1 // SPDX-License-Identifier: GPL-2.0
2 // Copyright (c) 2023 Pengutronix, Oleksij Rempel <kernel@pengutronix.de>
3
4 /* Access Control List (ACL) structure:
5 *
6 * There are multiple groups of registers involved in ACL configuration:
7 *
8 * - Matching Rules: These registers define the criteria for matching incoming
9 * packets based on their header information (Layer 2 MAC, Layer 3 IP, or
10 * Layer 4 TCP/UDP). Different register settings are used depending on the
11 * matching rule mode (MD) and the Enable (ENB) settings.
12 *
13 * - Action Rules: These registers define how the ACL should modify the packet's
14 * priority, VLAN tag priority, and forwarding map once a matching rule has
15 * been triggered. The settings vary depending on whether the matching rule is
16 * in Count Mode (MD = 01 and ENB = 00) or not.
17 *
18 * - Processing Rules: These registers control the overall behavior of the ACL,
19 * such as selecting which matching rule to apply first, enabling/disabling
20 * specific rules, or specifying actions for matched packets.
21 *
22 * ACL Structure:
23 * +----------------------+
24 * +----------------------+ | (optional) |
25 * | Matching Rules | | Matching Rules |
26 * | (Layer 2, 3, 4) | | (Layer 2, 3, 4) |
27 * +----------------------+ +----------------------+
28 * | |
29 * \___________________________/
30 * v
31 * +----------------------+
32 * | Processing Rules |
33 * | (action idx, |
34 * | matching rule set) |
35 * +----------------------+
36 * |
37 * v
38 * +----------------------+
39 * | Action Rules |
40 * | (Modify Priority, |
41 * | Forwarding Map, |
42 * | VLAN tag, etc) |
43 * +----------------------+
44 */
45
46 #include <linux/bitops.h>
47
48 #include "ksz9477.h"
49 #include "ksz9477_reg.h"
50 #include "ksz_common.h"
51
52 #define KSZ9477_PORT_ACL_0 0x600
53
54 enum ksz9477_acl_port_access {
55 KSZ9477_ACL_PORT_ACCESS_0 = 0x00,
56 KSZ9477_ACL_PORT_ACCESS_1 = 0x01,
57 KSZ9477_ACL_PORT_ACCESS_2 = 0x02,
58 KSZ9477_ACL_PORT_ACCESS_3 = 0x03,
59 KSZ9477_ACL_PORT_ACCESS_4 = 0x04,
60 KSZ9477_ACL_PORT_ACCESS_5 = 0x05,
61 KSZ9477_ACL_PORT_ACCESS_6 = 0x06,
62 KSZ9477_ACL_PORT_ACCESS_7 = 0x07,
63 KSZ9477_ACL_PORT_ACCESS_8 = 0x08,
64 KSZ9477_ACL_PORT_ACCESS_9 = 0x09,
65 KSZ9477_ACL_PORT_ACCESS_A = 0x0A,
66 KSZ9477_ACL_PORT_ACCESS_B = 0x0B,
67 KSZ9477_ACL_PORT_ACCESS_C = 0x0C,
68 KSZ9477_ACL_PORT_ACCESS_D = 0x0D,
69 KSZ9477_ACL_PORT_ACCESS_E = 0x0E,
70 KSZ9477_ACL_PORT_ACCESS_F = 0x0F,
71 KSZ9477_ACL_PORT_ACCESS_10 = 0x10,
72 KSZ9477_ACL_PORT_ACCESS_11 = 0x11
73 };
74
75 #define KSZ9477_ACL_MD_MASK GENMASK(5, 4)
76 #define KSZ9477_ACL_MD_DISABLE 0
77 #define KSZ9477_ACL_MD_L2_MAC 1
78 #define KSZ9477_ACL_MD_L3_IP 2
79 #define KSZ9477_ACL_MD_L4_TCP_UDP 3
80
81 #define KSZ9477_ACL_ENB_MASK GENMASK(3, 2)
82 #define KSZ9477_ACL_ENB_L2_COUNTER 0
83 #define KSZ9477_ACL_ENB_L2_TYPE 1
84 #define KSZ9477_ACL_ENB_L2_MAC 2
85 #define KSZ9477_ACL_ENB_L2_MAC_TYPE 3
86
87 /* only IPv4 src or dst can be used with mask */
88 #define KSZ9477_ACL_ENB_L3_IPV4_ADDR_MASK 1
89 /* only IPv4 src and dst can be used without mask */
90 #define KSZ9477_ACL_ENB_L3_IPV4_ADDR_SRC_DST 2
91
92 #define KSZ9477_ACL_ENB_L4_IP_PROTO 0
93 #define KSZ9477_ACL_ENB_L4_TCP_SRC_DST_PORT 1
94 #define KSZ9477_ACL_ENB_L4_UDP_SRC_DST_PORT 2
95 #define KSZ9477_ACL_ENB_L4_TCP_SEQ_NUMBER 3
96
97 #define KSZ9477_ACL_SD_SRC BIT(1)
98 #define KSZ9477_ACL_SD_DST 0
99 #define KSZ9477_ACL_EQ_EQUAL BIT(0)
100 #define KSZ9477_ACL_EQ_NOT_EQUAL 0
101
102 #define KSZ9477_ACL_PM_M GENMASK(7, 6)
103 #define KSZ9477_ACL_PM_DISABLE 0
104 #define KSZ9477_ACL_PM_HIGHER 1
105 #define KSZ9477_ACL_PM_LOWER 2
106 #define KSZ9477_ACL_PM_REPLACE 3
107 #define KSZ9477_ACL_P_M GENMASK(5, 3)
108
109 #define KSZ9477_PORT_ACL_CTRL_0 0x0612
110
111 #define KSZ9477_ACL_WRITE_DONE BIT(6)
112 #define KSZ9477_ACL_READ_DONE BIT(5)
113 #define KSZ9477_ACL_WRITE BIT(4)
114 #define KSZ9477_ACL_INDEX_M GENMASK(3, 0)
115
116 /**
117 * ksz9477_dump_acl_index - Print the ACL entry at the specified index
118 *
119 * @dev: Pointer to the ksz9477 device structure.
120 * @acle: Pointer to the ACL entry array.
121 * @index: The index of the ACL entry to print.
122 *
123 * This function prints the details of an ACL entry, located at a particular
124 * index within the ksz9477 device's ACL table. It omits printing entries that
125 * are empty.
126 *
127 * Return: 1 if the entry is non-empty and printed, 0 otherwise.
128 */
ksz9477_dump_acl_index(struct ksz_device * dev,struct ksz9477_acl_entry * acle,int index)129 static int ksz9477_dump_acl_index(struct ksz_device *dev,
130 struct ksz9477_acl_entry *acle, int index)
131 {
132 bool empty = true;
133 char buf[64];
134 u8 *entry;
135 int i;
136
137 entry = &acle[index].entry[0];
138 for (i = 0; i <= KSZ9477_ACL_PORT_ACCESS_11; i++) {
139 if (entry[i])
140 empty = false;
141
142 sprintf(buf + (i * 3), "%02x ", entry[i]);
143 }
144
145 /* no need to print empty entries */
146 if (empty)
147 return 0;
148
149 dev_err(dev->dev, " Entry %02d, prio: %02d : %s", index,
150 acle[index].prio, buf);
151
152 return 1;
153 }
154
155 /**
156 * ksz9477_dump_acl - Print ACL entries
157 *
158 * @dev: Pointer to the device structure.
159 * @acle: Pointer to the ACL entry array.
160 */
ksz9477_dump_acl(struct ksz_device * dev,struct ksz9477_acl_entry * acle)161 static void ksz9477_dump_acl(struct ksz_device *dev,
162 struct ksz9477_acl_entry *acle)
163 {
164 int count = 0;
165 int i;
166
167 for (i = 0; i < KSZ9477_ACL_MAX_ENTRIES; i++)
168 count += ksz9477_dump_acl_index(dev, acle, i);
169
170 if (count != KSZ9477_ACL_MAX_ENTRIES - 1)
171 dev_err(dev->dev, " Empty ACL entries were skipped\n");
172 }
173
174 /**
175 * ksz9477_acl_is_valid_matching_rule - Check if an ACL entry contains a valid
176 * matching rule.
177 *
178 * @entry: Pointer to ACL entry buffer
179 *
180 * This function checks if the given ACL entry buffer contains a valid
181 * matching rule by inspecting the Mode (MD) and Enable (ENB) fields.
182 *
183 * Returns: True if it's a valid matching rule, false otherwise.
184 */
ksz9477_acl_is_valid_matching_rule(u8 * entry)185 static bool ksz9477_acl_is_valid_matching_rule(u8 *entry)
186 {
187 u8 val1, md, enb;
188
189 val1 = entry[KSZ9477_ACL_PORT_ACCESS_1];
190
191 md = FIELD_GET(KSZ9477_ACL_MD_MASK, val1);
192 if (md == KSZ9477_ACL_MD_DISABLE)
193 return false;
194
195 if (md == KSZ9477_ACL_MD_L2_MAC) {
196 /* L2 counter is not support, so it is not valid rule for now */
197 enb = FIELD_GET(KSZ9477_ACL_ENB_MASK, val1);
198 if (enb == KSZ9477_ACL_ENB_L2_COUNTER)
199 return false;
200 }
201
202 return true;
203 }
204
205 /**
206 * ksz9477_acl_get_cont_entr - Get count of contiguous ACL entries and validate
207 * the matching rules.
208 * @dev: Pointer to the KSZ9477 device structure.
209 * @port: Port number.
210 * @index: Index of the starting ACL entry.
211 *
212 * Based on the KSZ9477 switch's Access Control List (ACL) system, the RuleSet
213 * in an ACL entry indicates which entries contain Matching rules linked to it.
214 * This RuleSet is represented by two registers: KSZ9477_ACL_PORT_ACCESS_E and
215 * KSZ9477_ACL_PORT_ACCESS_F. Each bit set in these registers corresponds to
216 * an entry containing a Matching rule for this RuleSet.
217 *
218 * For a single Matching rule linked, only one bit is set. However, when an
219 * entry links multiple Matching rules, forming what's termed a 'complex rule',
220 * multiple bits are set in these registers.
221 *
222 * This function checks that, for complex rules, the entries containing the
223 * linked Matching rules are contiguous in terms of their indices. It calculates
224 * and returns the number of these contiguous entries.
225 *
226 * Returns:
227 * - 0 if the entry is empty and can be safely overwritten
228 * - 1 if the entry represents a simple rule
229 * - The number of contiguous entries if it is the root entry of a complex
230 * rule
231 * - -ENOTEMPTY if the entry is part of a complex rule but not the root
232 * entry
233 * - -EINVAL if the validation fails
234 */
ksz9477_acl_get_cont_entr(struct ksz_device * dev,int port,int index)235 static int ksz9477_acl_get_cont_entr(struct ksz_device *dev, int port,
236 int index)
237 {
238 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
239 struct ksz9477_acl_entries *acles = &acl->acles;
240 int start_idx, end_idx, contiguous_count;
241 unsigned long val;
242 u8 vale, valf;
243 u8 *entry;
244 int i;
245
246 entry = &acles->entries[index].entry[0];
247 vale = entry[KSZ9477_ACL_PORT_ACCESS_E];
248 valf = entry[KSZ9477_ACL_PORT_ACCESS_F];
249
250 val = (vale << 8) | valf;
251
252 /* If no bits are set, return an appropriate value or error */
253 if (!val) {
254 if (ksz9477_acl_is_valid_matching_rule(entry)) {
255 /* Looks like we are about to corrupt some complex rule.
256 * Do not print an error here, as this is a normal case
257 * when we are trying to find a free or starting entry.
258 */
259 dev_dbg(dev->dev, "ACL: entry %d starting with a valid matching rule, but no bits set in RuleSet\n",
260 index);
261 return -ENOTEMPTY;
262 }
263
264 /* This entry does not contain a valid matching rule */
265 return 0;
266 }
267
268 start_idx = find_first_bit((unsigned long *)&val, 16);
269 end_idx = find_last_bit((unsigned long *)&val, 16);
270
271 /* Calculate the contiguous count */
272 contiguous_count = end_idx - start_idx + 1;
273
274 /* Check if the number of bits set in val matches our calculated count */
275 if (contiguous_count != hweight16(val)) {
276 /* Probably we have a fragmented complex rule, which is not
277 * supported by this driver.
278 */
279 dev_err(dev->dev, "ACL: number of bits set in RuleSet does not match calculated count\n");
280 return -EINVAL;
281 }
282
283 /* loop over the contiguous entries and check for valid matching rules */
284 for (i = start_idx; i <= end_idx; i++) {
285 u8 *current_entry = &acles->entries[i].entry[0];
286
287 if (!ksz9477_acl_is_valid_matching_rule(current_entry)) {
288 /* we have something linked without a valid matching
289 * rule. ACL table?
290 */
291 dev_err(dev->dev, "ACL: entry %d does not contain a valid matching rule\n",
292 i);
293 return -EINVAL;
294 }
295
296 if (i > start_idx) {
297 vale = current_entry[KSZ9477_ACL_PORT_ACCESS_E];
298 valf = current_entry[KSZ9477_ACL_PORT_ACCESS_F];
299 /* Following entry should have empty linkage list */
300 if (vale || valf) {
301 dev_err(dev->dev, "ACL: entry %d has non-empty RuleSet linkage\n",
302 i);
303 return -EINVAL;
304 }
305 }
306 }
307
308 return contiguous_count;
309 }
310
311 /**
312 * ksz9477_acl_update_linkage - Update the RuleSet linkage for an ACL entry
313 * after a move operation.
314 *
315 * @dev: Pointer to the ksz_device.
316 * @entry: Pointer to the ACL entry array.
317 * @old_idx: The original index of the ACL entry before moving.
318 * @new_idx: The new index of the ACL entry after moving.
319 *
320 * This function updates the RuleSet linkage bits for an ACL entry when
321 * it's moved from one position to another in the ACL table. The RuleSet
322 * linkage is represented by two 8-bit registers, which are combined
323 * into a 16-bit value for easier manipulation. The linkage bits are shifted
324 * based on the difference between the old and new index. If any bits are lost
325 * during the shift operation, an error is returned.
326 *
327 * Note: Fragmentation within a RuleSet is not supported. Hence, entries must
328 * be moved as complete blocks, maintaining the integrity of the RuleSet.
329 *
330 * Returns: 0 on success, or -EINVAL if any RuleSet linkage bits are lost
331 * during the move.
332 */
ksz9477_acl_update_linkage(struct ksz_device * dev,u8 * entry,u16 old_idx,u16 new_idx)333 static int ksz9477_acl_update_linkage(struct ksz_device *dev, u8 *entry,
334 u16 old_idx, u16 new_idx)
335 {
336 unsigned int original_bit_count;
337 unsigned long rule_linkage;
338 u8 vale, valf, val0;
339 int shift;
340
341 val0 = entry[KSZ9477_ACL_PORT_ACCESS_0];
342 vale = entry[KSZ9477_ACL_PORT_ACCESS_E];
343 valf = entry[KSZ9477_ACL_PORT_ACCESS_F];
344
345 /* Combine the two u8 values into one u16 for easier manipulation */
346 rule_linkage = (vale << 8) | valf;
347 original_bit_count = hweight16(rule_linkage);
348
349 /* Even if HW is able to handle fragmented RuleSet, we don't support it.
350 * RuleSet is filled only for the first entry of the set.
351 */
352 if (!rule_linkage)
353 return 0;
354
355 if (val0 != old_idx) {
356 dev_err(dev->dev, "ACL: entry %d has unexpected ActionRule linkage: %d\n",
357 old_idx, val0);
358 return -EINVAL;
359 }
360
361 val0 = new_idx;
362
363 /* Calculate the number of positions to shift */
364 shift = new_idx - old_idx;
365
366 /* Shift the RuleSet */
367 if (shift > 0)
368 rule_linkage <<= shift;
369 else
370 rule_linkage >>= -shift;
371
372 /* Check that no bits were lost in the process */
373 if (original_bit_count != hweight16(rule_linkage)) {
374 dev_err(dev->dev, "ACL RuleSet linkage bits lost during move\n");
375 return -EINVAL;
376 }
377
378 entry[KSZ9477_ACL_PORT_ACCESS_0] = val0;
379
380 /* Update the RuleSet bitfields in the entry */
381 entry[KSZ9477_ACL_PORT_ACCESS_E] = (rule_linkage >> 8) & 0xFF;
382 entry[KSZ9477_ACL_PORT_ACCESS_F] = rule_linkage & 0xFF;
383
384 return 0;
385 }
386
387 /**
388 * ksz9477_validate_and_get_src_count - Validate source and destination indices
389 * and determine the source entry count.
390 * @dev: Pointer to the KSZ device structure.
391 * @port: Port number on the KSZ device where the ACL entries reside.
392 * @src_idx: Index of the starting ACL entry that needs to be validated.
393 * @dst_idx: Index of the destination where the source entries are intended to
394 * be moved.
395 * @src_count: Pointer to the variable that will hold the number of contiguous
396 * source entries if the validation passes.
397 * @dst_count: Pointer to the variable that will hold the number of contiguous
398 * destination entries if the validation passes.
399 *
400 * This function performs validation on the source and destination indices
401 * provided for ACL entries. It checks if the indices are within the valid
402 * range, and if the source entries are contiguous. Additionally, the function
403 * ensures that there's adequate space at the destination for the source entries
404 * and that the destination index isn't in the middle of a RuleSet. If all
405 * validations pass, the function returns the number of contiguous source and
406 * destination entries.
407 *
408 * Return: 0 on success, otherwise returns a negative error code if any
409 * validation check fails.
410 */
ksz9477_validate_and_get_src_count(struct ksz_device * dev,int port,int src_idx,int dst_idx,int * src_count,int * dst_count)411 static int ksz9477_validate_and_get_src_count(struct ksz_device *dev, int port,
412 int src_idx, int dst_idx,
413 int *src_count, int *dst_count)
414 {
415 int ret;
416
417 if (src_idx >= KSZ9477_ACL_MAX_ENTRIES ||
418 dst_idx >= KSZ9477_ACL_MAX_ENTRIES) {
419 dev_err(dev->dev, "ACL: invalid entry index\n");
420 return -EINVAL;
421 }
422
423 /* Validate if the source entries are contiguous */
424 ret = ksz9477_acl_get_cont_entr(dev, port, src_idx);
425 if (ret < 0)
426 return ret;
427 *src_count = ret;
428
429 if (!*src_count) {
430 dev_err(dev->dev, "ACL: source entry is empty\n");
431 return -EINVAL;
432 }
433
434 if (dst_idx + *src_count >= KSZ9477_ACL_MAX_ENTRIES) {
435 dev_err(dev->dev, "ACL: Not enough space at the destination. Move operation will fail.\n");
436 return -EINVAL;
437 }
438
439 /* Validate if the destination entry is empty or not in the middle of
440 * a RuleSet.
441 */
442 ret = ksz9477_acl_get_cont_entr(dev, port, dst_idx);
443 if (ret < 0)
444 return ret;
445 *dst_count = ret;
446
447 return 0;
448 }
449
450 /**
451 * ksz9477_move_entries_downwards - Move a range of ACL entries downwards in
452 * the list.
453 * @dev: Pointer to the KSZ device structure.
454 * @acles: Pointer to the structure encapsulating all the ACL entries.
455 * @start_idx: Starting index of the entries to be relocated.
456 * @num_entries_to_move: Number of consecutive entries to be relocated.
457 * @end_idx: Destination index where the first entry should be situated post
458 * relocation.
459 *
460 * This function is responsible for rearranging a specific block of ACL entries
461 * by shifting them downwards in the list based on the supplied source and
462 * destination indices. It ensures that the linkage between the ACL entries is
463 * maintained accurately after the relocation.
464 *
465 * Return: 0 on successful relocation of entries, otherwise returns a negative
466 * error code.
467 */
ksz9477_move_entries_downwards(struct ksz_device * dev,struct ksz9477_acl_entries * acles,u16 start_idx,u16 num_entries_to_move,u16 end_idx)468 static int ksz9477_move_entries_downwards(struct ksz_device *dev,
469 struct ksz9477_acl_entries *acles,
470 u16 start_idx,
471 u16 num_entries_to_move,
472 u16 end_idx)
473 {
474 struct ksz9477_acl_entry *e;
475 int ret, i;
476
477 for (i = start_idx; i < end_idx; i++) {
478 e = &acles->entries[i];
479 *e = acles->entries[i + num_entries_to_move];
480
481 ret = ksz9477_acl_update_linkage(dev, &e->entry[0],
482 i + num_entries_to_move, i);
483 if (ret < 0)
484 return ret;
485 }
486
487 return 0;
488 }
489
490 /**
491 * ksz9477_move_entries_upwards - Move a range of ACL entries upwards in the
492 * list.
493 * @dev: Pointer to the KSZ device structure.
494 * @acles: Pointer to the structure holding all the ACL entries.
495 * @start_idx: The starting index of the entries to be moved.
496 * @num_entries_to_move: Number of contiguous entries to be moved.
497 * @target_idx: The destination index where the first entry should be placed
498 * after moving.
499 *
500 * This function rearranges a chunk of ACL entries by moving them upwards
501 * in the list based on the given source and destination indices. The reordering
502 * process preserves the linkage between entries by updating it accordingly.
503 *
504 * Return: 0 if the entries were successfully moved, otherwise a negative error
505 * code.
506 */
ksz9477_move_entries_upwards(struct ksz_device * dev,struct ksz9477_acl_entries * acles,u16 start_idx,u16 num_entries_to_move,u16 target_idx)507 static int ksz9477_move_entries_upwards(struct ksz_device *dev,
508 struct ksz9477_acl_entries *acles,
509 u16 start_idx, u16 num_entries_to_move,
510 u16 target_idx)
511 {
512 struct ksz9477_acl_entry *e;
513 int ret, i, b;
514
515 for (i = start_idx; i > target_idx; i--) {
516 b = i + num_entries_to_move - 1;
517
518 e = &acles->entries[b];
519 *e = acles->entries[i - 1];
520
521 ret = ksz9477_acl_update_linkage(dev, &e->entry[0], i - 1, b);
522 if (ret < 0)
523 return ret;
524 }
525
526 return 0;
527 }
528
529 /**
530 * ksz9477_acl_move_entries - Move a block of contiguous ACL entries from a
531 * source to a destination index.
532 * @dev: Pointer to the KSZ9477 device structure.
533 * @port: Port number.
534 * @src_idx: Index of the starting source ACL entry.
535 * @dst_idx: Index of the starting destination ACL entry.
536 *
537 * This function aims to move a block of contiguous ACL entries from the source
538 * index to the destination index while ensuring the integrity and validity of
539 * the ACL table.
540 *
541 * In case of any errors during the adjustments or copying, the function will
542 * restore the ACL entries to their original state from the backup.
543 *
544 * Return: 0 if the move operation is successful. Returns -EINVAL for validation
545 * errors or other error codes based on specific failure conditions.
546 */
ksz9477_acl_move_entries(struct ksz_device * dev,int port,u16 src_idx,u16 dst_idx)547 static int ksz9477_acl_move_entries(struct ksz_device *dev, int port,
548 u16 src_idx, u16 dst_idx)
549 {
550 struct ksz9477_acl_entry buffer[KSZ9477_ACL_MAX_ENTRIES];
551 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
552 struct ksz9477_acl_entries *acles = &acl->acles;
553 int src_count, ret, dst_count;
554
555 /* Nothing to do */
556 if (src_idx == dst_idx)
557 return 0;
558
559 ret = ksz9477_validate_and_get_src_count(dev, port, src_idx, dst_idx,
560 &src_count, &dst_count);
561 if (ret)
562 return ret;
563
564 /* In case dst_index is greater than src_index, we need to adjust the
565 * destination index to account for the entries that will be moved
566 * downwards and the size of the entry located at dst_idx.
567 */
568 if (dst_idx > src_idx)
569 dst_idx = dst_idx + dst_count - src_count;
570
571 /* Copy source block to buffer and update its linkage */
572 for (int i = 0; i < src_count; i++) {
573 buffer[i] = acles->entries[src_idx + i];
574 ret = ksz9477_acl_update_linkage(dev, &buffer[i].entry[0],
575 src_idx + i, dst_idx + i);
576 if (ret < 0)
577 return ret;
578 }
579
580 /* Adjust other entries and their linkage based on destination */
581 if (dst_idx > src_idx) {
582 ret = ksz9477_move_entries_downwards(dev, acles, src_idx,
583 src_count, dst_idx);
584 } else {
585 ret = ksz9477_move_entries_upwards(dev, acles, src_idx,
586 src_count, dst_idx);
587 }
588 if (ret < 0)
589 return ret;
590
591 /* Copy buffer to destination block */
592 for (int i = 0; i < src_count; i++)
593 acles->entries[dst_idx + i] = buffer[i];
594
595 return 0;
596 }
597
598 /**
599 * ksz9477_get_next_block_start - Identify the starting index of the next ACL
600 * block.
601 * @dev: Pointer to the device structure.
602 * @port: The port number on which the ACL entries are being checked.
603 * @start: The starting index from which the search begins.
604 *
605 * This function looks for the next valid ACL block starting from the provided
606 * 'start' index and returns the beginning index of that block. If the block is
607 * invalid or if it reaches the end of the ACL entries without finding another
608 * block, it returns the maximum ACL entries count.
609 *
610 * Returns:
611 * - The starting index of the next valid ACL block.
612 * - KSZ9477_ACL_MAX_ENTRIES if no other valid blocks are found after 'start'.
613 * - A negative error code if an error occurs while checking.
614 */
ksz9477_get_next_block_start(struct ksz_device * dev,int port,int start)615 static int ksz9477_get_next_block_start(struct ksz_device *dev, int port,
616 int start)
617 {
618 int block_size;
619
620 for (int i = start; i < KSZ9477_ACL_MAX_ENTRIES;) {
621 block_size = ksz9477_acl_get_cont_entr(dev, port, i);
622 if (block_size < 0 && block_size != -ENOTEMPTY)
623 return block_size;
624
625 if (block_size > 0)
626 return i;
627
628 i++;
629 }
630 return KSZ9477_ACL_MAX_ENTRIES;
631 }
632
633 /**
634 * ksz9477_swap_acl_blocks - Swap two ACL blocks
635 * @dev: Pointer to the device structure.
636 * @port: The port number on which the ACL blocks are to be swapped.
637 * @i: The starting index of the first ACL block.
638 * @j: The starting index of the second ACL block.
639 *
640 * This function is used to swap two ACL blocks present at given indices. The
641 * main purpose is to aid in the sorting and reordering of ACL blocks based on
642 * certain criteria, e.g., priority. It checks the validity of the block at
643 * index 'i', ensuring it's not an empty block, and then proceeds to swap it
644 * with the block at index 'j'.
645 *
646 * Returns:
647 * - 0 on successful swapping of blocks.
648 * - -EINVAL if the block at index 'i' is empty.
649 * - A negative error code if any other error occurs during the swap.
650 */
ksz9477_swap_acl_blocks(struct ksz_device * dev,int port,int i,int j)651 static int ksz9477_swap_acl_blocks(struct ksz_device *dev, int port, int i,
652 int j)
653 {
654 int ret, current_block_size;
655
656 current_block_size = ksz9477_acl_get_cont_entr(dev, port, i);
657 if (current_block_size < 0)
658 return current_block_size;
659
660 if (!current_block_size) {
661 dev_err(dev->dev, "ACL: swapping empty entry %d\n", i);
662 return -EINVAL;
663 }
664
665 ret = ksz9477_acl_move_entries(dev, port, i, j);
666 if (ret)
667 return ret;
668
669 ret = ksz9477_acl_move_entries(dev, port, j - current_block_size, i);
670 if (ret)
671 return ret;
672
673 return 0;
674 }
675
676 /**
677 * ksz9477_sort_acl_entr_no_back - Sort ACL entries for a given port based on
678 * priority without backing up entries.
679 * @dev: Pointer to the device structure.
680 * @port: The port number whose ACL entries need to be sorted.
681 *
682 * This function sorts ACL entries of the specified port using a variant of the
683 * bubble sort algorithm. It operates on blocks of ACL entries rather than
684 * individual entries. Each block's starting point is identified and then
685 * compared with subsequent blocks based on their priority. If the current
686 * block has a lower priority than the subsequent block, the two blocks are
687 * swapped.
688 *
689 * This is done in order to maintain an organized order of ACL entries based on
690 * priority, ensuring efficient and predictable ACL rule application.
691 *
692 * Returns:
693 * - 0 on successful sorting of entries.
694 * - A negative error code if any issue arises during sorting, e.g.,
695 * if the function is unable to get the next block start.
696 */
ksz9477_sort_acl_entr_no_back(struct ksz_device * dev,int port)697 static int ksz9477_sort_acl_entr_no_back(struct ksz_device *dev, int port)
698 {
699 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
700 struct ksz9477_acl_entries *acles = &acl->acles;
701 struct ksz9477_acl_entry *curr, *next;
702 int i, j, ret;
703
704 /* Bubble sort */
705 for (i = 0; i < KSZ9477_ACL_MAX_ENTRIES;) {
706 curr = &acles->entries[i];
707
708 j = ksz9477_get_next_block_start(dev, port, i + 1);
709 if (j < 0)
710 return j;
711
712 while (j < KSZ9477_ACL_MAX_ENTRIES) {
713 next = &acles->entries[j];
714
715 if (curr->prio > next->prio) {
716 ret = ksz9477_swap_acl_blocks(dev, port, i, j);
717 if (ret)
718 return ret;
719 }
720
721 j = ksz9477_get_next_block_start(dev, port, j + 1);
722 if (j < 0)
723 return j;
724 }
725
726 i = ksz9477_get_next_block_start(dev, port, i + 1);
727 if (i < 0)
728 return i;
729 }
730
731 return 0;
732 }
733
734 /**
735 * ksz9477_sort_acl_entries - Sort the ACL entries for a given port.
736 * @dev: Pointer to the KSZ device.
737 * @port: Port number.
738 *
739 * This function sorts the Access Control List (ACL) entries for a specified
740 * port. Before sorting, a backup of the original entries is created. If the
741 * sorting process fails, the function will log error messages displaying both
742 * the original and attempted sorted entries, and then restore the original
743 * entries from the backup.
744 *
745 * Return: 0 if the sorting succeeds, otherwise a negative error code.
746 */
ksz9477_sort_acl_entries(struct ksz_device * dev,int port)747 int ksz9477_sort_acl_entries(struct ksz_device *dev, int port)
748 {
749 struct ksz9477_acl_entry backup[KSZ9477_ACL_MAX_ENTRIES];
750 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
751 struct ksz9477_acl_entries *acles = &acl->acles;
752 int ret;
753
754 /* create a backup of the ACL entries, if something goes wrong
755 * we can restore the ACL entries.
756 */
757 memcpy(backup, acles->entries, sizeof(backup));
758
759 ret = ksz9477_sort_acl_entr_no_back(dev, port);
760 if (ret) {
761 dev_err(dev->dev, "ACL: failed to sort entries for port %d\n",
762 port);
763 dev_err(dev->dev, "ACL dump before sorting:\n");
764 ksz9477_dump_acl(dev, backup);
765 dev_err(dev->dev, "ACL dump after sorting:\n");
766 ksz9477_dump_acl(dev, acles->entries);
767 /* Restore the original entries */
768 memcpy(acles->entries, backup, sizeof(backup));
769 }
770
771 return ret;
772 }
773
774 /**
775 * ksz9477_acl_wait_ready - Waits for the ACL operation to complete on a given
776 * port.
777 * @dev: The ksz_device instance.
778 * @port: The port number to wait for.
779 *
780 * This function checks if the ACL write or read operation is completed by
781 * polling the specified register.
782 *
783 * Returns: 0 if the operation is successful, or a negative error code if an
784 * error occurs.
785 */
ksz9477_acl_wait_ready(struct ksz_device * dev,int port)786 static int ksz9477_acl_wait_ready(struct ksz_device *dev, int port)
787 {
788 unsigned int wr_mask = KSZ9477_ACL_WRITE_DONE | KSZ9477_ACL_READ_DONE;
789 unsigned int val, reg;
790 int ret;
791
792 reg = dev->dev_ops->get_port_addr(port, KSZ9477_PORT_ACL_CTRL_0);
793
794 ret = regmap_read_poll_timeout(dev->regmap[0], reg, val,
795 (val & wr_mask) == wr_mask, 1000, 10000);
796 if (ret)
797 dev_err(dev->dev, "Failed to read/write ACL table\n");
798
799 return ret;
800 }
801
802 /**
803 * ksz9477_acl_entry_write - Writes an ACL entry to a given port at the
804 * specified index.
805 * @dev: The ksz_device instance.
806 * @port: The port number to write the ACL entry to.
807 * @entry: A pointer to the ACL entry data.
808 * @idx: The index at which to write the ACL entry.
809 *
810 * This function writes the provided ACL entry to the specified port at the
811 * given index.
812 *
813 * Returns: 0 if the operation is successful, or a negative error code if an
814 * error occurs.
815 */
ksz9477_acl_entry_write(struct ksz_device * dev,int port,u8 * entry,int idx)816 static int ksz9477_acl_entry_write(struct ksz_device *dev, int port, u8 *entry,
817 int idx)
818 {
819 int ret, i;
820 u8 val;
821
822 for (i = 0; i < KSZ9477_ACL_ENTRY_SIZE; i++) {
823 ret = ksz_pwrite8(dev, port, KSZ9477_PORT_ACL_0 + i, entry[i]);
824 if (ret) {
825 dev_err(dev->dev, "Failed to write ACL entry %d\n", i);
826 return ret;
827 }
828 }
829
830 /* write everything down */
831 val = FIELD_PREP(KSZ9477_ACL_INDEX_M, idx) | KSZ9477_ACL_WRITE;
832 ret = ksz_pwrite8(dev, port, KSZ9477_PORT_ACL_CTRL_0, val);
833 if (ret)
834 return ret;
835
836 /* wait until everything is written */
837 return ksz9477_acl_wait_ready(dev, port);
838 }
839
840 /**
841 * ksz9477_acl_port_enable - Enables ACL functionality on a given port.
842 * @dev: The ksz_device instance.
843 * @port: The port number on which to enable ACL functionality.
844 *
845 * This function enables ACL functionality on the specified port by configuring
846 * the appropriate control registers. It returns 0 if the operation is
847 * successful, or a negative error code if an error occurs.
848 *
849 * 0xn801 - KSZ9477S 5.2.8.2 Port Priority Control Register
850 * Bit 7 - Highest Priority
851 * Bit 6 - OR'ed Priority
852 * Bit 4 - MAC Address Priority Classification
853 * Bit 3 - VLAN Priority Classification
854 * Bit 2 - 802.1p Priority Classification
855 * Bit 1 - Diffserv Priority Classification
856 * Bit 0 - ACL Priority Classification
857 *
858 * Current driver implementation sets 802.1p priority classification by default.
859 * In this function we add ACL priority classification with OR'ed priority.
860 * According to testing, priority set by ACL will supersede the 802.1p priority.
861 *
862 * 0xn803 - KSZ9477S 5.2.8.4 Port Authentication Control Register
863 * Bit 2 - Access Control List (ACL) Enable
864 * Bits 1:0 - Authentication Mode
865 * 00 = Reserved
866 * 01 = Block Mode. Authentication is enabled. When ACL is
867 * enabled, all traffic that misses the ACL rules is
868 * blocked; otherwise ACL actions apply.
869 * 10 = Pass Mode. Authentication is disabled. When ACL is
870 * enabled, all traffic that misses the ACL rules is
871 * forwarded; otherwise ACL actions apply.
872 * 11 = Trap Mode. Authentication is enabled. All traffic is
873 * forwarded to the host port. When ACL is enabled, all
874 * traffic that misses the ACL rules is blocked; otherwise
875 * ACL actions apply.
876 *
877 * We are using Pass Mode int this function.
878 *
879 * Returns: 0 if the operation is successful, or a negative error code if an
880 * error occurs.
881 */
ksz9477_acl_port_enable(struct ksz_device * dev,int port)882 static int ksz9477_acl_port_enable(struct ksz_device *dev, int port)
883 {
884 int ret;
885
886 ret = ksz_prmw8(dev, port, P_PRIO_CTRL, 0, PORT_ACL_PRIO_ENABLE |
887 PORT_OR_PRIO);
888 if (ret)
889 return ret;
890
891 return ksz_pwrite8(dev, port, REG_PORT_MRI_AUTHEN_CTRL,
892 PORT_ACL_ENABLE |
893 FIELD_PREP(PORT_AUTHEN_MODE, PORT_AUTHEN_PASS));
894 }
895
896 /**
897 * ksz9477_acl_port_disable - Disables ACL functionality on a given port.
898 * @dev: The ksz_device instance.
899 * @port: The port number on which to disable ACL functionality.
900 *
901 * This function disables ACL functionality on the specified port by writing a
902 * value of 0 to the REG_PORT_MRI_AUTHEN_CTRL control register and remove
903 * PORT_ACL_PRIO_ENABLE bit from P_PRIO_CTRL register.
904 *
905 * Returns: 0 if the operation is successful, or a negative error code if an
906 * error occurs.
907 */
ksz9477_acl_port_disable(struct ksz_device * dev,int port)908 static int ksz9477_acl_port_disable(struct ksz_device *dev, int port)
909 {
910 int ret;
911
912 ret = ksz_prmw8(dev, port, P_PRIO_CTRL, PORT_ACL_PRIO_ENABLE, 0);
913 if (ret)
914 return ret;
915
916 return ksz_pwrite8(dev, port, REG_PORT_MRI_AUTHEN_CTRL, 0);
917 }
918
919 /**
920 * ksz9477_acl_write_list - Write a list of ACL entries to a given port.
921 * @dev: The ksz_device instance.
922 * @port: The port number on which to write ACL entries.
923 *
924 * This function enables ACL functionality on the specified port, writes a list
925 * of ACL entries to the port, and disables ACL functionality if there are no
926 * entries.
927 *
928 * Returns: 0 if the operation is successful, or a negative error code if an
929 * error occurs.
930 */
ksz9477_acl_write_list(struct ksz_device * dev,int port)931 int ksz9477_acl_write_list(struct ksz_device *dev, int port)
932 {
933 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
934 struct ksz9477_acl_entries *acles = &acl->acles;
935 int ret, i;
936
937 /* ACL should be enabled before writing entries */
938 ret = ksz9477_acl_port_enable(dev, port);
939 if (ret)
940 return ret;
941
942 /* write all entries */
943 for (i = 0; i < ARRAY_SIZE(acles->entries); i++) {
944 u8 *entry = acles->entries[i].entry;
945
946 /* Check if entry was removed and should be zeroed.
947 * If last fields of the entry are not zero, it means
948 * it is removed locally but currently not synced with the HW.
949 * So, we will write it down to the HW to remove it.
950 */
951 if (i >= acles->entries_count &&
952 entry[KSZ9477_ACL_PORT_ACCESS_10] == 0 &&
953 entry[KSZ9477_ACL_PORT_ACCESS_11] == 0)
954 continue;
955
956 ret = ksz9477_acl_entry_write(dev, port, entry, i);
957 if (ret)
958 return ret;
959
960 /* now removed entry is clean on HW side, so it can
961 * in the cache too
962 */
963 if (i >= acles->entries_count &&
964 entry[KSZ9477_ACL_PORT_ACCESS_10] != 0 &&
965 entry[KSZ9477_ACL_PORT_ACCESS_11] != 0) {
966 entry[KSZ9477_ACL_PORT_ACCESS_10] = 0;
967 entry[KSZ9477_ACL_PORT_ACCESS_11] = 0;
968 }
969 }
970
971 if (!acles->entries_count)
972 return ksz9477_acl_port_disable(dev, port);
973
974 return 0;
975 }
976
977 /**
978 * ksz9477_acl_remove_entries - Remove ACL entries with a given cookie from a
979 * specified ksz9477_acl_entries structure.
980 * @dev: The ksz_device instance.
981 * @port: The port number on which to remove ACL entries.
982 * @acles: The ksz9477_acl_entries instance.
983 * @cookie: The cookie value to match for entry removal.
984 *
985 * This function iterates through the entries array, removing any entries with
986 * a matching cookie value. The remaining entries are then shifted down to fill
987 * the gap.
988 */
ksz9477_acl_remove_entries(struct ksz_device * dev,int port,struct ksz9477_acl_entries * acles,unsigned long cookie)989 void ksz9477_acl_remove_entries(struct ksz_device *dev, int port,
990 struct ksz9477_acl_entries *acles,
991 unsigned long cookie)
992 {
993 int entries_count = acles->entries_count;
994 int ret, i, src_count;
995 int src_idx = -1;
996
997 if (!entries_count)
998 return;
999
1000 /* Search for the first position with the cookie */
1001 for (i = 0; i < entries_count; i++) {
1002 if (acles->entries[i].cookie == cookie) {
1003 src_idx = i;
1004 break;
1005 }
1006 }
1007
1008 /* No entries with the matching cookie found */
1009 if (src_idx == -1)
1010 return;
1011
1012 /* Get the size of the cookie entry. We may have complex entries. */
1013 src_count = ksz9477_acl_get_cont_entr(dev, port, src_idx);
1014 if (src_count <= 0)
1015 return;
1016
1017 /* Move all entries down to overwrite removed entry with the cookie */
1018 ret = ksz9477_move_entries_downwards(dev, acles, src_idx,
1019 src_count,
1020 entries_count - src_count);
1021 if (ret) {
1022 dev_err(dev->dev, "Failed to move ACL entries down\n");
1023 return;
1024 }
1025
1026 /* Overwrite new empty places at the end of the list with zeros to make
1027 * sure not unexpected things will happen or no unexplored quirks will
1028 * come out.
1029 */
1030 for (i = entries_count - src_count; i < entries_count; i++) {
1031 struct ksz9477_acl_entry *entry = &acles->entries[i];
1032
1033 memset(entry, 0, sizeof(*entry));
1034
1035 /* Set all access bits to be able to write zeroed entry to HW */
1036 entry->entry[KSZ9477_ACL_PORT_ACCESS_10] = 0xff;
1037 entry->entry[KSZ9477_ACL_PORT_ACCESS_11] = 0xff;
1038 }
1039
1040 /* Adjust the total entries count */
1041 acles->entries_count -= src_count;
1042 }
1043
1044 /**
1045 * ksz9477_port_acl_init - Initialize the ACL for a specified port on a ksz
1046 * device.
1047 * @dev: The ksz_device instance.
1048 * @port: The port number to initialize the ACL for.
1049 *
1050 * This function allocates memory for an acl structure, associates it with the
1051 * specified port, and initializes the ACL entries to a default state. The
1052 * entries are then written using the ksz9477_acl_write_list function, ensuring
1053 * the ACL has a predictable initial hardware state.
1054 *
1055 * Returns: 0 on success, or an error code on failure.
1056 */
ksz9477_port_acl_init(struct ksz_device * dev,int port)1057 int ksz9477_port_acl_init(struct ksz_device *dev, int port)
1058 {
1059 struct ksz9477_acl_entries *acles;
1060 struct ksz9477_acl_priv *acl;
1061 int ret, i;
1062
1063 acl = kzalloc(sizeof(*acl), GFP_KERNEL);
1064 if (!acl)
1065 return -ENOMEM;
1066
1067 dev->ports[port].acl_priv = acl;
1068
1069 acles = &acl->acles;
1070 /* write all entries */
1071 for (i = 0; i < ARRAY_SIZE(acles->entries); i++) {
1072 u8 *entry = acles->entries[i].entry;
1073
1074 /* Set all access bits to be able to write zeroed
1075 * entry
1076 */
1077 entry[KSZ9477_ACL_PORT_ACCESS_10] = 0xff;
1078 entry[KSZ9477_ACL_PORT_ACCESS_11] = 0xff;
1079 }
1080
1081 ret = ksz9477_acl_write_list(dev, port);
1082 if (ret)
1083 goto free_acl;
1084
1085 return 0;
1086
1087 free_acl:
1088 kfree(dev->ports[port].acl_priv);
1089 dev->ports[port].acl_priv = NULL;
1090
1091 return ret;
1092 }
1093
1094 /**
1095 * ksz9477_port_acl_free - Free the ACL resources for a specified port on a ksz
1096 * device.
1097 * @dev: The ksz_device instance.
1098 * @port: The port number to initialize the ACL for.
1099 *
1100 * This disables the ACL for the specified port and frees the associated memory,
1101 */
ksz9477_port_acl_free(struct ksz_device * dev,int port)1102 void ksz9477_port_acl_free(struct ksz_device *dev, int port)
1103 {
1104 if (!dev->ports[port].acl_priv)
1105 return;
1106
1107 ksz9477_acl_port_disable(dev, port);
1108
1109 kfree(dev->ports[port].acl_priv);
1110 dev->ports[port].acl_priv = NULL;
1111 }
1112
1113 /**
1114 * ksz9477_acl_set_reg - Set entry[16] and entry[17] depending on the updated
1115 * entry[]
1116 * @entry: An array containing the entries
1117 * @reg: The register of the entry that needs to be updated
1118 * @value: The value to be assigned to the updated entry
1119 *
1120 * This function updates the entry[] array based on the provided register and
1121 * value. It also sets entry[0x10] and entry[0x11] according to the ACL byte
1122 * enable rules.
1123 *
1124 * 0x10 - Byte Enable [15:8]
1125 *
1126 * Each bit enables accessing one of the ACL bytes when a read or write is
1127 * initiated by writing to the Port ACL Byte Enable LSB Register.
1128 * Bit 0 applies to the Port ACL Access 7 Register
1129 * Bit 1 applies to the Port ACL Access 6 Register, etc.
1130 * Bit 7 applies to the Port ACL Access 0 Register
1131 * 1 = Byte is selected for read/write
1132 * 0 = Byte is not selected
1133 *
1134 * 0x11 - Byte Enable [7:0]
1135 *
1136 * Each bit enables accessing one of the ACL bytes when a read or write is
1137 * initiated by writing to the Port ACL Byte Enable LSB Register.
1138 * Bit 0 applies to the Port ACL Access F Register
1139 * Bit 1 applies to the Port ACL Access E Register, etc.
1140 * Bit 7 applies to the Port ACL Access 8 Register
1141 * 1 = Byte is selected for read/write
1142 * 0 = Byte is not selected
1143 */
ksz9477_acl_set_reg(u8 * entry,enum ksz9477_acl_port_access reg,u8 value)1144 static void ksz9477_acl_set_reg(u8 *entry, enum ksz9477_acl_port_access reg,
1145 u8 value)
1146 {
1147 if (reg >= KSZ9477_ACL_PORT_ACCESS_0 &&
1148 reg <= KSZ9477_ACL_PORT_ACCESS_7) {
1149 entry[KSZ9477_ACL_PORT_ACCESS_10] |=
1150 BIT(KSZ9477_ACL_PORT_ACCESS_7 - reg);
1151 } else if (reg >= KSZ9477_ACL_PORT_ACCESS_8 &&
1152 reg <= KSZ9477_ACL_PORT_ACCESS_F) {
1153 entry[KSZ9477_ACL_PORT_ACCESS_11] |=
1154 BIT(KSZ9477_ACL_PORT_ACCESS_F - reg);
1155 } else {
1156 WARN_ON(1);
1157 return;
1158 }
1159
1160 entry[reg] = value;
1161 }
1162
1163 /**
1164 * ksz9477_acl_matching_rule_cfg_l2 - Configure an ACL filtering entry to match
1165 * L2 types of Ethernet frames
1166 * @entry: Pointer to ACL entry buffer
1167 * @ethertype: Ethertype value
1168 * @eth_addr: Pointer to Ethernet address
1169 * @is_src: If true, match the source MAC address; if false, match the
1170 * destination MAC address
1171 *
1172 * This function configures an Access Control List (ACL) filtering
1173 * entry to match Layer 2 types of Ethernet frames based on the provided
1174 * ethertype and Ethernet address. Additionally, it can match either the source
1175 * or destination MAC address depending on the value of the is_src parameter.
1176 *
1177 * Register Descriptions for MD = 01 and ENB != 00 (Layer 2 MAC header
1178 * filtering)
1179 *
1180 * 0x01 - Mode and Enable
1181 * Bits 5:4 - MD (Mode)
1182 * 01 = Layer 2 MAC header or counter filtering
1183 * Bits 3:2 - ENB (Enable)
1184 * 01 = Comparison is performed only on the TYPE value
1185 * 10 = Comparison is performed only on the MAC Address value
1186 * 11 = Both the MAC Address and TYPE are tested
1187 * Bit 1 - S/D (Source / Destination)
1188 * 0 = Destination address
1189 * 1 = Source address
1190 * Bit 0 - EQ (Equal / Not Equal)
1191 * 0 = Not Equal produces true result
1192 * 1 = Equal produces true result
1193 *
1194 * 0x02-0x07 - MAC Address
1195 * 0x02 - MAC Address [47:40]
1196 * 0x03 - MAC Address [39:32]
1197 * 0x04 - MAC Address [31:24]
1198 * 0x05 - MAC Address [23:16]
1199 * 0x06 - MAC Address [15:8]
1200 * 0x07 - MAC Address [7:0]
1201 *
1202 * 0x08-0x09 - EtherType
1203 * 0x08 - EtherType [15:8]
1204 * 0x09 - EtherType [7:0]
1205 */
ksz9477_acl_matching_rule_cfg_l2(u8 * entry,u16 ethertype,u8 * eth_addr,bool is_src)1206 static void ksz9477_acl_matching_rule_cfg_l2(u8 *entry, u16 ethertype,
1207 u8 *eth_addr, bool is_src)
1208 {
1209 u8 enb = 0;
1210 u8 val;
1211
1212 if (ethertype)
1213 enb |= KSZ9477_ACL_ENB_L2_TYPE;
1214 if (eth_addr)
1215 enb |= KSZ9477_ACL_ENB_L2_MAC;
1216
1217 val = FIELD_PREP(KSZ9477_ACL_MD_MASK, KSZ9477_ACL_MD_L2_MAC) |
1218 FIELD_PREP(KSZ9477_ACL_ENB_MASK, enb) |
1219 FIELD_PREP(KSZ9477_ACL_SD_SRC, is_src) | KSZ9477_ACL_EQ_EQUAL;
1220 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_1, val);
1221
1222 if (eth_addr) {
1223 int i;
1224
1225 for (i = 0; i < ETH_ALEN; i++) {
1226 ksz9477_acl_set_reg(entry,
1227 KSZ9477_ACL_PORT_ACCESS_2 + i,
1228 eth_addr[i]);
1229 }
1230 }
1231
1232 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_8, ethertype >> 8);
1233 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_9, ethertype & 0xff);
1234 }
1235
1236 /**
1237 * ksz9477_acl_action_rule_cfg - Set action for an ACL entry
1238 * @entry: Pointer to the ACL entry
1239 * @force_prio: If true, force the priority value
1240 * @prio_val: Priority value
1241 *
1242 * This function sets the action for the specified ACL entry. It prepares
1243 * the priority mode and traffic class values and updates the entry's
1244 * action registers accordingly. Currently, there is no port or VLAN PCP
1245 * remapping.
1246 *
1247 * ACL Action Rule Parameters for Non-Count Modes (MD ≠ 01 or ENB ≠ 00)
1248 *
1249 * 0x0A - PM, P, RPE, RP[2:1]
1250 * Bits 7:6 - PM[1:0] - Priority Mode
1251 * 00 = ACL does not specify the packet priority. Priority is
1252 * determined by standard QoS functions.
1253 * 01 = Change packet priority to P[2:0] if it is greater than QoS
1254 * result.
1255 * 10 = Change packet priority to P[2:0] if it is smaller than the
1256 * QoS result.
1257 * 11 = Always change packet priority to P[2:0].
1258 * Bits 5:3 - P[2:0] - Priority value
1259 * Bit 2 - RPE - Remark Priority Enable
1260 * Bits 1:0 - RP[2:1] - Remarked Priority value (bits 2:1)
1261 * 0 = Disable priority remarking
1262 * 1 = Enable priority remarking. VLAN tag priority (PCP) bits are
1263 * replaced by RP[2:0].
1264 *
1265 * 0x0B - RP[0], MM
1266 * Bit 7 - RP[0] - Remarked Priority value (bit 0)
1267 * Bits 6:5 - MM[1:0] - Map Mode
1268 * 00 = No forwarding remapping
1269 * 01 = The forwarding map in FORWARD is OR'ed with the forwarding
1270 * map from the Address Lookup Table.
1271 * 10 = The forwarding map in FORWARD is AND'ed with the forwarding
1272 * map from the Address Lookup Table.
1273 * 11 = The forwarding map in FORWARD replaces the forwarding map
1274 * from the Address Lookup Table.
1275 * 0x0D - FORWARD[n:0]
1276 * Bits 7:0 - FORWARD[n:0] - Forwarding map. Bit 0 = port 1,
1277 * bit 1 = port 2, etc.
1278 * 1 = enable forwarding to this port
1279 * 0 = do not forward to this port
1280 */
ksz9477_acl_action_rule_cfg(u8 * entry,bool force_prio,u8 prio_val)1281 void ksz9477_acl_action_rule_cfg(u8 *entry, bool force_prio, u8 prio_val)
1282 {
1283 u8 prio_mode, val;
1284
1285 if (force_prio)
1286 prio_mode = KSZ9477_ACL_PM_REPLACE;
1287 else
1288 prio_mode = KSZ9477_ACL_PM_DISABLE;
1289
1290 val = FIELD_PREP(KSZ9477_ACL_PM_M, prio_mode) |
1291 FIELD_PREP(KSZ9477_ACL_P_M, prio_val);
1292 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_A, val);
1293
1294 /* no port or VLAN PCP remapping for now */
1295 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_B, 0);
1296 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_D, 0);
1297 }
1298
1299 /**
1300 * ksz9477_acl_processing_rule_set_action - Set the action for the processing
1301 * rule set.
1302 * @entry: Pointer to the ACL entry
1303 * @action_idx: Index of the action to be applied
1304 *
1305 * This function sets the action for the processing rule set by updating the
1306 * appropriate register in the entry. There can be only one action per
1307 * processing rule.
1308 *
1309 * Access Control List (ACL) Processing Rule Registers:
1310 *
1311 * 0x00 - First Rule Number (FRN)
1312 * Bits 3:0 - First Rule Number. Pointer to an Action rule entry.
1313 */
ksz9477_acl_processing_rule_set_action(u8 * entry,u8 action_idx)1314 void ksz9477_acl_processing_rule_set_action(u8 *entry, u8 action_idx)
1315 {
1316 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_0, action_idx);
1317 }
1318
1319 /**
1320 * ksz9477_acl_processing_rule_add_match - Add a matching rule to the rule set
1321 * @entry: Pointer to the ACL entry
1322 * @match_idx: Index of the matching rule to be added
1323 *
1324 * This function adds a matching rule to the rule set by updating the
1325 * appropriate bits in the entry's rule set registers.
1326 *
1327 * Access Control List (ACL) Processing Rule Registers:
1328 *
1329 * 0x0E - RuleSet [15:8]
1330 * Bits 7:0 - RuleSet [15:8] Specifies a set of one or more Matching rule
1331 * entries. RuleSet has one bit for each of the 16 Matching rule entries.
1332 * If multiple Matching rules are selected, then all conditions will be
1333 * AND'ed to produce a final match result.
1334 * 0 = Matching rule not selected
1335 * 1 = Matching rule selected
1336 *
1337 * 0x0F - RuleSet [7:0]
1338 * Bits 7:0 - RuleSet [7:0]
1339 */
ksz9477_acl_processing_rule_add_match(u8 * entry,u8 match_idx)1340 static void ksz9477_acl_processing_rule_add_match(u8 *entry, u8 match_idx)
1341 {
1342 u8 vale = entry[KSZ9477_ACL_PORT_ACCESS_E];
1343 u8 valf = entry[KSZ9477_ACL_PORT_ACCESS_F];
1344
1345 if (match_idx < 8)
1346 valf |= BIT(match_idx);
1347 else
1348 vale |= BIT(match_idx - 8);
1349
1350 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_E, vale);
1351 ksz9477_acl_set_reg(entry, KSZ9477_ACL_PORT_ACCESS_F, valf);
1352 }
1353
1354 /**
1355 * ksz9477_acl_get_init_entry - Get a new uninitialized entry for a specified
1356 * port on a ksz_device.
1357 * @dev: The ksz_device instance.
1358 * @port: The port number to get the uninitialized entry for.
1359 * @cookie: The cookie to associate with the entry.
1360 * @prio: The priority to associate with the entry.
1361 *
1362 * This function retrieves the next available ACL entry for the specified port,
1363 * clears all access flags, and associates it with the current cookie.
1364 *
1365 * Returns: A pointer to the new uninitialized ACL entry.
1366 */
1367 static struct ksz9477_acl_entry *
ksz9477_acl_get_init_entry(struct ksz_device * dev,int port,unsigned long cookie,u32 prio)1368 ksz9477_acl_get_init_entry(struct ksz_device *dev, int port,
1369 unsigned long cookie, u32 prio)
1370 {
1371 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
1372 struct ksz9477_acl_entries *acles = &acl->acles;
1373 struct ksz9477_acl_entry *entry;
1374
1375 entry = &acles->entries[acles->entries_count];
1376 entry->cookie = cookie;
1377 entry->prio = prio;
1378
1379 /* clear all access flags */
1380 entry->entry[KSZ9477_ACL_PORT_ACCESS_10] = 0;
1381 entry->entry[KSZ9477_ACL_PORT_ACCESS_11] = 0;
1382
1383 return entry;
1384 }
1385
1386 /**
1387 * ksz9477_acl_match_process_l2 - Configure Layer 2 ACL matching rules and
1388 * processing rules.
1389 * @dev: Pointer to the ksz_device.
1390 * @port: Port number.
1391 * @ethtype: Ethernet type.
1392 * @src_mac: Source MAC address.
1393 * @dst_mac: Destination MAC address.
1394 * @cookie: The cookie to associate with the entry.
1395 * @prio: The priority of the entry.
1396 *
1397 * This function sets up matching and processing rules for Layer 2 ACLs.
1398 * It takes into account that only one MAC per entry is supported.
1399 */
ksz9477_acl_match_process_l2(struct ksz_device * dev,int port,u16 ethtype,u8 * src_mac,u8 * dst_mac,unsigned long cookie,u32 prio)1400 void ksz9477_acl_match_process_l2(struct ksz_device *dev, int port,
1401 u16 ethtype, u8 *src_mac, u8 *dst_mac,
1402 unsigned long cookie, u32 prio)
1403 {
1404 struct ksz9477_acl_priv *acl = dev->ports[port].acl_priv;
1405 struct ksz9477_acl_entries *acles = &acl->acles;
1406 struct ksz9477_acl_entry *entry;
1407
1408 entry = ksz9477_acl_get_init_entry(dev, port, cookie, prio);
1409
1410 /* ACL supports only one MAC per entry */
1411 if (src_mac && dst_mac) {
1412 ksz9477_acl_matching_rule_cfg_l2(entry->entry, ethtype, src_mac,
1413 true);
1414
1415 /* Add both match entries to first processing rule */
1416 ksz9477_acl_processing_rule_add_match(entry->entry,
1417 acles->entries_count);
1418 acles->entries_count++;
1419 ksz9477_acl_processing_rule_add_match(entry->entry,
1420 acles->entries_count);
1421
1422 entry = ksz9477_acl_get_init_entry(dev, port, cookie, prio);
1423 ksz9477_acl_matching_rule_cfg_l2(entry->entry, 0, dst_mac,
1424 false);
1425 acles->entries_count++;
1426 } else {
1427 u8 *mac = src_mac ? src_mac : dst_mac;
1428 bool is_src = src_mac ? true : false;
1429
1430 ksz9477_acl_matching_rule_cfg_l2(entry->entry, ethtype, mac,
1431 is_src);
1432 ksz9477_acl_processing_rule_add_match(entry->entry,
1433 acles->entries_count);
1434 acles->entries_count++;
1435 }
1436 }
1437