer to the HW structure
3262	*
3263	* Reads the diagnostic status register and verifies result is valid before
3264	* placing it in the phy_cable_length field.
3265	**/
3266	s32 e1000_get_cable_length_82577(struct e1000_hw *hw)
3267	{
3268	struct e1000_phy_info *phy = &hw->phy;
3269	s32 ret_val;
3270	u16 phy_data, length;
3271
3272	ret_val = e1e_rphy(hw, I82577_PHY_DIAG_STATUS, data: &phy_data);
3273	if (ret_val)
3274	return ret_val;
3275
3276	length = FIELD_GET(I82577_DSTATUS_CABLE_LENGTH, phy_data);
3277
3278	if (length == E1000_CABLE_LENGTH_UNDEFINED)
3279	return -E1000_ERR_PHY;
3280
3281	phy->cable_length = length;
3282
3283	return `0`;
3284	}
3285

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