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1// SPDX-License-Identifier: GPL-2.0
2/* Copyright (c) 2018-2023, Intel Corporation. */
3
4#include "ice_common.h"
5#include "ice_sched.h"
6#include "ice_adminq_cmd.h"
7#include "ice_flow.h"
8#include "ice_ptp_hw.h"
9
10#define ICE_PF_RESET_WAIT_COUNT 300
11#define ICE_MAX_NETLIST_SIZE 10
12
13static const char * const ice_link_mode_str_low[] = {
14 [0] = "100BASE_TX",
15 [1] = "100M_SGMII",
16 [2] = "1000BASE_T",
17 [3] = "1000BASE_SX",
18 [4] = "1000BASE_LX",
19 [5] = "1000BASE_KX",
20 [6] = "1G_SGMII",
21 [7] = "2500BASE_T",
22 [8] = "2500BASE_X",
23 [9] = "2500BASE_KX",
24 [10] = "5GBASE_T",
25 [11] = "5GBASE_KR",
26 [12] = "10GBASE_T",
27 [13] = "10G_SFI_DA",
28 [14] = "10GBASE_SR",
29 [15] = "10GBASE_LR",
30 [16] = "10GBASE_KR_CR1",
31 [17] = "10G_SFI_AOC_ACC",
32 [18] = "10G_SFI_C2C",
33 [19] = "25GBASE_T",
34 [20] = "25GBASE_CR",
35 [21] = "25GBASE_CR_S",
36 [22] = "25GBASE_CR1",
37 [23] = "25GBASE_SR",
38 [24] = "25GBASE_LR",
39 [25] = "25GBASE_KR",
40 [26] = "25GBASE_KR_S",
41 [27] = "25GBASE_KR1",
42 [28] = "25G_AUI_AOC_ACC",
43 [29] = "25G_AUI_C2C",
44 [30] = "40GBASE_CR4",
45 [31] = "40GBASE_SR4",
46 [32] = "40GBASE_LR4",
47 [33] = "40GBASE_KR4",
48 [34] = "40G_XLAUI_AOC_ACC",
49 [35] = "40G_XLAUI",
50 [36] = "50GBASE_CR2",
51 [37] = "50GBASE_SR2",
52 [38] = "50GBASE_LR2",
53 [39] = "50GBASE_KR2",
54 [40] = "50G_LAUI2_AOC_ACC",
55 [41] = "50G_LAUI2",
56 [42] = "50G_AUI2_AOC_ACC",
57 [43] = "50G_AUI2",
58 [44] = "50GBASE_CP",
59 [45] = "50GBASE_SR",
60 [46] = "50GBASE_FR",
61 [47] = "50GBASE_LR",
62 [48] = "50GBASE_KR_PAM4",
63 [49] = "50G_AUI1_AOC_ACC",
64 [50] = "50G_AUI1",
65 [51] = "100GBASE_CR4",
66 [52] = "100GBASE_SR4",
67 [53] = "100GBASE_LR4",
68 [54] = "100GBASE_KR4",
69 [55] = "100G_CAUI4_AOC_ACC",
70 [56] = "100G_CAUI4",
71 [57] = "100G_AUI4_AOC_ACC",
72 [58] = "100G_AUI4",
73 [59] = "100GBASE_CR_PAM4",
74 [60] = "100GBASE_KR_PAM4",
75 [61] = "100GBASE_CP2",
76 [62] = "100GBASE_SR2",
77 [63] = "100GBASE_DR",
78};
79
80static const char * const ice_link_mode_str_high[] = {
81 [0] = "100GBASE_KR2_PAM4",
82 [1] = "100G_CAUI2_AOC_ACC",
83 [2] = "100G_CAUI2",
84 [3] = "100G_AUI2_AOC_ACC",
85 [4] = "100G_AUI2",
86};
87
88/**
89 * ice_dump_phy_type - helper function to dump phy_type
90 * @hw: pointer to the HW structure
91 * @low: 64 bit value for phy_type_low
92 * @high: 64 bit value for phy_type_high
93 * @prefix: prefix string to differentiate multiple dumps
94 */
95static void
96ice_dump_phy_type(struct ice_hw *hw, u64 low, u64 high, const char *prefix)
97{
98 ice_debug(hw, ICE_DBG_PHY, "%s: phy_type_low: 0x%016llx\n", prefix, low);
99
100 for (u32 i = 0; i < BITS_PER_TYPE(typeof(low)); i++) {
101 if (low & BIT_ULL(i))
102 ice_debug(hw, ICE_DBG_PHY, "%s: bit(%d): %s\n",
103 prefix, i, ice_link_mode_str_low[i]);
104 }
105
106 ice_debug(hw, ICE_DBG_PHY, "%s: phy_type_high: 0x%016llx\n", prefix, high);
107
108 for (u32 i = 0; i < BITS_PER_TYPE(typeof(high)); i++) {
109 if (high & BIT_ULL(i))
110 ice_debug(hw, ICE_DBG_PHY, "%s: bit(%d): %s\n",
111 prefix, i, ice_link_mode_str_high[i]);
112 }
113}
114
115/**
116 * ice_set_mac_type - Sets MAC type
117 * @hw: pointer to the HW structure
118 *
119 * This function sets the MAC type of the adapter based on the
120 * vendor ID and device ID stored in the HW structure.
121 */
122static int ice_set_mac_type(struct ice_hw *hw)
123{
124 if (hw->vendor_id != PCI_VENDOR_ID_INTEL)
125 return -ENODEV;
126
127 switch (hw->device_id) {
128 case ICE_DEV_ID_E810C_BACKPLANE:
129 case ICE_DEV_ID_E810C_QSFP:
130 case ICE_DEV_ID_E810C_SFP:
131 case ICE_DEV_ID_E810_XXV_BACKPLANE:
132 case ICE_DEV_ID_E810_XXV_QSFP:
133 case ICE_DEV_ID_E810_XXV_SFP:
134 hw->mac_type = ICE_MAC_E810;
135 break;
136 case ICE_DEV_ID_E823C_10G_BASE_T:
137 case ICE_DEV_ID_E823C_BACKPLANE:
138 case ICE_DEV_ID_E823C_QSFP:
139 case ICE_DEV_ID_E823C_SFP:
140 case ICE_DEV_ID_E823C_SGMII:
141 case ICE_DEV_ID_E822C_10G_BASE_T:
142 case ICE_DEV_ID_E822C_BACKPLANE:
143 case ICE_DEV_ID_E822C_QSFP:
144 case ICE_DEV_ID_E822C_SFP:
145 case ICE_DEV_ID_E822C_SGMII:
146 case ICE_DEV_ID_E822L_10G_BASE_T:
147 case ICE_DEV_ID_E822L_BACKPLANE:
148 case ICE_DEV_ID_E822L_SFP:
149 case ICE_DEV_ID_E822L_SGMII:
150 case ICE_DEV_ID_E823L_10G_BASE_T:
151 case ICE_DEV_ID_E823L_1GBE:
152 case ICE_DEV_ID_E823L_BACKPLANE:
153 case ICE_DEV_ID_E823L_QSFP:
154 case ICE_DEV_ID_E823L_SFP:
155 hw->mac_type = ICE_MAC_GENERIC;
156 break;
157 case ICE_DEV_ID_E830_BACKPLANE:
158 case ICE_DEV_ID_E830_QSFP56:
159 case ICE_DEV_ID_E830_SFP:
160 case ICE_DEV_ID_E830_SFP_DD:
161 hw->mac_type = ICE_MAC_E830;
162 break;
163 default:
164 hw->mac_type = ICE_MAC_UNKNOWN;
165 break;
166 }
167
168 ice_debug(hw, ICE_DBG_INIT, "mac_type: %d\n", hw->mac_type);
169 return 0;
170}
171
172/**
173 * ice_is_e810
174 * @hw: pointer to the hardware structure
175 *
176 * returns true if the device is E810 based, false if not.
177 */
178bool ice_is_e810(struct ice_hw *hw)
179{
180 return hw->mac_type == ICE_MAC_E810;
181}
182
183/**
184 * ice_is_e810t
185 * @hw: pointer to the hardware structure
186 *
187 * returns true if the device is E810T based, false if not.
188 */
189bool ice_is_e810t(struct ice_hw *hw)
190{
191 switch (hw->device_id) {
192 case ICE_DEV_ID_E810C_SFP:
193 switch (hw->subsystem_device_id) {
194 case ICE_SUBDEV_ID_E810T:
195 case ICE_SUBDEV_ID_E810T2:
196 case ICE_SUBDEV_ID_E810T3:
197 case ICE_SUBDEV_ID_E810T4:
198 case ICE_SUBDEV_ID_E810T6:
199 case ICE_SUBDEV_ID_E810T7:
200 return true;
201 }
202 break;
203 case ICE_DEV_ID_E810C_QSFP:
204 switch (hw->subsystem_device_id) {
205 case ICE_SUBDEV_ID_E810T2:
206 case ICE_SUBDEV_ID_E810T3:
207 case ICE_SUBDEV_ID_E810T5:
208 return true;
209 }
210 break;
211 default:
212 break;
213 }
214
215 return false;
216}
217
218/**
219 * ice_is_e823
220 * @hw: pointer to the hardware structure
221 *
222 * returns true if the device is E823-L or E823-C based, false if not.
223 */
224bool ice_is_e823(struct ice_hw *hw)
225{
226 switch (hw->device_id) {
227 case ICE_DEV_ID_E823L_BACKPLANE:
228 case ICE_DEV_ID_E823L_SFP:
229 case ICE_DEV_ID_E823L_10G_BASE_T:
230 case ICE_DEV_ID_E823L_1GBE:
231 case ICE_DEV_ID_E823L_QSFP:
232 case ICE_DEV_ID_E823C_BACKPLANE:
233 case ICE_DEV_ID_E823C_QSFP:
234 case ICE_DEV_ID_E823C_SFP:
235 case ICE_DEV_ID_E823C_10G_BASE_T:
236 case ICE_DEV_ID_E823C_SGMII:
237 return true;
238 default:
239 return false;
240 }
241}
242
243/**
244 * ice_clear_pf_cfg - Clear PF configuration
245 * @hw: pointer to the hardware structure
246 *
247 * Clears any existing PF configuration (VSIs, VSI lists, switch rules, port
248 * configuration, flow director filters, etc.).
249 */
250int ice_clear_pf_cfg(struct ice_hw *hw)
251{
252 struct ice_aq_desc desc;
253
254 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_clear_pf_cfg);
255
256 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
257}
258
259/**
260 * ice_aq_manage_mac_read - manage MAC address read command
261 * @hw: pointer to the HW struct
262 * @buf: a virtual buffer to hold the manage MAC read response
263 * @buf_size: Size of the virtual buffer
264 * @cd: pointer to command details structure or NULL
265 *
266 * This function is used to return per PF station MAC address (0x0107).
267 * NOTE: Upon successful completion of this command, MAC address information
268 * is returned in user specified buffer. Please interpret user specified
269 * buffer as "manage_mac_read" response.
270 * Response such as various MAC addresses are stored in HW struct (port.mac)
271 * ice_discover_dev_caps is expected to be called before this function is
272 * called.
273 */
274static int
275ice_aq_manage_mac_read(struct ice_hw *hw, void *buf, u16 buf_size,
276 struct ice_sq_cd *cd)
277{
278 struct ice_aqc_manage_mac_read_resp *resp;
279 struct ice_aqc_manage_mac_read *cmd;
280 struct ice_aq_desc desc;
281 int status;
282 u16 flags;
283 u8 i;
284
285 cmd = &desc.params.mac_read;
286
287 if (buf_size < sizeof(*resp))
288 return -EINVAL;
289
290 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_manage_mac_read);
291
292 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
293 if (status)
294 return status;
295
296 resp = buf;
297 flags = le16_to_cpu(cmd->flags) & ICE_AQC_MAN_MAC_READ_M;
298
299 if (!(flags & ICE_AQC_MAN_MAC_LAN_ADDR_VALID)) {
300 ice_debug(hw, ICE_DBG_LAN, "got invalid MAC address\n");
301 return -EIO;
302 }
303
304 /* A single port can report up to two (LAN and WoL) addresses */
305 for (i = 0; i < cmd->num_addr; i++)
306 if (resp[i].addr_type == ICE_AQC_MAN_MAC_ADDR_TYPE_LAN) {
307 ether_addr_copy(hw->port_info->mac.lan_addr,
308 resp[i].mac_addr);
309 ether_addr_copy(hw->port_info->mac.perm_addr,
310 resp[i].mac_addr);
311 break;
312 }
313
314 return 0;
315}
316
317/**
318 * ice_aq_get_phy_caps - returns PHY capabilities
319 * @pi: port information structure
320 * @qual_mods: report qualified modules
321 * @report_mode: report mode capabilities
322 * @pcaps: structure for PHY capabilities to be filled
323 * @cd: pointer to command details structure or NULL
324 *
325 * Returns the various PHY capabilities supported on the Port (0x0600)
326 */
327int
328ice_aq_get_phy_caps(struct ice_port_info *pi, bool qual_mods, u8 report_mode,
329 struct ice_aqc_get_phy_caps_data *pcaps,
330 struct ice_sq_cd *cd)
331{
332 struct ice_aqc_get_phy_caps *cmd;
333 u16 pcaps_size = sizeof(*pcaps);
334 struct ice_aq_desc desc;
335 const char *prefix;
336 struct ice_hw *hw;
337 int status;
338
339 cmd = &desc.params.get_phy;
340
341 if (!pcaps || (report_mode & ~ICE_AQC_REPORT_MODE_M) || !pi)
342 return -EINVAL;
343 hw = pi->hw;
344
345 if (report_mode == ICE_AQC_REPORT_DFLT_CFG &&
346 !ice_fw_supports_report_dflt_cfg(hw))
347 return -EINVAL;
348
349 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_phy_caps);
350
351 if (qual_mods)
352 cmd->param0 |= cpu_to_le16(ICE_AQC_GET_PHY_RQM);
353
354 cmd->param0 |= cpu_to_le16(report_mode);
355 status = ice_aq_send_cmd(hw, &desc, pcaps, pcaps_size, cd);
356
357 ice_debug(hw, ICE_DBG_LINK, "get phy caps dump\n");
358
359 switch (report_mode) {
360 case ICE_AQC_REPORT_TOPO_CAP_MEDIA:
361 prefix = "phy_caps_media";
362 break;
363 case ICE_AQC_REPORT_TOPO_CAP_NO_MEDIA:
364 prefix = "phy_caps_no_media";
365 break;
366 case ICE_AQC_REPORT_ACTIVE_CFG:
367 prefix = "phy_caps_active";
368 break;
369 case ICE_AQC_REPORT_DFLT_CFG:
370 prefix = "phy_caps_default";
371 break;
372 default:
373 prefix = "phy_caps_invalid";
374 }
375
376 ice_dump_phy_type(hw, le64_to_cpu(pcaps->phy_type_low),
377 le64_to_cpu(pcaps->phy_type_high), prefix);
378
379 ice_debug(hw, ICE_DBG_LINK, "%s: report_mode = 0x%x\n",
380 prefix, report_mode);
381 ice_debug(hw, ICE_DBG_LINK, "%s: caps = 0x%x\n", prefix, pcaps->caps);
382 ice_debug(hw, ICE_DBG_LINK, "%s: low_power_ctrl_an = 0x%x\n", prefix,
383 pcaps->low_power_ctrl_an);
384 ice_debug(hw, ICE_DBG_LINK, "%s: eee_cap = 0x%x\n", prefix,
385 pcaps->eee_cap);
386 ice_debug(hw, ICE_DBG_LINK, "%s: eeer_value = 0x%x\n", prefix,
387 pcaps->eeer_value);
388 ice_debug(hw, ICE_DBG_LINK, "%s: link_fec_options = 0x%x\n", prefix,
389 pcaps->link_fec_options);
390 ice_debug(hw, ICE_DBG_LINK, "%s: module_compliance_enforcement = 0x%x\n",
391 prefix, pcaps->module_compliance_enforcement);
392 ice_debug(hw, ICE_DBG_LINK, "%s: extended_compliance_code = 0x%x\n",
393 prefix, pcaps->extended_compliance_code);
394 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[0] = 0x%x\n", prefix,
395 pcaps->module_type[0]);
396 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[1] = 0x%x\n", prefix,
397 pcaps->module_type[1]);
398 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[2] = 0x%x\n", prefix,
399 pcaps->module_type[2]);
400
401 if (!status && report_mode == ICE_AQC_REPORT_TOPO_CAP_MEDIA) {
402 pi->phy.phy_type_low = le64_to_cpu(pcaps->phy_type_low);
403 pi->phy.phy_type_high = le64_to_cpu(pcaps->phy_type_high);
404 memcpy(pi->phy.link_info.module_type, &pcaps->module_type,
405 sizeof(pi->phy.link_info.module_type));
406 }
407
408 return status;
409}
410
411/**
412 * ice_aq_get_link_topo_handle - get link topology node return status
413 * @pi: port information structure
414 * @node_type: requested node type
415 * @cd: pointer to command details structure or NULL
416 *
417 * Get link topology node return status for specified node type (0x06E0)
418 *
419 * Node type cage can be used to determine if cage is present. If AQC
420 * returns error (ENOENT), then no cage present. If no cage present, then
421 * connection type is backplane or BASE-T.
422 */
423static int
424ice_aq_get_link_topo_handle(struct ice_port_info *pi, u8 node_type,
425 struct ice_sq_cd *cd)
426{
427 struct ice_aqc_get_link_topo *cmd;
428 struct ice_aq_desc desc;
429
430 cmd = &desc.params.get_link_topo;
431
432 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_topo);
433
434 cmd->addr.topo_params.node_type_ctx =
435 (ICE_AQC_LINK_TOPO_NODE_CTX_PORT <<
436 ICE_AQC_LINK_TOPO_NODE_CTX_S);
437
438 /* set node type */
439 cmd->addr.topo_params.node_type_ctx |=
440 (ICE_AQC_LINK_TOPO_NODE_TYPE_M & node_type);
441
442 return ice_aq_send_cmd(pi->hw, &desc, NULL, 0, cd);
443}
444
445/**
446 * ice_aq_get_netlist_node
447 * @hw: pointer to the hw struct
448 * @cmd: get_link_topo AQ structure
449 * @node_part_number: output node part number if node found
450 * @node_handle: output node handle parameter if node found
451 *
452 * Get netlist node handle.
453 */
454int
455ice_aq_get_netlist_node(struct ice_hw *hw, struct ice_aqc_get_link_topo *cmd,
456 u8 *node_part_number, u16 *node_handle)
457{
458 struct ice_aq_desc desc;
459
460 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_topo);
461 desc.params.get_link_topo = *cmd;
462
463 if (ice_aq_send_cmd(hw, &desc, NULL, 0, NULL))
464 return -EINTR;
465
466 if (node_handle)
467 *node_handle =
468 le16_to_cpu(desc.params.get_link_topo.addr.handle);
469 if (node_part_number)
470 *node_part_number = desc.params.get_link_topo.node_part_num;
471
472 return 0;
473}
474
475/**
476 * ice_find_netlist_node
477 * @hw: pointer to the hw struct
478 * @node_type_ctx: type of netlist node to look for
479 * @node_part_number: node part number to look for
480 * @node_handle: output parameter if node found - optional
481 *
482 * Scan the netlist for a node handle of the given node type and part number.
483 *
484 * If node_handle is non-NULL it will be modified on function exit. It is only
485 * valid if the function returns zero, and should be ignored on any non-zero
486 * return value.
487 *
488 * Returns: 0 if the node is found, -ENOENT if no handle was found, and
489 * a negative error code on failure to access the AQ.
490 */
491static int ice_find_netlist_node(struct ice_hw *hw, u8 node_type_ctx,
492 u8 node_part_number, u16 *node_handle)
493{
494 u8 idx;
495
496 for (idx = 0; idx < ICE_MAX_NETLIST_SIZE; idx++) {
497 struct ice_aqc_get_link_topo cmd = {};
498 u8 rec_node_part_number;
499 int status;
500
501 cmd.addr.topo_params.node_type_ctx =
502 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_TYPE_M,
503 node_type_ctx);
504 cmd.addr.topo_params.index = idx;
505
506 status = ice_aq_get_netlist_node(hw, &cmd,
507 &rec_node_part_number,
508 node_handle);
509 if (status)
510 return status;
511
512 if (rec_node_part_number == node_part_number)
513 return 0;
514 }
515
516 return -ENOENT;
517}
518
519/**
520 * ice_is_media_cage_present
521 * @pi: port information structure
522 *
523 * Returns true if media cage is present, else false. If no cage, then
524 * media type is backplane or BASE-T.
525 */
526static bool ice_is_media_cage_present(struct ice_port_info *pi)
527{
528 /* Node type cage can be used to determine if cage is present. If AQC
529 * returns error (ENOENT), then no cage present. If no cage present then
530 * connection type is backplane or BASE-T.
531 */
532 return !ice_aq_get_link_topo_handle(pi,
533 ICE_AQC_LINK_TOPO_NODE_TYPE_CAGE,
534 NULL);
535}
536
537/**
538 * ice_get_media_type - Gets media type
539 * @pi: port information structure
540 */
541static enum ice_media_type ice_get_media_type(struct ice_port_info *pi)
542{
543 struct ice_link_status *hw_link_info;
544
545 if (!pi)
546 return ICE_MEDIA_UNKNOWN;
547
548 hw_link_info = &pi->phy.link_info;
549 if (hw_link_info->phy_type_low && hw_link_info->phy_type_high)
550 /* If more than one media type is selected, report unknown */
551 return ICE_MEDIA_UNKNOWN;
552
553 if (hw_link_info->phy_type_low) {
554 /* 1G SGMII is a special case where some DA cable PHYs
555 * may show this as an option when it really shouldn't
556 * be since SGMII is meant to be between a MAC and a PHY
557 * in a backplane. Try to detect this case and handle it
558 */
559 if (hw_link_info->phy_type_low == ICE_PHY_TYPE_LOW_1G_SGMII &&
560 (hw_link_info->module_type[ICE_AQC_MOD_TYPE_IDENT] ==
561 ICE_AQC_MOD_TYPE_BYTE1_SFP_PLUS_CU_ACTIVE ||
562 hw_link_info->module_type[ICE_AQC_MOD_TYPE_IDENT] ==
563 ICE_AQC_MOD_TYPE_BYTE1_SFP_PLUS_CU_PASSIVE))
564 return ICE_MEDIA_DA;
565
566 switch (hw_link_info->phy_type_low) {
567 case ICE_PHY_TYPE_LOW_1000BASE_SX:
568 case ICE_PHY_TYPE_LOW_1000BASE_LX:
569 case ICE_PHY_TYPE_LOW_10GBASE_SR:
570 case ICE_PHY_TYPE_LOW_10GBASE_LR:
571 case ICE_PHY_TYPE_LOW_10G_SFI_C2C:
572 case ICE_PHY_TYPE_LOW_25GBASE_SR:
573 case ICE_PHY_TYPE_LOW_25GBASE_LR:
574 case ICE_PHY_TYPE_LOW_40GBASE_SR4:
575 case ICE_PHY_TYPE_LOW_40GBASE_LR4:
576 case ICE_PHY_TYPE_LOW_50GBASE_SR2:
577 case ICE_PHY_TYPE_LOW_50GBASE_LR2:
578 case ICE_PHY_TYPE_LOW_50GBASE_SR:
579 case ICE_PHY_TYPE_LOW_50GBASE_FR:
580 case ICE_PHY_TYPE_LOW_50GBASE_LR:
581 case ICE_PHY_TYPE_LOW_100GBASE_SR4:
582 case ICE_PHY_TYPE_LOW_100GBASE_LR4:
583 case ICE_PHY_TYPE_LOW_100GBASE_SR2:
584 case ICE_PHY_TYPE_LOW_100GBASE_DR:
585 case ICE_PHY_TYPE_LOW_10G_SFI_AOC_ACC:
586 case ICE_PHY_TYPE_LOW_25G_AUI_AOC_ACC:
587 case ICE_PHY_TYPE_LOW_40G_XLAUI_AOC_ACC:
588 case ICE_PHY_TYPE_LOW_50G_LAUI2_AOC_ACC:
589 case ICE_PHY_TYPE_LOW_50G_AUI2_AOC_ACC:
590 case ICE_PHY_TYPE_LOW_50G_AUI1_AOC_ACC:
591 case ICE_PHY_TYPE_LOW_100G_CAUI4_AOC_ACC:
592 case ICE_PHY_TYPE_LOW_100G_AUI4_AOC_ACC:
593 return ICE_MEDIA_FIBER;
594 case ICE_PHY_TYPE_LOW_100BASE_TX:
595 case ICE_PHY_TYPE_LOW_1000BASE_T:
596 case ICE_PHY_TYPE_LOW_2500BASE_T:
597 case ICE_PHY_TYPE_LOW_5GBASE_T:
598 case ICE_PHY_TYPE_LOW_10GBASE_T:
599 case ICE_PHY_TYPE_LOW_25GBASE_T:
600 return ICE_MEDIA_BASET;
601 case ICE_PHY_TYPE_LOW_10G_SFI_DA:
602 case ICE_PHY_TYPE_LOW_25GBASE_CR:
603 case ICE_PHY_TYPE_LOW_25GBASE_CR_S:
604 case ICE_PHY_TYPE_LOW_25GBASE_CR1:
605 case ICE_PHY_TYPE_LOW_40GBASE_CR4:
606 case ICE_PHY_TYPE_LOW_50GBASE_CR2:
607 case ICE_PHY_TYPE_LOW_50GBASE_CP:
608 case ICE_PHY_TYPE_LOW_100GBASE_CR4:
609 case ICE_PHY_TYPE_LOW_100GBASE_CR_PAM4:
610 case ICE_PHY_TYPE_LOW_100GBASE_CP2:
611 return ICE_MEDIA_DA;
612 case ICE_PHY_TYPE_LOW_25G_AUI_C2C:
613 case ICE_PHY_TYPE_LOW_40G_XLAUI:
614 case ICE_PHY_TYPE_LOW_50G_LAUI2:
615 case ICE_PHY_TYPE_LOW_50G_AUI2:
616 case ICE_PHY_TYPE_LOW_50G_AUI1:
617 case ICE_PHY_TYPE_LOW_100G_AUI4:
618 case ICE_PHY_TYPE_LOW_100G_CAUI4:
619 if (ice_is_media_cage_present(pi))
620 return ICE_MEDIA_DA;
621 fallthrough;
622 case ICE_PHY_TYPE_LOW_1000BASE_KX:
623 case ICE_PHY_TYPE_LOW_2500BASE_KX:
624 case ICE_PHY_TYPE_LOW_2500BASE_X:
625 case ICE_PHY_TYPE_LOW_5GBASE_KR:
626 case ICE_PHY_TYPE_LOW_10GBASE_KR_CR1:
627 case ICE_PHY_TYPE_LOW_25GBASE_KR:
628 case ICE_PHY_TYPE_LOW_25GBASE_KR1:
629 case ICE_PHY_TYPE_LOW_25GBASE_KR_S:
630 case ICE_PHY_TYPE_LOW_40GBASE_KR4:
631 case ICE_PHY_TYPE_LOW_50GBASE_KR_PAM4:
632 case ICE_PHY_TYPE_LOW_50GBASE_KR2:
633 case ICE_PHY_TYPE_LOW_100GBASE_KR4:
634 case ICE_PHY_TYPE_LOW_100GBASE_KR_PAM4:
635 return ICE_MEDIA_BACKPLANE;
636 }
637 } else {
638 switch (hw_link_info->phy_type_high) {
639 case ICE_PHY_TYPE_HIGH_100G_AUI2:
640 case ICE_PHY_TYPE_HIGH_100G_CAUI2:
641 if (ice_is_media_cage_present(pi))
642 return ICE_MEDIA_DA;
643 fallthrough;
644 case ICE_PHY_TYPE_HIGH_100GBASE_KR2_PAM4:
645 return ICE_MEDIA_BACKPLANE;
646 case ICE_PHY_TYPE_HIGH_100G_CAUI2_AOC_ACC:
647 case ICE_PHY_TYPE_HIGH_100G_AUI2_AOC_ACC:
648 return ICE_MEDIA_FIBER;
649 }
650 }
651 return ICE_MEDIA_UNKNOWN;
652}
653
654/**
655 * ice_get_link_status_datalen
656 * @hw: pointer to the HW struct
657 *
658 * Returns datalength for the Get Link Status AQ command, which is bigger for
659 * newer adapter families handled by ice driver.
660 */
661static u16 ice_get_link_status_datalen(struct ice_hw *hw)
662{
663 switch (hw->mac_type) {
664 case ICE_MAC_E830:
665 return ICE_AQC_LS_DATA_SIZE_V2;
666 case ICE_MAC_E810:
667 default:
668 return ICE_AQC_LS_DATA_SIZE_V1;
669 }
670}
671
672/**
673 * ice_aq_get_link_info
674 * @pi: port information structure
675 * @ena_lse: enable/disable LinkStatusEvent reporting
676 * @link: pointer to link status structure - optional
677 * @cd: pointer to command details structure or NULL
678 *
679 * Get Link Status (0x607). Returns the link status of the adapter.
680 */
681int
682ice_aq_get_link_info(struct ice_port_info *pi, bool ena_lse,
683 struct ice_link_status *link, struct ice_sq_cd *cd)
684{
685 struct ice_aqc_get_link_status_data link_data = { 0 };
686 struct ice_aqc_get_link_status *resp;
687 struct ice_link_status *li_old, *li;
688 enum ice_media_type *hw_media_type;
689 struct ice_fc_info *hw_fc_info;
690 bool tx_pause, rx_pause;
691 struct ice_aq_desc desc;
692 struct ice_hw *hw;
693 u16 cmd_flags;
694 int status;
695
696 if (!pi)
697 return -EINVAL;
698 hw = pi->hw;
699 li_old = &pi->phy.link_info_old;
700 hw_media_type = &pi->phy.media_type;
701 li = &pi->phy.link_info;
702 hw_fc_info = &pi->fc;
703
704 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_status);
705 cmd_flags = (ena_lse) ? ICE_AQ_LSE_ENA : ICE_AQ_LSE_DIS;
706 resp = &desc.params.get_link_status;
707 resp->cmd_flags = cpu_to_le16(cmd_flags);
708 resp->lport_num = pi->lport;
709
710 status = ice_aq_send_cmd(hw, &desc, &link_data,
711 ice_get_link_status_datalen(hw), cd);
712 if (status)
713 return status;
714
715 /* save off old link status information */
716 *li_old = *li;
717
718 /* update current link status information */
719 li->link_speed = le16_to_cpu(link_data.link_speed);
720 li->phy_type_low = le64_to_cpu(link_data.phy_type_low);
721 li->phy_type_high = le64_to_cpu(link_data.phy_type_high);
722 *hw_media_type = ice_get_media_type(pi);
723 li->link_info = link_data.link_info;
724 li->link_cfg_err = link_data.link_cfg_err;
725 li->an_info = link_data.an_info;
726 li->ext_info = link_data.ext_info;
727 li->max_frame_size = le16_to_cpu(link_data.max_frame_size);
728 li->fec_info = link_data.cfg & ICE_AQ_FEC_MASK;
729 li->topo_media_conflict = link_data.topo_media_conflict;
730 li->pacing = link_data.cfg & (ICE_AQ_CFG_PACING_M |
731 ICE_AQ_CFG_PACING_TYPE_M);
732
733 /* update fc info */
734 tx_pause = !!(link_data.an_info & ICE_AQ_LINK_PAUSE_TX);
735 rx_pause = !!(link_data.an_info & ICE_AQ_LINK_PAUSE_RX);
736 if (tx_pause && rx_pause)
737 hw_fc_info->current_mode = ICE_FC_FULL;
738 else if (tx_pause)
739 hw_fc_info->current_mode = ICE_FC_TX_PAUSE;
740 else if (rx_pause)
741 hw_fc_info->current_mode = ICE_FC_RX_PAUSE;
742 else
743 hw_fc_info->current_mode = ICE_FC_NONE;
744
745 li->lse_ena = !!(resp->cmd_flags & cpu_to_le16(ICE_AQ_LSE_IS_ENABLED));
746
747 ice_debug(hw, ICE_DBG_LINK, "get link info\n");
748 ice_debug(hw, ICE_DBG_LINK, " link_speed = 0x%x\n", li->link_speed);
749 ice_debug(hw, ICE_DBG_LINK, " phy_type_low = 0x%llx\n",
750 (unsigned long long)li->phy_type_low);
751 ice_debug(hw, ICE_DBG_LINK, " phy_type_high = 0x%llx\n",
752 (unsigned long long)li->phy_type_high);
753 ice_debug(hw, ICE_DBG_LINK, " media_type = 0x%x\n", *hw_media_type);
754 ice_debug(hw, ICE_DBG_LINK, " link_info = 0x%x\n", li->link_info);
755 ice_debug(hw, ICE_DBG_LINK, " link_cfg_err = 0x%x\n", li->link_cfg_err);
756 ice_debug(hw, ICE_DBG_LINK, " an_info = 0x%x\n", li->an_info);
757 ice_debug(hw, ICE_DBG_LINK, " ext_info = 0x%x\n", li->ext_info);
758 ice_debug(hw, ICE_DBG_LINK, " fec_info = 0x%x\n", li->fec_info);
759 ice_debug(hw, ICE_DBG_LINK, " lse_ena = 0x%x\n", li->lse_ena);
760 ice_debug(hw, ICE_DBG_LINK, " max_frame = 0x%x\n",
761 li->max_frame_size);
762 ice_debug(hw, ICE_DBG_LINK, " pacing = 0x%x\n", li->pacing);
763
764 /* save link status information */
765 if (link)
766 *link = *li;
767
768 /* flag cleared so calling functions don't call AQ again */
769 pi->phy.get_link_info = false;
770
771 return 0;
772}
773
774/**
775 * ice_fill_tx_timer_and_fc_thresh
776 * @hw: pointer to the HW struct
777 * @cmd: pointer to MAC cfg structure
778 *
779 * Add Tx timer and FC refresh threshold info to Set MAC Config AQ command
780 * descriptor
781 */
782static void
783ice_fill_tx_timer_and_fc_thresh(struct ice_hw *hw,
784 struct ice_aqc_set_mac_cfg *cmd)
785{
786 u32 val, fc_thres_m;
787
788 /* We read back the transmit timer and FC threshold value of
789 * LFC. Thus, we will use index =
790 * PRTMAC_HSEC_CTL_TX_PAUSE_QUANTA_MAX_INDEX.
791 *
792 * Also, because we are operating on transmit timer and FC
793 * threshold of LFC, we don't turn on any bit in tx_tmr_priority
794 */
795#define E800_IDX_OF_LFC E800_PRTMAC_HSEC_CTL_TX_PS_QNT_MAX
796#define E800_REFRESH_TMR E800_PRTMAC_HSEC_CTL_TX_PS_RFSH_TMR
797
798 if (hw->mac_type == ICE_MAC_E830) {
799 /* Retrieve the transmit timer */
800 val = rd32(hw, E830_PRTMAC_CL01_PS_QNT);
801 cmd->tx_tmr_value =
802 le16_encode_bits(val, E830_PRTMAC_CL01_PS_QNT_CL0_M);
803
804 /* Retrieve the fc threshold */
805 val = rd32(hw, E830_PRTMAC_CL01_QNT_THR);
806 fc_thres_m = E830_PRTMAC_CL01_QNT_THR_CL0_M;
807 } else {
808 /* Retrieve the transmit timer */
809 val = rd32(hw,
810 E800_PRTMAC_HSEC_CTL_TX_PS_QNT(E800_IDX_OF_LFC));
811 cmd->tx_tmr_value =
812 le16_encode_bits(val,
813 E800_PRTMAC_HSEC_CTL_TX_PS_QNT_M);
814
815 /* Retrieve the fc threshold */
816 val = rd32(hw,
817 E800_REFRESH_TMR(E800_IDX_OF_LFC));
818 fc_thres_m = E800_PRTMAC_HSEC_CTL_TX_PS_RFSH_TMR_M;
819 }
820 cmd->fc_refresh_threshold = le16_encode_bits(val, fc_thres_m);
821}
822
823/**
824 * ice_aq_set_mac_cfg
825 * @hw: pointer to the HW struct
826 * @max_frame_size: Maximum Frame Size to be supported
827 * @cd: pointer to command details structure or NULL
828 *
829 * Set MAC configuration (0x0603)
830 */
831int
832ice_aq_set_mac_cfg(struct ice_hw *hw, u16 max_frame_size, struct ice_sq_cd *cd)
833{
834 struct ice_aqc_set_mac_cfg *cmd;
835 struct ice_aq_desc desc;
836
837 cmd = &desc.params.set_mac_cfg;
838
839 if (max_frame_size == 0)
840 return -EINVAL;
841
842 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_mac_cfg);
843
844 cmd->max_frame_size = cpu_to_le16(max_frame_size);
845
846 ice_fill_tx_timer_and_fc_thresh(hw, cmd);
847
848 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
849}
850
851/**
852 * ice_init_fltr_mgmt_struct - initializes filter management list and locks
853 * @hw: pointer to the HW struct
854 */
855static int ice_init_fltr_mgmt_struct(struct ice_hw *hw)
856{
857 struct ice_switch_info *sw;
858 int status;
859
860 hw->switch_info = devm_kzalloc(ice_hw_to_dev(hw),
861 sizeof(*hw->switch_info), GFP_KERNEL);
862 sw = hw->switch_info;
863
864 if (!sw)
865 return -ENOMEM;
866
867 INIT_LIST_HEAD(&sw->vsi_list_map_head);
868 sw->prof_res_bm_init = 0;
869
870 status = ice_init_def_sw_recp(hw);
871 if (status) {
872 devm_kfree(ice_hw_to_dev(hw), hw->switch_info);
873 return status;
874 }
875 return 0;
876}
877
878/**
879 * ice_cleanup_fltr_mgmt_struct - cleanup filter management list and locks
880 * @hw: pointer to the HW struct
881 */
882static void ice_cleanup_fltr_mgmt_struct(struct ice_hw *hw)
883{
884 struct ice_switch_info *sw = hw->switch_info;
885 struct ice_vsi_list_map_info *v_pos_map;
886 struct ice_vsi_list_map_info *v_tmp_map;
887 struct ice_sw_recipe *recps;
888 u8 i;
889
890 list_for_each_entry_safe(v_pos_map, v_tmp_map, &sw->vsi_list_map_head,
891 list_entry) {
892 list_del(&v_pos_map->list_entry);
893 devm_kfree(ice_hw_to_dev(hw), v_pos_map);
894 }
895 recps = sw->recp_list;
896 for (i = 0; i < ICE_MAX_NUM_RECIPES; i++) {
897 struct ice_recp_grp_entry *rg_entry, *tmprg_entry;
898
899 recps[i].root_rid = i;
900 list_for_each_entry_safe(rg_entry, tmprg_entry,
901 &recps[i].rg_list, l_entry) {
902 list_del(&rg_entry->l_entry);
903 devm_kfree(ice_hw_to_dev(hw), rg_entry);
904 }
905
906 if (recps[i].adv_rule) {
907 struct ice_adv_fltr_mgmt_list_entry *tmp_entry;
908 struct ice_adv_fltr_mgmt_list_entry *lst_itr;
909
910 mutex_destroy(&recps[i].filt_rule_lock);
911 list_for_each_entry_safe(lst_itr, tmp_entry,
912 &recps[i].filt_rules,
913 list_entry) {
914 list_del(&lst_itr->list_entry);
915 devm_kfree(ice_hw_to_dev(hw), lst_itr->lkups);
916 devm_kfree(ice_hw_to_dev(hw), lst_itr);
917 }
918 } else {
919 struct ice_fltr_mgmt_list_entry *lst_itr, *tmp_entry;
920
921 mutex_destroy(&recps[i].filt_rule_lock);
922 list_for_each_entry_safe(lst_itr, tmp_entry,
923 &recps[i].filt_rules,
924 list_entry) {
925 list_del(&lst_itr->list_entry);
926 devm_kfree(ice_hw_to_dev(hw), lst_itr);
927 }
928 }
929 devm_kfree(ice_hw_to_dev(hw), recps[i].root_buf);
930 }
931 ice_rm_all_sw_replay_rule_info(hw);
932 devm_kfree(ice_hw_to_dev(hw), sw->recp_list);
933 devm_kfree(ice_hw_to_dev(hw), sw);
934}
935
936/**
937 * ice_get_itr_intrl_gran
938 * @hw: pointer to the HW struct
939 *
940 * Determines the ITR/INTRL granularities based on the maximum aggregate
941 * bandwidth according to the device's configuration during power-on.
942 */
943static void ice_get_itr_intrl_gran(struct ice_hw *hw)
944{
945 u8 max_agg_bw = FIELD_GET(GL_PWR_MODE_CTL_CAR_MAX_BW_M,
946 rd32(hw, GL_PWR_MODE_CTL));
947
948 switch (max_agg_bw) {
949 case ICE_MAX_AGG_BW_200G:
950 case ICE_MAX_AGG_BW_100G:
951 case ICE_MAX_AGG_BW_50G:
952 hw->itr_gran = ICE_ITR_GRAN_ABOVE_25;
953 hw->intrl_gran = ICE_INTRL_GRAN_ABOVE_25;
954 break;
955 case ICE_MAX_AGG_BW_25G:
956 hw->itr_gran = ICE_ITR_GRAN_MAX_25;
957 hw->intrl_gran = ICE_INTRL_GRAN_MAX_25;
958 break;
959 }
960}
961
962/**
963 * ice_init_hw - main hardware initialization routine
964 * @hw: pointer to the hardware structure
965 */
966int ice_init_hw(struct ice_hw *hw)
967{
968 struct ice_aqc_get_phy_caps_data *pcaps;
969 u16 mac_buf_len;
970 void *mac_buf;
971 int status;
972
973 /* Set MAC type based on DeviceID */
974 status = ice_set_mac_type(hw);
975 if (status)
976 return status;
977
978 hw->pf_id = FIELD_GET(PF_FUNC_RID_FUNC_NUM_M, rd32(hw, PF_FUNC_RID));
979
980 status = ice_reset(hw, ICE_RESET_PFR);
981 if (status)
982 return status;
983
984 ice_get_itr_intrl_gran(hw);
985
986 status = ice_create_all_ctrlq(hw);
987 if (status)
988 goto err_unroll_cqinit;
989
990 status = ice_fwlog_init(hw);
991 if (status)
992 ice_debug(hw, ICE_DBG_FW_LOG, "Error initializing FW logging: %d\n",
993 status);
994
995 status = ice_clear_pf_cfg(hw);
996 if (status)
997 goto err_unroll_cqinit;
998
999 /* Set bit to enable Flow Director filters */
1000 wr32(hw, PFQF_FD_ENA, PFQF_FD_ENA_FD_ENA_M);
1001 INIT_LIST_HEAD(&hw->fdir_list_head);
1002
1003 ice_clear_pxe_mode(hw);
1004
1005 status = ice_init_nvm(hw);
1006 if (status)
1007 goto err_unroll_cqinit;
1008
1009 status = ice_get_caps(hw);
1010 if (status)
1011 goto err_unroll_cqinit;
1012
1013 if (!hw->port_info)
1014 hw->port_info = devm_kzalloc(ice_hw_to_dev(hw),
1015 sizeof(*hw->port_info),
1016 GFP_KERNEL);
1017 if (!hw->port_info) {
1018 status = -ENOMEM;
1019 goto err_unroll_cqinit;
1020 }
1021
1022 /* set the back pointer to HW */
1023 hw->port_info->hw = hw;
1024
1025 /* Initialize port_info struct with switch configuration data */
1026 status = ice_get_initial_sw_cfg(hw);
1027 if (status)
1028 goto err_unroll_alloc;
1029
1030 hw->evb_veb = true;
1031
1032 /* init xarray for identifying scheduling nodes uniquely */
1033 xa_init_flags(&hw->port_info->sched_node_ids, XA_FLAGS_ALLOC);
1034
1035 /* Query the allocated resources for Tx scheduler */
1036 status = ice_sched_query_res_alloc(hw);
1037 if (status) {
1038 ice_debug(hw, ICE_DBG_SCHED, "Failed to get scheduler allocated resources\n");
1039 goto err_unroll_alloc;
1040 }
1041 ice_sched_get_psm_clk_freq(hw);
1042
1043 /* Initialize port_info struct with scheduler data */
1044 status = ice_sched_init_port(hw->port_info);
1045 if (status)
1046 goto err_unroll_sched;
1047
1048 pcaps = devm_kzalloc(ice_hw_to_dev(hw), sizeof(*pcaps), GFP_KERNEL);
1049 if (!pcaps) {
1050 status = -ENOMEM;
1051 goto err_unroll_sched;
1052 }
1053
1054 /* Initialize port_info struct with PHY capabilities */
1055 status = ice_aq_get_phy_caps(hw->port_info, false,
1056 ICE_AQC_REPORT_TOPO_CAP_MEDIA, pcaps,
1057 NULL);
1058 devm_kfree(ice_hw_to_dev(hw), pcaps);
1059 if (status)
1060 dev_warn(ice_hw_to_dev(hw), "Get PHY capabilities failed status = %d, continuing anyway\n",
1061 status);
1062
1063 /* Initialize port_info struct with link information */
1064 status = ice_aq_get_link_info(hw->port_info, false, NULL, NULL);
1065 if (status)
1066 goto err_unroll_sched;
1067
1068 /* need a valid SW entry point to build a Tx tree */
1069 if (!hw->sw_entry_point_layer) {
1070 ice_debug(hw, ICE_DBG_SCHED, "invalid sw entry point\n");
1071 status = -EIO;
1072 goto err_unroll_sched;
1073 }
1074 INIT_LIST_HEAD(&hw->agg_list);
1075 /* Initialize max burst size */
1076 if (!hw->max_burst_size)
1077 ice_cfg_rl_burst_size(hw, ICE_SCHED_DFLT_BURST_SIZE);
1078
1079 status = ice_init_fltr_mgmt_struct(hw);
1080 if (status)
1081 goto err_unroll_sched;
1082
1083 /* Get MAC information */
1084 /* A single port can report up to two (LAN and WoL) addresses */
1085 mac_buf = devm_kcalloc(ice_hw_to_dev(hw), 2,
1086 sizeof(struct ice_aqc_manage_mac_read_resp),
1087 GFP_KERNEL);
1088 mac_buf_len = 2 * sizeof(struct ice_aqc_manage_mac_read_resp);
1089
1090 if (!mac_buf) {
1091 status = -ENOMEM;
1092 goto err_unroll_fltr_mgmt_struct;
1093 }
1094
1095 status = ice_aq_manage_mac_read(hw, mac_buf, mac_buf_len, NULL);
1096 devm_kfree(ice_hw_to_dev(hw), mac_buf);
1097
1098 if (status)
1099 goto err_unroll_fltr_mgmt_struct;
1100 /* enable jumbo frame support at MAC level */
1101 status = ice_aq_set_mac_cfg(hw, ICE_AQ_SET_MAC_FRAME_SIZE_MAX, NULL);
1102 if (status)
1103 goto err_unroll_fltr_mgmt_struct;
1104 /* Obtain counter base index which would be used by flow director */
1105 status = ice_alloc_fd_res_cntr(hw, &hw->fd_ctr_base);
1106 if (status)
1107 goto err_unroll_fltr_mgmt_struct;
1108 status = ice_init_hw_tbls(hw);
1109 if (status)
1110 goto err_unroll_fltr_mgmt_struct;
1111 mutex_init(&hw->tnl_lock);
1112 return 0;
1113
1114err_unroll_fltr_mgmt_struct:
1115 ice_cleanup_fltr_mgmt_struct(hw);
1116err_unroll_sched:
1117 ice_sched_cleanup_all(hw);
1118err_unroll_alloc:
1119 devm_kfree(ice_hw_to_dev(hw), hw->port_info);
1120err_unroll_cqinit:
1121 ice_destroy_all_ctrlq(hw);
1122 return status;
1123}
1124
1125/**
1126 * ice_deinit_hw - unroll initialization operations done by ice_init_hw
1127 * @hw: pointer to the hardware structure
1128 *
1129 * This should be called only during nominal operation, not as a result of
1130 * ice_init_hw() failing since ice_init_hw() will take care of unrolling
1131 * applicable initializations if it fails for any reason.
1132 */
1133void ice_deinit_hw(struct ice_hw *hw)
1134{
1135 ice_free_fd_res_cntr(hw, hw->fd_ctr_base);
1136 ice_cleanup_fltr_mgmt_struct(hw);
1137
1138 ice_sched_cleanup_all(hw);
1139 ice_sched_clear_agg(hw);
1140 ice_free_seg(hw);
1141 ice_free_hw_tbls(hw);
1142 mutex_destroy(&hw->tnl_lock);
1143
1144 ice_fwlog_deinit(hw);
1145 ice_destroy_all_ctrlq(hw);
1146
1147 /* Clear VSI contexts if not already cleared */
1148 ice_clear_all_vsi_ctx(hw);
1149}
1150
1151/**
1152 * ice_check_reset - Check to see if a global reset is complete
1153 * @hw: pointer to the hardware structure
1154 */
1155int ice_check_reset(struct ice_hw *hw)
1156{
1157 u32 cnt, reg = 0, grst_timeout, uld_mask;
1158
1159 /* Poll for Device Active state in case a recent CORER, GLOBR,
1160 * or EMPR has occurred. The grst delay value is in 100ms units.
1161 * Add 1sec for outstanding AQ commands that can take a long time.
1162 */
1163 grst_timeout = FIELD_GET(GLGEN_RSTCTL_GRSTDEL_M,
1164 rd32(hw, GLGEN_RSTCTL)) + 10;
1165
1166 for (cnt = 0; cnt < grst_timeout; cnt++) {
1167 mdelay(100);
1168 reg = rd32(hw, GLGEN_RSTAT);
1169 if (!(reg & GLGEN_RSTAT_DEVSTATE_M))
1170 break;
1171 }
1172
1173 if (cnt == grst_timeout) {
1174 ice_debug(hw, ICE_DBG_INIT, "Global reset polling failed to complete.\n");
1175 return -EIO;
1176 }
1177
1178#define ICE_RESET_DONE_MASK (GLNVM_ULD_PCIER_DONE_M |\
1179 GLNVM_ULD_PCIER_DONE_1_M |\
1180 GLNVM_ULD_CORER_DONE_M |\
1181 GLNVM_ULD_GLOBR_DONE_M |\
1182 GLNVM_ULD_POR_DONE_M |\
1183 GLNVM_ULD_POR_DONE_1_M |\
1184 GLNVM_ULD_PCIER_DONE_2_M)
1185
1186 uld_mask = ICE_RESET_DONE_MASK | (hw->func_caps.common_cap.rdma ?
1187 GLNVM_ULD_PE_DONE_M : 0);
1188
1189 /* Device is Active; check Global Reset processes are done */
1190 for (cnt = 0; cnt < ICE_PF_RESET_WAIT_COUNT; cnt++) {
1191 reg = rd32(hw, GLNVM_ULD) & uld_mask;
1192 if (reg == uld_mask) {
1193 ice_debug(hw, ICE_DBG_INIT, "Global reset processes done. %d\n", cnt);
1194 break;
1195 }
1196 mdelay(10);
1197 }
1198
1199 if (cnt == ICE_PF_RESET_WAIT_COUNT) {
1200 ice_debug(hw, ICE_DBG_INIT, "Wait for Reset Done timed out. GLNVM_ULD = 0x%x\n",
1201 reg);
1202 return -EIO;
1203 }
1204
1205 return 0;
1206}
1207
1208/**
1209 * ice_pf_reset - Reset the PF
1210 * @hw: pointer to the hardware structure
1211 *
1212 * If a global reset has been triggered, this function checks
1213 * for its completion and then issues the PF reset
1214 */
1215static int ice_pf_reset(struct ice_hw *hw)
1216{
1217 u32 cnt, reg;
1218
1219 /* If at function entry a global reset was already in progress, i.e.
1220 * state is not 'device active' or any of the reset done bits are not
1221 * set in GLNVM_ULD, there is no need for a PF Reset; poll until the
1222 * global reset is done.
1223 */
1224 if ((rd32(hw, GLGEN_RSTAT) & GLGEN_RSTAT_DEVSTATE_M) ||
1225 (rd32(hw, GLNVM_ULD) & ICE_RESET_DONE_MASK) ^ ICE_RESET_DONE_MASK) {
1226 /* poll on global reset currently in progress until done */
1227 if (ice_check_reset(hw))
1228 return -EIO;
1229
1230 return 0;
1231 }
1232
1233 /* Reset the PF */
1234 reg = rd32(hw, PFGEN_CTRL);
1235
1236 wr32(hw, PFGEN_CTRL, (reg | PFGEN_CTRL_PFSWR_M));
1237
1238 /* Wait for the PFR to complete. The wait time is the global config lock
1239 * timeout plus the PFR timeout which will account for a possible reset
1240 * that is occurring during a download package operation.
1241 */
1242 for (cnt = 0; cnt < ICE_GLOBAL_CFG_LOCK_TIMEOUT +
1243 ICE_PF_RESET_WAIT_COUNT; cnt++) {
1244 reg = rd32(hw, PFGEN_CTRL);
1245 if (!(reg & PFGEN_CTRL_PFSWR_M))
1246 break;
1247
1248 mdelay(1);
1249 }
1250
1251 if (cnt == ICE_PF_RESET_WAIT_COUNT) {
1252 ice_debug(hw, ICE_DBG_INIT, "PF reset polling failed to complete.\n");
1253 return -EIO;
1254 }
1255
1256 return 0;
1257}
1258
1259/**
1260 * ice_reset - Perform different types of reset
1261 * @hw: pointer to the hardware structure
1262 * @req: reset request
1263 *
1264 * This function triggers a reset as specified by the req parameter.
1265 *
1266 * Note:
1267 * If anything other than a PF reset is triggered, PXE mode is restored.
1268 * This has to be cleared using ice_clear_pxe_mode again, once the AQ
1269 * interface has been restored in the rebuild flow.
1270 */
1271int ice_reset(struct ice_hw *hw, enum ice_reset_req req)
1272{
1273 u32 val = 0;
1274
1275 switch (req) {
1276 case ICE_RESET_PFR:
1277 return ice_pf_reset(hw);
1278 case ICE_RESET_CORER:
1279 ice_debug(hw, ICE_DBG_INIT, "CoreR requested\n");
1280 val = GLGEN_RTRIG_CORER_M;
1281 break;
1282 case ICE_RESET_GLOBR:
1283 ice_debug(hw, ICE_DBG_INIT, "GlobalR requested\n");
1284 val = GLGEN_RTRIG_GLOBR_M;
1285 break;
1286 default:
1287 return -EINVAL;
1288 }
1289
1290 val |= rd32(hw, GLGEN_RTRIG);
1291 wr32(hw, GLGEN_RTRIG, val);
1292 ice_flush(hw);
1293
1294 /* wait for the FW to be ready */
1295 return ice_check_reset(hw);
1296}
1297
1298/**
1299 * ice_copy_rxq_ctx_to_hw
1300 * @hw: pointer to the hardware structure
1301 * @ice_rxq_ctx: pointer to the rxq context
1302 * @rxq_index: the index of the Rx queue
1303 *
1304 * Copies rxq context from dense structure to HW register space
1305 */
1306static int
1307ice_copy_rxq_ctx_to_hw(struct ice_hw *hw, u8 *ice_rxq_ctx, u32 rxq_index)
1308{
1309 u8 i;
1310
1311 if (!ice_rxq_ctx)
1312 return -EINVAL;
1313
1314 if (rxq_index > QRX_CTRL_MAX_INDEX)
1315 return -EINVAL;
1316
1317 /* Copy each dword separately to HW */
1318 for (i = 0; i < ICE_RXQ_CTX_SIZE_DWORDS; i++) {
1319 wr32(hw, QRX_CONTEXT(i, rxq_index),
1320 *((u32 *)(ice_rxq_ctx + (i * sizeof(u32)))));
1321
1322 ice_debug(hw, ICE_DBG_QCTX, "qrxdata[%d]: %08X\n", i,
1323 *((u32 *)(ice_rxq_ctx + (i * sizeof(u32)))));
1324 }
1325
1326 return 0;
1327}
1328
1329/* LAN Rx Queue Context */
1330static const struct ice_ctx_ele ice_rlan_ctx_info[] = {
1331 /* Field Width LSB */
1332 ICE_CTX_STORE(ice_rlan_ctx, head, 13, 0),
1333 ICE_CTX_STORE(ice_rlan_ctx, cpuid, 8, 13),
1334 ICE_CTX_STORE(ice_rlan_ctx, base, 57, 32),
1335 ICE_CTX_STORE(ice_rlan_ctx, qlen, 13, 89),
1336 ICE_CTX_STORE(ice_rlan_ctx, dbuf, 7, 102),
1337 ICE_CTX_STORE(ice_rlan_ctx, hbuf, 5, 109),
1338 ICE_CTX_STORE(ice_rlan_ctx, dtype, 2, 114),
1339 ICE_CTX_STORE(ice_rlan_ctx, dsize, 1, 116),
1340 ICE_CTX_STORE(ice_rlan_ctx, crcstrip, 1, 117),
1341 ICE_CTX_STORE(ice_rlan_ctx, l2tsel, 1, 119),
1342 ICE_CTX_STORE(ice_rlan_ctx, hsplit_0, 4, 120),
1343 ICE_CTX_STORE(ice_rlan_ctx, hsplit_1, 2, 124),
1344 ICE_CTX_STORE(ice_rlan_ctx, showiv, 1, 127),
1345 ICE_CTX_STORE(ice_rlan_ctx, rxmax, 14, 174),
1346 ICE_CTX_STORE(ice_rlan_ctx, tphrdesc_ena, 1, 193),
1347 ICE_CTX_STORE(ice_rlan_ctx, tphwdesc_ena, 1, 194),
1348 ICE_CTX_STORE(ice_rlan_ctx, tphdata_ena, 1, 195),
1349 ICE_CTX_STORE(ice_rlan_ctx, tphhead_ena, 1, 196),
1350 ICE_CTX_STORE(ice_rlan_ctx, lrxqthresh, 3, 198),
1351 ICE_CTX_STORE(ice_rlan_ctx, prefena, 1, 201),
1352 { 0 }
1353};
1354
1355/**
1356 * ice_write_rxq_ctx
1357 * @hw: pointer to the hardware structure
1358 * @rlan_ctx: pointer to the rxq context
1359 * @rxq_index: the index of the Rx queue
1360 *
1361 * Converts rxq context from sparse to dense structure and then writes
1362 * it to HW register space and enables the hardware to prefetch descriptors
1363 * instead of only fetching them on demand
1364 */
1365int
1366ice_write_rxq_ctx(struct ice_hw *hw, struct ice_rlan_ctx *rlan_ctx,
1367 u32 rxq_index)
1368{
1369 u8 ctx_buf[ICE_RXQ_CTX_SZ] = { 0 };
1370
1371 if (!rlan_ctx)
1372 return -EINVAL;
1373
1374 rlan_ctx->prefena = 1;
1375
1376 ice_set_ctx(hw, (u8 *)rlan_ctx, ctx_buf, ice_rlan_ctx_info);
1377 return ice_copy_rxq_ctx_to_hw(hw, ctx_buf, rxq_index);
1378}
1379
1380/* LAN Tx Queue Context */
1381const struct ice_ctx_ele ice_tlan_ctx_info[] = {
1382 /* Field Width LSB */
1383 ICE_CTX_STORE(ice_tlan_ctx, base, 57, 0),
1384 ICE_CTX_STORE(ice_tlan_ctx, port_num, 3, 57),
1385 ICE_CTX_STORE(ice_tlan_ctx, cgd_num, 5, 60),
1386 ICE_CTX_STORE(ice_tlan_ctx, pf_num, 3, 65),
1387 ICE_CTX_STORE(ice_tlan_ctx, vmvf_num, 10, 68),
1388 ICE_CTX_STORE(ice_tlan_ctx, vmvf_type, 2, 78),
1389 ICE_CTX_STORE(ice_tlan_ctx, src_vsi, 10, 80),
1390 ICE_CTX_STORE(ice_tlan_ctx, tsyn_ena, 1, 90),
1391 ICE_CTX_STORE(ice_tlan_ctx, internal_usage_flag, 1, 91),
1392 ICE_CTX_STORE(ice_tlan_ctx, alt_vlan, 1, 92),
1393 ICE_CTX_STORE(ice_tlan_ctx, cpuid, 8, 93),
1394 ICE_CTX_STORE(ice_tlan_ctx, wb_mode, 1, 101),
1395 ICE_CTX_STORE(ice_tlan_ctx, tphrd_desc, 1, 102),
1396 ICE_CTX_STORE(ice_tlan_ctx, tphrd, 1, 103),
1397 ICE_CTX_STORE(ice_tlan_ctx, tphwr_desc, 1, 104),
1398 ICE_CTX_STORE(ice_tlan_ctx, cmpq_id, 9, 105),
1399 ICE_CTX_STORE(ice_tlan_ctx, qnum_in_func, 14, 114),
1400 ICE_CTX_STORE(ice_tlan_ctx, itr_notification_mode, 1, 128),
1401 ICE_CTX_STORE(ice_tlan_ctx, adjust_prof_id, 6, 129),
1402 ICE_CTX_STORE(ice_tlan_ctx, qlen, 13, 135),
1403 ICE_CTX_STORE(ice_tlan_ctx, quanta_prof_idx, 4, 148),
1404 ICE_CTX_STORE(ice_tlan_ctx, tso_ena, 1, 152),
1405 ICE_CTX_STORE(ice_tlan_ctx, tso_qnum, 11, 153),
1406 ICE_CTX_STORE(ice_tlan_ctx, legacy_int, 1, 164),
1407 ICE_CTX_STORE(ice_tlan_ctx, drop_ena, 1, 165),
1408 ICE_CTX_STORE(ice_tlan_ctx, cache_prof_idx, 2, 166),
1409 ICE_CTX_STORE(ice_tlan_ctx, pkt_shaper_prof_idx, 3, 168),
1410 ICE_CTX_STORE(ice_tlan_ctx, int_q_state, 122, 171),
1411 { 0 }
1412};
1413
1414/* Sideband Queue command wrappers */
1415
1416/**
1417 * ice_sbq_send_cmd - send Sideband Queue command to Sideband Queue
1418 * @hw: pointer to the HW struct
1419 * @desc: descriptor describing the command
1420 * @buf: buffer to use for indirect commands (NULL for direct commands)
1421 * @buf_size: size of buffer for indirect commands (0 for direct commands)
1422 * @cd: pointer to command details structure
1423 */
1424static int
1425ice_sbq_send_cmd(struct ice_hw *hw, struct ice_sbq_cmd_desc *desc,
1426 void *buf, u16 buf_size, struct ice_sq_cd *cd)
1427{
1428 return ice_sq_send_cmd(hw, ice_get_sbq(hw),
1429 (struct ice_aq_desc *)desc, buf, buf_size, cd);
1430}
1431
1432/**
1433 * ice_sbq_rw_reg - Fill Sideband Queue command
1434 * @hw: pointer to the HW struct
1435 * @in: message info to be filled in descriptor
1436 */
1437int ice_sbq_rw_reg(struct ice_hw *hw, struct ice_sbq_msg_input *in)
1438{
1439 struct ice_sbq_cmd_desc desc = {0};
1440 struct ice_sbq_msg_req msg = {0};
1441 u16 msg_len;
1442 int status;
1443
1444 msg_len = sizeof(msg);
1445
1446 msg.dest_dev = in->dest_dev;
1447 msg.opcode = in->opcode;
1448 msg.flags = ICE_SBQ_MSG_FLAGS;
1449 msg.sbe_fbe = ICE_SBQ_MSG_SBE_FBE;
1450 msg.msg_addr_low = cpu_to_le16(in->msg_addr_low);
1451 msg.msg_addr_high = cpu_to_le32(in->msg_addr_high);
1452
1453 if (in->opcode)
1454 msg.data = cpu_to_le32(in->data);
1455 else
1456 /* data read comes back in completion, so shorten the struct by
1457 * sizeof(msg.data)
1458 */
1459 msg_len -= sizeof(msg.data);
1460
1461 desc.flags = cpu_to_le16(ICE_AQ_FLAG_RD);
1462 desc.opcode = cpu_to_le16(ice_sbq_opc_neigh_dev_req);
1463 desc.param0.cmd_len = cpu_to_le16(msg_len);
1464 status = ice_sbq_send_cmd(hw, &desc, &msg, msg_len, NULL);
1465 if (!status && !in->opcode)
1466 in->data = le32_to_cpu
1467 (((struct ice_sbq_msg_cmpl *)&msg)->data);
1468 return status;
1469}
1470
1471/* FW Admin Queue command wrappers */
1472
1473/* Software lock/mutex that is meant to be held while the Global Config Lock
1474 * in firmware is acquired by the software to prevent most (but not all) types
1475 * of AQ commands from being sent to FW
1476 */
1477DEFINE_MUTEX(ice_global_cfg_lock_sw);
1478
1479/**
1480 * ice_should_retry_sq_send_cmd
1481 * @opcode: AQ opcode
1482 *
1483 * Decide if we should retry the send command routine for the ATQ, depending
1484 * on the opcode.
1485 */
1486static bool ice_should_retry_sq_send_cmd(u16 opcode)
1487{
1488 switch (opcode) {
1489 case ice_aqc_opc_get_link_topo:
1490 case ice_aqc_opc_lldp_stop:
1491 case ice_aqc_opc_lldp_start:
1492 case ice_aqc_opc_lldp_filter_ctrl:
1493 return true;
1494 }
1495
1496 return false;
1497}
1498
1499/**
1500 * ice_sq_send_cmd_retry - send command to Control Queue (ATQ)
1501 * @hw: pointer to the HW struct
1502 * @cq: pointer to the specific Control queue
1503 * @desc: prefilled descriptor describing the command
1504 * @buf: buffer to use for indirect commands (or NULL for direct commands)
1505 * @buf_size: size of buffer for indirect commands (or 0 for direct commands)
1506 * @cd: pointer to command details structure
1507 *
1508 * Retry sending the FW Admin Queue command, multiple times, to the FW Admin
1509 * Queue if the EBUSY AQ error is returned.
1510 */
1511static int
1512ice_sq_send_cmd_retry(struct ice_hw *hw, struct ice_ctl_q_info *cq,
1513 struct ice_aq_desc *desc, void *buf, u16 buf_size,
1514 struct ice_sq_cd *cd)
1515{
1516 struct ice_aq_desc desc_cpy;
1517 bool is_cmd_for_retry;
1518 u8 idx = 0;
1519 u16 opcode;
1520 int status;
1521
1522 opcode = le16_to_cpu(desc->opcode);
1523 is_cmd_for_retry = ice_should_retry_sq_send_cmd(opcode);
1524 memset(&desc_cpy, 0, sizeof(desc_cpy));
1525
1526 if (is_cmd_for_retry) {
1527 /* All retryable cmds are direct, without buf. */
1528 WARN_ON(buf);
1529
1530 memcpy(&desc_cpy, desc, sizeof(desc_cpy));
1531 }
1532
1533 do {
1534 status = ice_sq_send_cmd(hw, cq, desc, buf, buf_size, cd);
1535
1536 if (!is_cmd_for_retry || !status ||
1537 hw->adminq.sq_last_status != ICE_AQ_RC_EBUSY)
1538 break;
1539
1540 memcpy(desc, &desc_cpy, sizeof(desc_cpy));
1541
1542 msleep(ICE_SQ_SEND_DELAY_TIME_MS);
1543
1544 } while (++idx < ICE_SQ_SEND_MAX_EXECUTE);
1545
1546 return status;
1547}
1548
1549/**
1550 * ice_aq_send_cmd - send FW Admin Queue command to FW Admin Queue
1551 * @hw: pointer to the HW struct
1552 * @desc: descriptor describing the command
1553 * @buf: buffer to use for indirect commands (NULL for direct commands)
1554 * @buf_size: size of buffer for indirect commands (0 for direct commands)
1555 * @cd: pointer to command details structure
1556 *
1557 * Helper function to send FW Admin Queue commands to the FW Admin Queue.
1558 */
1559int
1560ice_aq_send_cmd(struct ice_hw *hw, struct ice_aq_desc *desc, void *buf,
1561 u16 buf_size, struct ice_sq_cd *cd)
1562{
1563 struct ice_aqc_req_res *cmd = &desc->params.res_owner;
1564 bool lock_acquired = false;
1565 int status;
1566
1567 /* When a package download is in process (i.e. when the firmware's
1568 * Global Configuration Lock resource is held), only the Download
1569 * Package, Get Version, Get Package Info List, Upload Section,
1570 * Update Package, Set Port Parameters, Get/Set VLAN Mode Parameters,
1571 * Add Recipe, Set Recipes to Profile Association, Get Recipe, and Get
1572 * Recipes to Profile Association, and Release Resource (with resource
1573 * ID set to Global Config Lock) AdminQ commands are allowed; all others
1574 * must block until the package download completes and the Global Config
1575 * Lock is released. See also ice_acquire_global_cfg_lock().
1576 */
1577 switch (le16_to_cpu(desc->opcode)) {
1578 case ice_aqc_opc_download_pkg:
1579 case ice_aqc_opc_get_pkg_info_list:
1580 case ice_aqc_opc_get_ver:
1581 case ice_aqc_opc_upload_section:
1582 case ice_aqc_opc_update_pkg:
1583 case ice_aqc_opc_set_port_params:
1584 case ice_aqc_opc_get_vlan_mode_parameters:
1585 case ice_aqc_opc_set_vlan_mode_parameters:
1586 case ice_aqc_opc_add_recipe:
1587 case ice_aqc_opc_recipe_to_profile:
1588 case ice_aqc_opc_get_recipe:
1589 case ice_aqc_opc_get_recipe_to_profile:
1590 break;
1591 case ice_aqc_opc_release_res:
1592 if (le16_to_cpu(cmd->res_id) == ICE_AQC_RES_ID_GLBL_LOCK)
1593 break;
1594 fallthrough;
1595 default:
1596 mutex_lock(&ice_global_cfg_lock_sw);
1597 lock_acquired = true;
1598 break;
1599 }
1600
1601 status = ice_sq_send_cmd_retry(hw, &hw->adminq, desc, buf, buf_size, cd);
1602 if (lock_acquired)
1603 mutex_unlock(&ice_global_cfg_lock_sw);
1604
1605 return status;
1606}
1607
1608/**
1609 * ice_aq_get_fw_ver
1610 * @hw: pointer to the HW struct
1611 * @cd: pointer to command details structure or NULL
1612 *
1613 * Get the firmware version (0x0001) from the admin queue commands
1614 */
1615int ice_aq_get_fw_ver(struct ice_hw *hw, struct ice_sq_cd *cd)
1616{
1617 struct ice_aqc_get_ver *resp;
1618 struct ice_aq_desc desc;
1619 int status;
1620
1621 resp = &desc.params.get_ver;
1622
1623 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_ver);
1624
1625 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1626
1627 if (!status) {
1628 hw->fw_branch = resp->fw_branch;
1629 hw->fw_maj_ver = resp->fw_major;
1630 hw->fw_min_ver = resp->fw_minor;
1631 hw->fw_patch = resp->fw_patch;
1632 hw->fw_build = le32_to_cpu(resp->fw_build);
1633 hw->api_branch = resp->api_branch;
1634 hw->api_maj_ver = resp->api_major;
1635 hw->api_min_ver = resp->api_minor;
1636 hw->api_patch = resp->api_patch;
1637 }
1638
1639 return status;
1640}
1641
1642/**
1643 * ice_aq_send_driver_ver
1644 * @hw: pointer to the HW struct
1645 * @dv: driver's major, minor version
1646 * @cd: pointer to command details structure or NULL
1647 *
1648 * Send the driver version (0x0002) to the firmware
1649 */
1650int
1651ice_aq_send_driver_ver(struct ice_hw *hw, struct ice_driver_ver *dv,
1652 struct ice_sq_cd *cd)
1653{
1654 struct ice_aqc_driver_ver *cmd;
1655 struct ice_aq_desc desc;
1656 u16 len;
1657
1658 cmd = &desc.params.driver_ver;
1659
1660 if (!dv)
1661 return -EINVAL;
1662
1663 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_driver_ver);
1664
1665 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
1666 cmd->major_ver = dv->major_ver;
1667 cmd->minor_ver = dv->minor_ver;
1668 cmd->build_ver = dv->build_ver;
1669 cmd->subbuild_ver = dv->subbuild_ver;
1670
1671 len = 0;
1672 while (len < sizeof(dv->driver_string) &&
1673 isascii(dv->driver_string[len]) && dv->driver_string[len])
1674 len++;
1675
1676 return ice_aq_send_cmd(hw, &desc, dv->driver_string, len, cd);
1677}
1678
1679/**
1680 * ice_aq_q_shutdown
1681 * @hw: pointer to the HW struct
1682 * @unloading: is the driver unloading itself
1683 *
1684 * Tell the Firmware that we're shutting down the AdminQ and whether
1685 * or not the driver is unloading as well (0x0003).
1686 */
1687int ice_aq_q_shutdown(struct ice_hw *hw, bool unloading)
1688{
1689 struct ice_aqc_q_shutdown *cmd;
1690 struct ice_aq_desc desc;
1691
1692 cmd = &desc.params.q_shutdown;
1693
1694 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_q_shutdown);
1695
1696 if (unloading)
1697 cmd->driver_unloading = ICE_AQC_DRIVER_UNLOADING;
1698
1699 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
1700}
1701
1702/**
1703 * ice_aq_req_res
1704 * @hw: pointer to the HW struct
1705 * @res: resource ID
1706 * @access: access type
1707 * @sdp_number: resource number
1708 * @timeout: the maximum time in ms that the driver may hold the resource
1709 * @cd: pointer to command details structure or NULL
1710 *
1711 * Requests common resource using the admin queue commands (0x0008).
1712 * When attempting to acquire the Global Config Lock, the driver can
1713 * learn of three states:
1714 * 1) 0 - acquired lock, and can perform download package
1715 * 2) -EIO - did not get lock, driver should fail to load
1716 * 3) -EALREADY - did not get lock, but another driver has
1717 * successfully downloaded the package; the driver does
1718 * not have to download the package and can continue
1719 * loading
1720 *
1721 * Note that if the caller is in an acquire lock, perform action, release lock
1722 * phase of operation, it is possible that the FW may detect a timeout and issue
1723 * a CORER. In this case, the driver will receive a CORER interrupt and will
1724 * have to determine its cause. The calling thread that is handling this flow
1725 * will likely get an error propagated back to it indicating the Download
1726 * Package, Update Package or the Release Resource AQ commands timed out.
1727 */
1728static int
1729ice_aq_req_res(struct ice_hw *hw, enum ice_aq_res_ids res,
1730 enum ice_aq_res_access_type access, u8 sdp_number, u32 *timeout,
1731 struct ice_sq_cd *cd)
1732{
1733 struct ice_aqc_req_res *cmd_resp;
1734 struct ice_aq_desc desc;
1735 int status;
1736
1737 cmd_resp = &desc.params.res_owner;
1738
1739 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_req_res);
1740
1741 cmd_resp->res_id = cpu_to_le16(res);
1742 cmd_resp->access_type = cpu_to_le16(access);
1743 cmd_resp->res_number = cpu_to_le32(sdp_number);
1744 cmd_resp->timeout = cpu_to_le32(*timeout);
1745 *timeout = 0;
1746
1747 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1748
1749 /* The completion specifies the maximum time in ms that the driver
1750 * may hold the resource in the Timeout field.
1751 */
1752
1753 /* Global config lock response utilizes an additional status field.
1754 *
1755 * If the Global config lock resource is held by some other driver, the
1756 * command completes with ICE_AQ_RES_GLBL_IN_PROG in the status field
1757 * and the timeout field indicates the maximum time the current owner
1758 * of the resource has to free it.
1759 */
1760 if (res == ICE_GLOBAL_CFG_LOCK_RES_ID) {
1761 if (le16_to_cpu(cmd_resp->status) == ICE_AQ_RES_GLBL_SUCCESS) {
1762 *timeout = le32_to_cpu(cmd_resp->timeout);
1763 return 0;
1764 } else if (le16_to_cpu(cmd_resp->status) ==
1765 ICE_AQ_RES_GLBL_IN_PROG) {
1766 *timeout = le32_to_cpu(cmd_resp->timeout);
1767 return -EIO;
1768 } else if (le16_to_cpu(cmd_resp->status) ==
1769 ICE_AQ_RES_GLBL_DONE) {
1770 return -EALREADY;
1771 }
1772
1773 /* invalid FW response, force a timeout immediately */
1774 *timeout = 0;
1775 return -EIO;
1776 }
1777
1778 /* If the resource is held by some other driver, the command completes
1779 * with a busy return value and the timeout field indicates the maximum
1780 * time the current owner of the resource has to free it.
1781 */
1782 if (!status || hw->adminq.sq_last_status == ICE_AQ_RC_EBUSY)
1783 *timeout = le32_to_cpu(cmd_resp->timeout);
1784
1785 return status;
1786}
1787
1788/**
1789 * ice_aq_release_res
1790 * @hw: pointer to the HW struct
1791 * @res: resource ID
1792 * @sdp_number: resource number
1793 * @cd: pointer to command details structure or NULL
1794 *
1795 * release common resource using the admin queue commands (0x0009)
1796 */
1797static int
1798ice_aq_release_res(struct ice_hw *hw, enum ice_aq_res_ids res, u8 sdp_number,
1799 struct ice_sq_cd *cd)
1800{
1801 struct ice_aqc_req_res *cmd;
1802 struct ice_aq_desc desc;
1803
1804 cmd = &desc.params.res_owner;
1805
1806 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_release_res);
1807
1808 cmd->res_id = cpu_to_le16(res);
1809 cmd->res_number = cpu_to_le32(sdp_number);
1810
1811 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1812}
1813
1814/**
1815 * ice_acquire_res
1816 * @hw: pointer to the HW structure
1817 * @res: resource ID
1818 * @access: access type (read or write)
1819 * @timeout: timeout in milliseconds
1820 *
1821 * This function will attempt to acquire the ownership of a resource.
1822 */
1823int
1824ice_acquire_res(struct ice_hw *hw, enum ice_aq_res_ids res,
1825 enum ice_aq_res_access_type access, u32 timeout)
1826{
1827#define ICE_RES_POLLING_DELAY_MS 10
1828 u32 delay = ICE_RES_POLLING_DELAY_MS;
1829 u32 time_left = timeout;
1830 int status;
1831
1832 status = ice_aq_req_res(hw, res, access, 0, &time_left, NULL);
1833
1834 /* A return code of -EALREADY means that another driver has
1835 * previously acquired the resource and performed any necessary updates;
1836 * in this case the caller does not obtain the resource and has no
1837 * further work to do.
1838 */
1839 if (status == -EALREADY)
1840 goto ice_acquire_res_exit;
1841
1842 if (status)
1843 ice_debug(hw, ICE_DBG_RES, "resource %d acquire type %d failed.\n", res, access);
1844
1845 /* If necessary, poll until the current lock owner timeouts */
1846 timeout = time_left;
1847 while (status && timeout && time_left) {
1848 mdelay(delay);
1849 timeout = (timeout > delay) ? timeout - delay : 0;
1850 status = ice_aq_req_res(hw, res, access, 0, &time_left, NULL);
1851
1852 if (status == -EALREADY)
1853 /* lock free, but no work to do */
1854 break;
1855
1856 if (!status)
1857 /* lock acquired */
1858 break;
1859 }
1860 if (status && status != -EALREADY)
1861 ice_debug(hw, ICE_DBG_RES, "resource acquire timed out.\n");
1862
1863ice_acquire_res_exit:
1864 if (status == -EALREADY) {
1865 if (access == ICE_RES_WRITE)
1866 ice_debug(hw, ICE_DBG_RES, "resource indicates no work to do.\n");
1867 else
1868 ice_debug(hw, ICE_DBG_RES, "Warning: -EALREADY not expected\n");
1869 }
1870 return status;
1871}
1872
1873/**
1874 * ice_release_res
1875 * @hw: pointer to the HW structure
1876 * @res: resource ID
1877 *
1878 * This function will release a resource using the proper Admin Command.
1879 */
1880void ice_release_res(struct ice_hw *hw, enum ice_aq_res_ids res)
1881{
1882 unsigned long timeout;
1883 int status;
1884
1885 /* there are some rare cases when trying to release the resource
1886 * results in an admin queue timeout, so handle them correctly
1887 */
1888 timeout = jiffies + 10 * ICE_CTL_Q_SQ_CMD_TIMEOUT;
1889 do {
1890 status = ice_aq_release_res(hw, res, 0, NULL);
1891 if (status != -EIO)
1892 break;
1893 usleep_range(1000, 2000);
1894 } while (time_before(jiffies, timeout));
1895}
1896
1897/**
1898 * ice_aq_alloc_free_res - command to allocate/free resources
1899 * @hw: pointer to the HW struct
1900 * @buf: Indirect buffer to hold data parameters and response
1901 * @buf_size: size of buffer for indirect commands
1902 * @opc: pass in the command opcode
1903 *
1904 * Helper function to allocate/free resources using the admin queue commands
1905 */
1906int ice_aq_alloc_free_res(struct ice_hw *hw,
1907 struct ice_aqc_alloc_free_res_elem *buf, u16 buf_size,
1908 enum ice_adminq_opc opc)
1909{
1910 struct ice_aqc_alloc_free_res_cmd *cmd;
1911 struct ice_aq_desc desc;
1912
1913 cmd = &desc.params.sw_res_ctrl;
1914
1915 if (!buf || buf_size < flex_array_size(buf, elem, 1))
1916 return -EINVAL;
1917
1918 ice_fill_dflt_direct_cmd_desc(&desc, opc);
1919
1920 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
1921
1922 cmd->num_entries = cpu_to_le16(1);
1923
1924 return ice_aq_send_cmd(hw, &desc, buf, buf_size, NULL);
1925}
1926
1927/**
1928 * ice_alloc_hw_res - allocate resource
1929 * @hw: pointer to the HW struct
1930 * @type: type of resource
1931 * @num: number of resources to allocate
1932 * @btm: allocate from bottom
1933 * @res: pointer to array that will receive the resources
1934 */
1935int
1936ice_alloc_hw_res(struct ice_hw *hw, u16 type, u16 num, bool btm, u16 *res)
1937{
1938 struct ice_aqc_alloc_free_res_elem *buf;
1939 u16 buf_len;
1940 int status;
1941
1942 buf_len = struct_size(buf, elem, num);
1943 buf = kzalloc(buf_len, GFP_KERNEL);
1944 if (!buf)
1945 return -ENOMEM;
1946
1947 /* Prepare buffer to allocate resource. */
1948 buf->num_elems = cpu_to_le16(num);
1949 buf->res_type = cpu_to_le16(type | ICE_AQC_RES_TYPE_FLAG_DEDICATED |
1950 ICE_AQC_RES_TYPE_FLAG_IGNORE_INDEX);
1951 if (btm)
1952 buf->res_type |= cpu_to_le16(ICE_AQC_RES_TYPE_FLAG_SCAN_BOTTOM);
1953
1954 status = ice_aq_alloc_free_res(hw, buf, buf_len, ice_aqc_opc_alloc_res);
1955 if (status)
1956 goto ice_alloc_res_exit;
1957
1958 memcpy(res, buf->elem, sizeof(*buf->elem) * num);
1959
1960ice_alloc_res_exit:
1961 kfree(buf);
1962 return status;
1963}
1964
1965/**
1966 * ice_free_hw_res - free allocated HW resource
1967 * @hw: pointer to the HW struct
1968 * @type: type of resource to free
1969 * @num: number of resources
1970 * @res: pointer to array that contains the resources to free
1971 */
1972int ice_free_hw_res(struct ice_hw *hw, u16 type, u16 num, u16 *res)
1973{
1974 struct ice_aqc_alloc_free_res_elem *buf;
1975 u16 buf_len;
1976 int status;
1977
1978 buf_len = struct_size(buf, elem, num);
1979 buf = kzalloc(buf_len, GFP_KERNEL);
1980 if (!buf)
1981 return -ENOMEM;
1982
1983 /* Prepare buffer to free resource. */
1984 buf->num_elems = cpu_to_le16(num);
1985 buf->res_type = cpu_to_le16(type);
1986 memcpy(buf->elem, res, sizeof(*buf->elem) * num);
1987
1988 status = ice_aq_alloc_free_res(hw, buf, buf_len, ice_aqc_opc_free_res);
1989 if (status)
1990 ice_debug(hw, ICE_DBG_SW, "CQ CMD Buffer:\n");
1991
1992 kfree(buf);
1993 return status;
1994}
1995
1996/**
1997 * ice_get_num_per_func - determine number of resources per PF
1998 * @hw: pointer to the HW structure
1999 * @max: value to be evenly split between each PF
2000 *
2001 * Determine the number of valid functions by going through the bitmap returned
2002 * from parsing capabilities and use this to calculate the number of resources
2003 * per PF based on the max value passed in.
2004 */
2005static u32 ice_get_num_per_func(struct ice_hw *hw, u32 max)
2006{
2007 u8 funcs;
2008
2009#define ICE_CAPS_VALID_FUNCS_M 0xFF
2010 funcs = hweight8(hw->dev_caps.common_cap.valid_functions &
2011 ICE_CAPS_VALID_FUNCS_M);
2012
2013 if (!funcs)
2014 return 0;
2015
2016 return max / funcs;
2017}
2018
2019/**
2020 * ice_parse_common_caps - parse common device/function capabilities
2021 * @hw: pointer to the HW struct
2022 * @caps: pointer to common capabilities structure
2023 * @elem: the capability element to parse
2024 * @prefix: message prefix for tracing capabilities
2025 *
2026 * Given a capability element, extract relevant details into the common
2027 * capability structure.
2028 *
2029 * Returns: true if the capability matches one of the common capability ids,
2030 * false otherwise.
2031 */
2032static bool
2033ice_parse_common_caps(struct ice_hw *hw, struct ice_hw_common_caps *caps,
2034 struct ice_aqc_list_caps_elem *elem, const char *prefix)
2035{
2036 u32 logical_id = le32_to_cpu(elem->logical_id);
2037 u32 phys_id = le32_to_cpu(elem->phys_id);
2038 u32 number = le32_to_cpu(elem->number);
2039 u16 cap = le16_to_cpu(elem->cap);
2040 bool found = true;
2041
2042 switch (cap) {
2043 case ICE_AQC_CAPS_VALID_FUNCTIONS:
2044 caps->valid_functions = number;
2045 ice_debug(hw, ICE_DBG_INIT, "%s: valid_functions (bitmap) = %d\n", prefix,
2046 caps->valid_functions);
2047 break;
2048 case ICE_AQC_CAPS_SRIOV:
2049 caps->sr_iov_1_1 = (number == 1);
2050 ice_debug(hw, ICE_DBG_INIT, "%s: sr_iov_1_1 = %d\n", prefix,
2051 caps->sr_iov_1_1);
2052 break;
2053 case ICE_AQC_CAPS_DCB:
2054 caps->dcb = (number == 1);
2055 caps->active_tc_bitmap = logical_id;
2056 caps->maxtc = phys_id;
2057 ice_debug(hw, ICE_DBG_INIT, "%s: dcb = %d\n", prefix, caps->dcb);
2058 ice_debug(hw, ICE_DBG_INIT, "%s: active_tc_bitmap = %d\n", prefix,
2059 caps->active_tc_bitmap);
2060 ice_debug(hw, ICE_DBG_INIT, "%s: maxtc = %d\n", prefix, caps->maxtc);
2061 break;
2062 case ICE_AQC_CAPS_RSS:
2063 caps->rss_table_size = number;
2064 caps->rss_table_entry_width = logical_id;
2065 ice_debug(hw, ICE_DBG_INIT, "%s: rss_table_size = %d\n", prefix,
2066 caps->rss_table_size);
2067 ice_debug(hw, ICE_DBG_INIT, "%s: rss_table_entry_width = %d\n", prefix,
2068 caps->rss_table_entry_width);
2069 break;
2070 case ICE_AQC_CAPS_RXQS:
2071 caps->num_rxq = number;
2072 caps->rxq_first_id = phys_id;
2073 ice_debug(hw, ICE_DBG_INIT, "%s: num_rxq = %d\n", prefix,
2074 caps->num_rxq);
2075 ice_debug(hw, ICE_DBG_INIT, "%s: rxq_first_id = %d\n", prefix,
2076 caps->rxq_first_id);
2077 break;
2078 case ICE_AQC_CAPS_TXQS:
2079 caps->num_txq = number;
2080 caps->txq_first_id = phys_id;
2081 ice_debug(hw, ICE_DBG_INIT, "%s: num_txq = %d\n", prefix,
2082 caps->num_txq);
2083 ice_debug(hw, ICE_DBG_INIT, "%s: txq_first_id = %d\n", prefix,
2084 caps->txq_first_id);
2085 break;
2086 case ICE_AQC_CAPS_MSIX:
2087 caps->num_msix_vectors = number;
2088 caps->msix_vector_first_id = phys_id;
2089 ice_debug(hw, ICE_DBG_INIT, "%s: num_msix_vectors = %d\n", prefix,
2090 caps->num_msix_vectors);
2091 ice_debug(hw, ICE_DBG_INIT, "%s: msix_vector_first_id = %d\n", prefix,
2092 caps->msix_vector_first_id);
2093 break;
2094 case ICE_AQC_CAPS_PENDING_NVM_VER:
2095 caps->nvm_update_pending_nvm = true;
2096 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_nvm\n", prefix);
2097 break;
2098 case ICE_AQC_CAPS_PENDING_OROM_VER:
2099 caps->nvm_update_pending_orom = true;
2100 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_orom\n", prefix);
2101 break;
2102 case ICE_AQC_CAPS_PENDING_NET_VER:
2103 caps->nvm_update_pending_netlist = true;
2104 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_netlist\n", prefix);
2105 break;
2106 case ICE_AQC_CAPS_NVM_MGMT:
2107 caps->nvm_unified_update =
2108 (number & ICE_NVM_MGMT_UNIFIED_UPD_SUPPORT) ?
2109 true : false;
2110 ice_debug(hw, ICE_DBG_INIT, "%s: nvm_unified_update = %d\n", prefix,
2111 caps->nvm_unified_update);
2112 break;
2113 case ICE_AQC_CAPS_RDMA:
2114 caps->rdma = (number == 1);
2115 ice_debug(hw, ICE_DBG_INIT, "%s: rdma = %d\n", prefix, caps->rdma);
2116 break;
2117 case ICE_AQC_CAPS_MAX_MTU:
2118 caps->max_mtu = number;
2119 ice_debug(hw, ICE_DBG_INIT, "%s: max_mtu = %d\n",
2120 prefix, caps->max_mtu);
2121 break;
2122 case ICE_AQC_CAPS_PCIE_RESET_AVOIDANCE:
2123 caps->pcie_reset_avoidance = (number > 0);
2124 ice_debug(hw, ICE_DBG_INIT,
2125 "%s: pcie_reset_avoidance = %d\n", prefix,
2126 caps->pcie_reset_avoidance);
2127 break;
2128 case ICE_AQC_CAPS_POST_UPDATE_RESET_RESTRICT:
2129 caps->reset_restrict_support = (number == 1);
2130 ice_debug(hw, ICE_DBG_INIT,
2131 "%s: reset_restrict_support = %d\n", prefix,
2132 caps->reset_restrict_support);
2133 break;
2134 case ICE_AQC_CAPS_FW_LAG_SUPPORT:
2135 caps->roce_lag = !!(number & ICE_AQC_BIT_ROCEV2_LAG);
2136 ice_debug(hw, ICE_DBG_INIT, "%s: roce_lag = %u\n",
2137 prefix, caps->roce_lag);
2138 caps->sriov_lag = !!(number & ICE_AQC_BIT_SRIOV_LAG);
2139 ice_debug(hw, ICE_DBG_INIT, "%s: sriov_lag = %u\n",
2140 prefix, caps->sriov_lag);
2141 break;
2142 default:
2143 /* Not one of the recognized common capabilities */
2144 found = false;
2145 }
2146
2147 return found;
2148}
2149
2150/**
2151 * ice_recalc_port_limited_caps - Recalculate port limited capabilities
2152 * @hw: pointer to the HW structure
2153 * @caps: pointer to capabilities structure to fix
2154 *
2155 * Re-calculate the capabilities that are dependent on the number of physical
2156 * ports; i.e. some features are not supported or function differently on
2157 * devices with more than 4 ports.
2158 */
2159static void
2160ice_recalc_port_limited_caps(struct ice_hw *hw, struct ice_hw_common_caps *caps)
2161{
2162 /* This assumes device capabilities are always scanned before function
2163 * capabilities during the initialization flow.
2164 */
2165 if (hw->dev_caps.num_funcs > 4) {
2166 /* Max 4 TCs per port */
2167 caps->maxtc = 4;
2168 ice_debug(hw, ICE_DBG_INIT, "reducing maxtc to %d (based on #ports)\n",
2169 caps->maxtc);
2170 if (caps->rdma) {
2171 ice_debug(hw, ICE_DBG_INIT, "forcing RDMA off\n");
2172 caps->rdma = 0;
2173 }
2174
2175 /* print message only when processing device capabilities
2176 * during initialization.
2177 */
2178 if (caps == &hw->dev_caps.common_cap)
2179 dev_info(ice_hw_to_dev(hw), "RDMA functionality is not available with the current device configuration.\n");
2180 }
2181}
2182
2183/**
2184 * ice_parse_vf_func_caps - Parse ICE_AQC_CAPS_VF function caps
2185 * @hw: pointer to the HW struct
2186 * @func_p: pointer to function capabilities structure
2187 * @cap: pointer to the capability element to parse
2188 *
2189 * Extract function capabilities for ICE_AQC_CAPS_VF.
2190 */
2191static void
2192ice_parse_vf_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2193 struct ice_aqc_list_caps_elem *cap)
2194{
2195 u32 logical_id = le32_to_cpu(cap->logical_id);
2196 u32 number = le32_to_cpu(cap->number);
2197
2198 func_p->num_allocd_vfs = number;
2199 func_p->vf_base_id = logical_id;
2200 ice_debug(hw, ICE_DBG_INIT, "func caps: num_allocd_vfs = %d\n",
2201 func_p->num_allocd_vfs);
2202 ice_debug(hw, ICE_DBG_INIT, "func caps: vf_base_id = %d\n",
2203 func_p->vf_base_id);
2204}
2205
2206/**
2207 * ice_parse_vsi_func_caps - Parse ICE_AQC_CAPS_VSI function caps
2208 * @hw: pointer to the HW struct
2209 * @func_p: pointer to function capabilities structure
2210 * @cap: pointer to the capability element to parse
2211 *
2212 * Extract function capabilities for ICE_AQC_CAPS_VSI.
2213 */
2214static void
2215ice_parse_vsi_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2216 struct ice_aqc_list_caps_elem *cap)
2217{
2218 func_p->guar_num_vsi = ice_get_num_per_func(hw, ICE_MAX_VSI);
2219 ice_debug(hw, ICE_DBG_INIT, "func caps: guar_num_vsi (fw) = %d\n",
2220 le32_to_cpu(cap->number));
2221 ice_debug(hw, ICE_DBG_INIT, "func caps: guar_num_vsi = %d\n",
2222 func_p->guar_num_vsi);
2223}
2224
2225/**
2226 * ice_parse_1588_func_caps - Parse ICE_AQC_CAPS_1588 function caps
2227 * @hw: pointer to the HW struct
2228 * @func_p: pointer to function capabilities structure
2229 * @cap: pointer to the capability element to parse
2230 *
2231 * Extract function capabilities for ICE_AQC_CAPS_1588.
2232 */
2233static void
2234ice_parse_1588_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2235 struct ice_aqc_list_caps_elem *cap)
2236{
2237 struct ice_ts_func_info *info = &func_p->ts_func_info;
2238 u32 number = le32_to_cpu(cap->number);
2239
2240 info->ena = ((number & ICE_TS_FUNC_ENA_M) != 0);
2241 func_p->common_cap.ieee_1588 = info->ena;
2242
2243 info->src_tmr_owned = ((number & ICE_TS_SRC_TMR_OWND_M) != 0);
2244 info->tmr_ena = ((number & ICE_TS_TMR_ENA_M) != 0);
2245 info->tmr_index_owned = ((number & ICE_TS_TMR_IDX_OWND_M) != 0);
2246 info->tmr_index_assoc = ((number & ICE_TS_TMR_IDX_ASSOC_M) != 0);
2247
2248 info->clk_freq = FIELD_GET(ICE_TS_CLK_FREQ_M, number);
2249 info->clk_src = ((number & ICE_TS_CLK_SRC_M) != 0);
2250
2251 if (info->clk_freq < NUM_ICE_TIME_REF_FREQ) {
2252 info->time_ref = (enum ice_time_ref_freq)info->clk_freq;
2253 } else {
2254 /* Unknown clock frequency, so assume a (probably incorrect)
2255 * default to avoid out-of-bounds look ups of frequency
2256 * related information.
2257 */
2258 ice_debug(hw, ICE_DBG_INIT, "1588 func caps: unknown clock frequency %u\n",
2259 info->clk_freq);
2260 info->time_ref = ICE_TIME_REF_FREQ_25_000;
2261 }
2262
2263 ice_debug(hw, ICE_DBG_INIT, "func caps: ieee_1588 = %u\n",
2264 func_p->common_cap.ieee_1588);
2265 ice_debug(hw, ICE_DBG_INIT, "func caps: src_tmr_owned = %u\n",
2266 info->src_tmr_owned);
2267 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_ena = %u\n",
2268 info->tmr_ena);
2269 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_index_owned = %u\n",
2270 info->tmr_index_owned);
2271 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_index_assoc = %u\n",
2272 info->tmr_index_assoc);
2273 ice_debug(hw, ICE_DBG_INIT, "func caps: clk_freq = %u\n",
2274 info->clk_freq);
2275 ice_debug(hw, ICE_DBG_INIT, "func caps: clk_src = %u\n",
2276 info->clk_src);
2277}
2278
2279/**
2280 * ice_parse_fdir_func_caps - Parse ICE_AQC_CAPS_FD function caps
2281 * @hw: pointer to the HW struct
2282 * @func_p: pointer to function capabilities structure
2283 *
2284 * Extract function capabilities for ICE_AQC_CAPS_FD.
2285 */
2286static void
2287ice_parse_fdir_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p)
2288{
2289 u32 reg_val, gsize, bsize;
2290
2291 reg_val = rd32(hw, GLQF_FD_SIZE);
2292 switch (hw->mac_type) {
2293 case ICE_MAC_E830:
2294 gsize = FIELD_GET(E830_GLQF_FD_SIZE_FD_GSIZE_M, reg_val);
2295 bsize = FIELD_GET(E830_GLQF_FD_SIZE_FD_BSIZE_M, reg_val);
2296 break;
2297 case ICE_MAC_E810:
2298 default:
2299 gsize = FIELD_GET(E800_GLQF_FD_SIZE_FD_GSIZE_M, reg_val);
2300 bsize = FIELD_GET(E800_GLQF_FD_SIZE_FD_BSIZE_M, reg_val);
2301 }
2302 func_p->fd_fltr_guar = ice_get_num_per_func(hw, gsize);
2303 func_p->fd_fltr_best_effort = bsize;
2304
2305 ice_debug(hw, ICE_DBG_INIT, "func caps: fd_fltr_guar = %d\n",
2306 func_p->fd_fltr_guar);
2307 ice_debug(hw, ICE_DBG_INIT, "func caps: fd_fltr_best_effort = %d\n",
2308 func_p->fd_fltr_best_effort);
2309}
2310
2311/**
2312 * ice_parse_func_caps - Parse function capabilities
2313 * @hw: pointer to the HW struct
2314 * @func_p: pointer to function capabilities structure
2315 * @buf: buffer containing the function capability records
2316 * @cap_count: the number of capabilities
2317 *
2318 * Helper function to parse function (0x000A) capabilities list. For
2319 * capabilities shared between device and function, this relies on
2320 * ice_parse_common_caps.
2321 *
2322 * Loop through the list of provided capabilities and extract the relevant
2323 * data into the function capabilities structured.
2324 */
2325static void
2326ice_parse_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2327 void *buf, u32 cap_count)
2328{
2329 struct ice_aqc_list_caps_elem *cap_resp;
2330 u32 i;
2331
2332 cap_resp = buf;
2333
2334 memset(func_p, 0, sizeof(*func_p));
2335
2336 for (i = 0; i < cap_count; i++) {
2337 u16 cap = le16_to_cpu(cap_resp[i].cap);
2338 bool found;
2339
2340 found = ice_parse_common_caps(hw, &func_p->common_cap,
2341 &cap_resp[i], "func caps");
2342
2343 switch (cap) {
2344 case ICE_AQC_CAPS_VF:
2345 ice_parse_vf_func_caps(hw, func_p, &cap_resp[i]);
2346 break;
2347 case ICE_AQC_CAPS_VSI:
2348 ice_parse_vsi_func_caps(hw, func_p, &cap_resp[i]);
2349 break;
2350 case ICE_AQC_CAPS_1588:
2351 ice_parse_1588_func_caps(hw, func_p, &cap_resp[i]);
2352 break;
2353 case ICE_AQC_CAPS_FD:
2354 ice_parse_fdir_func_caps(hw, func_p);
2355 break;
2356 default:
2357 /* Don't list common capabilities as unknown */
2358 if (!found)
2359 ice_debug(hw, ICE_DBG_INIT, "func caps: unknown capability[%d]: 0x%x\n",
2360 i, cap);
2361 break;
2362 }
2363 }
2364
2365 ice_recalc_port_limited_caps(hw, &func_p->common_cap);
2366}
2367
2368/**
2369 * ice_parse_valid_functions_cap - Parse ICE_AQC_CAPS_VALID_FUNCTIONS caps
2370 * @hw: pointer to the HW struct
2371 * @dev_p: pointer to device capabilities structure
2372 * @cap: capability element to parse
2373 *
2374 * Parse ICE_AQC_CAPS_VALID_FUNCTIONS for device capabilities.
2375 */
2376static void
2377ice_parse_valid_functions_cap(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2378 struct ice_aqc_list_caps_elem *cap)
2379{
2380 u32 number = le32_to_cpu(cap->number);
2381
2382 dev_p->num_funcs = hweight32(number);
2383 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_funcs = %d\n",
2384 dev_p->num_funcs);
2385}
2386
2387/**
2388 * ice_parse_vf_dev_caps - Parse ICE_AQC_CAPS_VF device caps
2389 * @hw: pointer to the HW struct
2390 * @dev_p: pointer to device capabilities structure
2391 * @cap: capability element to parse
2392 *
2393 * Parse ICE_AQC_CAPS_VF for device capabilities.
2394 */
2395static void
2396ice_parse_vf_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2397 struct ice_aqc_list_caps_elem *cap)
2398{
2399 u32 number = le32_to_cpu(cap->number);
2400
2401 dev_p->num_vfs_exposed = number;
2402 ice_debug(hw, ICE_DBG_INIT, "dev_caps: num_vfs_exposed = %d\n",
2403 dev_p->num_vfs_exposed);
2404}
2405
2406/**
2407 * ice_parse_vsi_dev_caps - Parse ICE_AQC_CAPS_VSI device caps
2408 * @hw: pointer to the HW struct
2409 * @dev_p: pointer to device capabilities structure
2410 * @cap: capability element to parse
2411 *
2412 * Parse ICE_AQC_CAPS_VSI for device capabilities.
2413 */
2414static void
2415ice_parse_vsi_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2416 struct ice_aqc_list_caps_elem *cap)
2417{
2418 u32 number = le32_to_cpu(cap->number);
2419
2420 dev_p->num_vsi_allocd_to_host = number;
2421 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_vsi_allocd_to_host = %d\n",
2422 dev_p->num_vsi_allocd_to_host);
2423}
2424
2425/**
2426 * ice_parse_1588_dev_caps - Parse ICE_AQC_CAPS_1588 device caps
2427 * @hw: pointer to the HW struct
2428 * @dev_p: pointer to device capabilities structure
2429 * @cap: capability element to parse
2430 *
2431 * Parse ICE_AQC_CAPS_1588 for device capabilities.
2432 */
2433static void
2434ice_parse_1588_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2435 struct ice_aqc_list_caps_elem *cap)
2436{
2437 struct ice_ts_dev_info *info = &dev_p->ts_dev_info;
2438 u32 logical_id = le32_to_cpu(cap->logical_id);
2439 u32 phys_id = le32_to_cpu(cap->phys_id);
2440 u32 number = le32_to_cpu(cap->number);
2441
2442 info->ena = ((number & ICE_TS_DEV_ENA_M) != 0);
2443 dev_p->common_cap.ieee_1588 = info->ena;
2444
2445 info->tmr0_owner = number & ICE_TS_TMR0_OWNR_M;
2446 info->tmr0_owned = ((number & ICE_TS_TMR0_OWND_M) != 0);
2447 info->tmr0_ena = ((number & ICE_TS_TMR0_ENA_M) != 0);
2448
2449 info->tmr1_owner = FIELD_GET(ICE_TS_TMR1_OWNR_M, number);
2450 info->tmr1_owned = ((number & ICE_TS_TMR1_OWND_M) != 0);
2451 info->tmr1_ena = ((number & ICE_TS_TMR1_ENA_M) != 0);
2452
2453 info->ts_ll_read = ((number & ICE_TS_LL_TX_TS_READ_M) != 0);
2454 info->ts_ll_int_read = ((number & ICE_TS_LL_TX_TS_INT_READ_M) != 0);
2455
2456 info->ena_ports = logical_id;
2457 info->tmr_own_map = phys_id;
2458
2459 ice_debug(hw, ICE_DBG_INIT, "dev caps: ieee_1588 = %u\n",
2460 dev_p->common_cap.ieee_1588);
2461 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_owner = %u\n",
2462 info->tmr0_owner);
2463 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_owned = %u\n",
2464 info->tmr0_owned);
2465 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_ena = %u\n",
2466 info->tmr0_ena);
2467 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_owner = %u\n",
2468 info->tmr1_owner);
2469 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_owned = %u\n",
2470 info->tmr1_owned);
2471 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_ena = %u\n",
2472 info->tmr1_ena);
2473 ice_debug(hw, ICE_DBG_INIT, "dev caps: ts_ll_read = %u\n",
2474 info->ts_ll_read);
2475 ice_debug(hw, ICE_DBG_INIT, "dev caps: ts_ll_int_read = %u\n",
2476 info->ts_ll_int_read);
2477 ice_debug(hw, ICE_DBG_INIT, "dev caps: ieee_1588 ena_ports = %u\n",
2478 info->ena_ports);
2479 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr_own_map = %u\n",
2480 info->tmr_own_map);
2481}
2482
2483/**
2484 * ice_parse_fdir_dev_caps - Parse ICE_AQC_CAPS_FD device caps
2485 * @hw: pointer to the HW struct
2486 * @dev_p: pointer to device capabilities structure
2487 * @cap: capability element to parse
2488 *
2489 * Parse ICE_AQC_CAPS_FD for device capabilities.
2490 */
2491static void
2492ice_parse_fdir_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2493 struct ice_aqc_list_caps_elem *cap)
2494{
2495 u32 number = le32_to_cpu(cap->number);
2496
2497 dev_p->num_flow_director_fltr = number;
2498 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_flow_director_fltr = %d\n",
2499 dev_p->num_flow_director_fltr);
2500}
2501
2502/**
2503 * ice_parse_sensor_reading_cap - Parse ICE_AQC_CAPS_SENSOR_READING cap
2504 * @hw: pointer to the HW struct
2505 * @dev_p: pointer to device capabilities structure
2506 * @cap: capability element to parse
2507 *
2508 * Parse ICE_AQC_CAPS_SENSOR_READING for device capability for reading
2509 * enabled sensors.
2510 */
2511static void
2512ice_parse_sensor_reading_cap(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2513 struct ice_aqc_list_caps_elem *cap)
2514{
2515 dev_p->supported_sensors = le32_to_cpu(cap->number);
2516
2517 ice_debug(hw, ICE_DBG_INIT,
2518 "dev caps: supported sensors (bitmap) = 0x%x\n",
2519 dev_p->supported_sensors);
2520}
2521
2522/**
2523 * ice_parse_dev_caps - Parse device capabilities
2524 * @hw: pointer to the HW struct
2525 * @dev_p: pointer to device capabilities structure
2526 * @buf: buffer containing the device capability records
2527 * @cap_count: the number of capabilities
2528 *
2529 * Helper device to parse device (0x000B) capabilities list. For
2530 * capabilities shared between device and function, this relies on
2531 * ice_parse_common_caps.
2532 *
2533 * Loop through the list of provided capabilities and extract the relevant
2534 * data into the device capabilities structured.
2535 */
2536static void
2537ice_parse_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2538 void *buf, u32 cap_count)
2539{
2540 struct ice_aqc_list_caps_elem *cap_resp;
2541 u32 i;
2542
2543 cap_resp = buf;
2544
2545 memset(dev_p, 0, sizeof(*dev_p));
2546
2547 for (i = 0; i < cap_count; i++) {
2548 u16 cap = le16_to_cpu(cap_resp[i].cap);
2549 bool found;
2550
2551 found = ice_parse_common_caps(hw, &dev_p->common_cap,
2552 &cap_resp[i], "dev caps");
2553
2554 switch (cap) {
2555 case ICE_AQC_CAPS_VALID_FUNCTIONS:
2556 ice_parse_valid_functions_cap(hw, dev_p, &cap_resp[i]);
2557 break;
2558 case ICE_AQC_CAPS_VF:
2559 ice_parse_vf_dev_caps(hw, dev_p, &cap_resp[i]);
2560 break;
2561 case ICE_AQC_CAPS_VSI:
2562 ice_parse_vsi_dev_caps(hw, dev_p, &cap_resp[i]);
2563 break;
2564 case ICE_AQC_CAPS_1588:
2565 ice_parse_1588_dev_caps(hw, dev_p, &cap_resp[i]);
2566 break;
2567 case ICE_AQC_CAPS_FD:
2568 ice_parse_fdir_dev_caps(hw, dev_p, &cap_resp[i]);
2569 break;
2570 case ICE_AQC_CAPS_SENSOR_READING:
2571 ice_parse_sensor_reading_cap(hw, dev_p, &cap_resp[i]);
2572 break;
2573 default:
2574 /* Don't list common capabilities as unknown */
2575 if (!found)
2576 ice_debug(hw, ICE_DBG_INIT, "dev caps: unknown capability[%d]: 0x%x\n",
2577 i, cap);
2578 break;
2579 }
2580 }
2581
2582 ice_recalc_port_limited_caps(hw, &dev_p->common_cap);
2583}
2584
2585/**
2586 * ice_is_pf_c827 - check if pf contains c827 phy
2587 * @hw: pointer to the hw struct
2588 */
2589bool ice_is_pf_c827(struct ice_hw *hw)
2590{
2591 struct ice_aqc_get_link_topo cmd = {};
2592 u8 node_part_number;
2593 u16 node_handle;
2594 int status;
2595
2596 if (hw->mac_type != ICE_MAC_E810)
2597 return false;
2598
2599 if (hw->device_id != ICE_DEV_ID_E810C_QSFP)
2600 return true;
2601
2602 cmd.addr.topo_params.node_type_ctx =
2603 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_TYPE_M, ICE_AQC_LINK_TOPO_NODE_TYPE_PHY) |
2604 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_CTX_M, ICE_AQC_LINK_TOPO_NODE_CTX_PORT);
2605 cmd.addr.topo_params.index = 0;
2606
2607 status = ice_aq_get_netlist_node(hw, &cmd, &node_part_number,
2608 &node_handle);
2609
2610 if (status || node_part_number != ICE_AQC_GET_LINK_TOPO_NODE_NR_C827)
2611 return false;
2612
2613 if (node_handle == E810C_QSFP_C827_0_HANDLE || node_handle == E810C_QSFP_C827_1_HANDLE)
2614 return true;
2615
2616 return false;
2617}
2618
2619/**
2620 * ice_is_phy_rclk_in_netlist
2621 * @hw: pointer to the hw struct
2622 *
2623 * Check if the PHY Recovered Clock device is present in the netlist
2624 */
2625bool ice_is_phy_rclk_in_netlist(struct ice_hw *hw)
2626{
2627 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2628 ICE_AQC_GET_LINK_TOPO_NODE_NR_C827, NULL) &&
2629 ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2630 ICE_AQC_GET_LINK_TOPO_NODE_NR_E822_PHY, NULL))
2631 return false;
2632
2633 return true;
2634}
2635
2636/**
2637 * ice_is_clock_mux_in_netlist
2638 * @hw: pointer to the hw struct
2639 *
2640 * Check if the Clock Multiplexer device is present in the netlist
2641 */
2642bool ice_is_clock_mux_in_netlist(struct ice_hw *hw)
2643{
2644 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_MUX,
2645 ICE_AQC_GET_LINK_TOPO_NODE_NR_GEN_CLK_MUX,
2646 NULL))
2647 return false;
2648
2649 return true;
2650}
2651
2652/**
2653 * ice_is_cgu_in_netlist - check for CGU presence
2654 * @hw: pointer to the hw struct
2655 *
2656 * Check if the Clock Generation Unit (CGU) device is present in the netlist.
2657 * Save the CGU part number in the hw structure for later use.
2658 * Return:
2659 * * true - cgu is present
2660 * * false - cgu is not present
2661 */
2662bool ice_is_cgu_in_netlist(struct ice_hw *hw)
2663{
2664 if (!ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2665 ICE_AQC_GET_LINK_TOPO_NODE_NR_ZL30632_80032,
2666 NULL)) {
2667 hw->cgu_part_number = ICE_AQC_GET_LINK_TOPO_NODE_NR_ZL30632_80032;
2668 return true;
2669 } else if (!ice_find_netlist_node(hw,
2670 ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2671 ICE_AQC_GET_LINK_TOPO_NODE_NR_SI5383_5384,
2672 NULL)) {
2673 hw->cgu_part_number = ICE_AQC_GET_LINK_TOPO_NODE_NR_SI5383_5384;
2674 return true;
2675 }
2676
2677 return false;
2678}
2679
2680/**
2681 * ice_is_gps_in_netlist
2682 * @hw: pointer to the hw struct
2683 *
2684 * Check if the GPS generic device is present in the netlist
2685 */
2686bool ice_is_gps_in_netlist(struct ice_hw *hw)
2687{
2688 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_GPS,
2689 ICE_AQC_GET_LINK_TOPO_NODE_NR_GEN_GPS, NULL))
2690 return false;
2691
2692 return true;
2693}
2694
2695/**
2696 * ice_aq_list_caps - query function/device capabilities
2697 * @hw: pointer to the HW struct
2698 * @buf: a buffer to hold the capabilities
2699 * @buf_size: size of the buffer
2700 * @cap_count: if not NULL, set to the number of capabilities reported
2701 * @opc: capabilities type to discover, device or function
2702 * @cd: pointer to command details structure or NULL
2703 *
2704 * Get the function (0x000A) or device (0x000B) capabilities description from
2705 * firmware and store it in the buffer.
2706 *
2707 * If the cap_count pointer is not NULL, then it is set to the number of
2708 * capabilities firmware will report. Note that if the buffer size is too
2709 * small, it is possible the command will return ICE_AQ_ERR_ENOMEM. The
2710 * cap_count will still be updated in this case. It is recommended that the
2711 * buffer size be set to ICE_AQ_MAX_BUF_LEN (the largest possible buffer that
2712 * firmware could return) to avoid this.
2713 */
2714int
2715ice_aq_list_caps(struct ice_hw *hw, void *buf, u16 buf_size, u32 *cap_count,
2716 enum ice_adminq_opc opc, struct ice_sq_cd *cd)
2717{
2718 struct ice_aqc_list_caps *cmd;
2719 struct ice_aq_desc desc;
2720 int status;
2721
2722 cmd = &desc.params.get_cap;
2723
2724 if (opc != ice_aqc_opc_list_func_caps &&
2725 opc != ice_aqc_opc_list_dev_caps)
2726 return -EINVAL;
2727
2728 ice_fill_dflt_direct_cmd_desc(&desc, opc);
2729 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
2730
2731 if (cap_count)
2732 *cap_count = le32_to_cpu(cmd->count);
2733
2734 return status;
2735}
2736
2737/**
2738 * ice_discover_dev_caps - Read and extract device capabilities
2739 * @hw: pointer to the hardware structure
2740 * @dev_caps: pointer to device capabilities structure
2741 *
2742 * Read the device capabilities and extract them into the dev_caps structure
2743 * for later use.
2744 */
2745int
2746ice_discover_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_caps)
2747{
2748 u32 cap_count = 0;
2749 void *cbuf;
2750 int status;
2751
2752 cbuf = kzalloc(ICE_AQ_MAX_BUF_LEN, GFP_KERNEL);
2753 if (!cbuf)
2754 return -ENOMEM;
2755
2756 /* Although the driver doesn't know the number of capabilities the
2757 * device will return, we can simply send a 4KB buffer, the maximum
2758 * possible size that firmware can return.
2759 */
2760 cap_count = ICE_AQ_MAX_BUF_LEN / sizeof(struct ice_aqc_list_caps_elem);
2761
2762 status = ice_aq_list_caps(hw, cbuf, ICE_AQ_MAX_BUF_LEN, &cap_count,
2763 ice_aqc_opc_list_dev_caps, NULL);
2764 if (!status)
2765 ice_parse_dev_caps(hw, dev_caps, cbuf, cap_count);
2766 kfree(cbuf);
2767
2768 return status;
2769}
2770
2771/**
2772 * ice_discover_func_caps - Read and extract function capabilities
2773 * @hw: pointer to the hardware structure
2774 * @func_caps: pointer to function capabilities structure
2775 *
2776 * Read the function capabilities and extract them into the func_caps structure
2777 * for later use.
2778 */
2779static int
2780ice_discover_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_caps)
2781{
2782 u32 cap_count = 0;
2783 void *cbuf;
2784 int status;
2785
2786 cbuf = kzalloc(ICE_AQ_MAX_BUF_LEN, GFP_KERNEL);
2787 if (!cbuf)
2788 return -ENOMEM;
2789
2790 /* Although the driver doesn't know the number of capabilities the
2791 * device will return, we can simply send a 4KB buffer, the maximum
2792 * possible size that firmware can return.
2793 */
2794 cap_count = ICE_AQ_MAX_BUF_LEN / sizeof(struct ice_aqc_list_caps_elem);
2795
2796 status = ice_aq_list_caps(hw, cbuf, ICE_AQ_MAX_BUF_LEN, &cap_count,
2797 ice_aqc_opc_list_func_caps, NULL);
2798 if (!status)
2799 ice_parse_func_caps(hw, func_caps, cbuf, cap_count);
2800 kfree(cbuf);
2801
2802 return status;
2803}
2804
2805/**
2806 * ice_set_safe_mode_caps - Override dev/func capabilities when in safe mode
2807 * @hw: pointer to the hardware structure
2808 */
2809void ice_set_safe_mode_caps(struct ice_hw *hw)
2810{
2811 struct ice_hw_func_caps *func_caps = &hw->func_caps;
2812 struct ice_hw_dev_caps *dev_caps = &hw->dev_caps;
2813 struct ice_hw_common_caps cached_caps;
2814 u32 num_funcs;
2815
2816 /* cache some func_caps values that should be restored after memset */
2817 cached_caps = func_caps->common_cap;
2818
2819 /* unset func capabilities */
2820 memset(func_caps, 0, sizeof(*func_caps));
2821
2822#define ICE_RESTORE_FUNC_CAP(name) \
2823 func_caps->common_cap.name = cached_caps.name
2824
2825 /* restore cached values */
2826 ICE_RESTORE_FUNC_CAP(valid_functions);
2827 ICE_RESTORE_FUNC_CAP(txq_first_id);
2828 ICE_RESTORE_FUNC_CAP(rxq_first_id);
2829 ICE_RESTORE_FUNC_CAP(msix_vector_first_id);
2830 ICE_RESTORE_FUNC_CAP(max_mtu);
2831 ICE_RESTORE_FUNC_CAP(nvm_unified_update);
2832 ICE_RESTORE_FUNC_CAP(nvm_update_pending_nvm);
2833 ICE_RESTORE_FUNC_CAP(nvm_update_pending_orom);
2834 ICE_RESTORE_FUNC_CAP(nvm_update_pending_netlist);
2835
2836 /* one Tx and one Rx queue in safe mode */
2837 func_caps->common_cap.num_rxq = 1;
2838 func_caps->common_cap.num_txq = 1;
2839
2840 /* two MSIX vectors, one for traffic and one for misc causes */
2841 func_caps->common_cap.num_msix_vectors = 2;
2842 func_caps->guar_num_vsi = 1;
2843
2844 /* cache some dev_caps values that should be restored after memset */
2845 cached_caps = dev_caps->common_cap;
2846 num_funcs = dev_caps->num_funcs;
2847
2848 /* unset dev capabilities */
2849 memset(dev_caps, 0, sizeof(*dev_caps));
2850
2851#define ICE_RESTORE_DEV_CAP(name) \
2852 dev_caps->common_cap.name = cached_caps.name
2853
2854 /* restore cached values */
2855 ICE_RESTORE_DEV_CAP(valid_functions);
2856 ICE_RESTORE_DEV_CAP(txq_first_id);
2857 ICE_RESTORE_DEV_CAP(rxq_first_id);
2858 ICE_RESTORE_DEV_CAP(msix_vector_first_id);
2859 ICE_RESTORE_DEV_CAP(max_mtu);
2860 ICE_RESTORE_DEV_CAP(nvm_unified_update);
2861 ICE_RESTORE_DEV_CAP(nvm_update_pending_nvm);
2862 ICE_RESTORE_DEV_CAP(nvm_update_pending_orom);
2863 ICE_RESTORE_DEV_CAP(nvm_update_pending_netlist);
2864 dev_caps->num_funcs = num_funcs;
2865
2866 /* one Tx and one Rx queue per function in safe mode */
2867 dev_caps->common_cap.num_rxq = num_funcs;
2868 dev_caps->common_cap.num_txq = num_funcs;
2869
2870 /* two MSIX vectors per function */
2871 dev_caps->common_cap.num_msix_vectors = 2 * num_funcs;
2872}
2873
2874/**
2875 * ice_get_caps - get info about the HW
2876 * @hw: pointer to the hardware structure
2877 */
2878int ice_get_caps(struct ice_hw *hw)
2879{
2880 int status;
2881
2882 status = ice_discover_dev_caps(hw, &hw->dev_caps);
2883 if (status)
2884 return status;
2885
2886 return ice_discover_func_caps(hw, &hw->func_caps);
2887}
2888
2889/**
2890 * ice_aq_manage_mac_write - manage MAC address write command
2891 * @hw: pointer to the HW struct
2892 * @mac_addr: MAC address to be written as LAA/LAA+WoL/Port address
2893 * @flags: flags to control write behavior
2894 * @cd: pointer to command details structure or NULL
2895 *
2896 * This function is used to write MAC address to the NVM (0x0108).
2897 */
2898int
2899ice_aq_manage_mac_write(struct ice_hw *hw, const u8 *mac_addr, u8 flags,
2900 struct ice_sq_cd *cd)
2901{
2902 struct ice_aqc_manage_mac_write *cmd;
2903 struct ice_aq_desc desc;
2904
2905 cmd = &desc.params.mac_write;
2906 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_manage_mac_write);
2907
2908 cmd->flags = flags;
2909 ether_addr_copy(cmd->mac_addr, mac_addr);
2910
2911 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
2912}
2913
2914/**
2915 * ice_aq_clear_pxe_mode
2916 * @hw: pointer to the HW struct
2917 *
2918 * Tell the firmware that the driver is taking over from PXE (0x0110).
2919 */
2920static int ice_aq_clear_pxe_mode(struct ice_hw *hw)
2921{
2922 struct ice_aq_desc desc;
2923
2924 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_clear_pxe_mode);
2925 desc.params.clear_pxe.rx_cnt = ICE_AQC_CLEAR_PXE_RX_CNT;
2926
2927 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
2928}
2929
2930/**
2931 * ice_clear_pxe_mode - clear pxe operations mode
2932 * @hw: pointer to the HW struct
2933 *
2934 * Make sure all PXE mode settings are cleared, including things
2935 * like descriptor fetch/write-back mode.
2936 */
2937void ice_clear_pxe_mode(struct ice_hw *hw)
2938{
2939 if (ice_check_sq_alive(hw, &hw->adminq))
2940 ice_aq_clear_pxe_mode(hw);
2941}
2942
2943/**
2944 * ice_aq_set_port_params - set physical port parameters.
2945 * @pi: pointer to the port info struct
2946 * @double_vlan: if set double VLAN is enabled
2947 * @cd: pointer to command details structure or NULL
2948 *
2949 * Set Physical port parameters (0x0203)
2950 */
2951int
2952ice_aq_set_port_params(struct ice_port_info *pi, bool double_vlan,
2953 struct ice_sq_cd *cd)
2954
2955{
2956 struct ice_aqc_set_port_params *cmd;
2957 struct ice_hw *hw = pi->hw;
2958 struct ice_aq_desc desc;
2959 u16 cmd_flags = 0;
2960
2961 cmd = &desc.params.set_port_params;
2962
2963 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_params);
2964 if (double_vlan)
2965 cmd_flags |= ICE_AQC_SET_P_PARAMS_DOUBLE_VLAN_ENA;
2966 cmd->cmd_flags = cpu_to_le16(cmd_flags);
2967
2968 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
2969}
2970
2971/**
2972 * ice_is_100m_speed_supported
2973 * @hw: pointer to the HW struct
2974 *
2975 * returns true if 100M speeds are supported by the device,
2976 * false otherwise.
2977 */
2978bool ice_is_100m_speed_supported(struct ice_hw *hw)
2979{
2980 switch (hw->device_id) {
2981 case ICE_DEV_ID_E822C_SGMII:
2982 case ICE_DEV_ID_E822L_SGMII:
2983 case ICE_DEV_ID_E823L_1GBE:
2984 case ICE_DEV_ID_E823C_SGMII:
2985 return true;
2986 default:
2987 return false;
2988 }
2989}
2990
2991/**
2992 * ice_get_link_speed_based_on_phy_type - returns link speed
2993 * @phy_type_low: lower part of phy_type
2994 * @phy_type_high: higher part of phy_type
2995 *
2996 * This helper function will convert an entry in PHY type structure
2997 * [phy_type_low, phy_type_high] to its corresponding link speed.
2998 * Note: In the structure of [phy_type_low, phy_type_high], there should
2999 * be one bit set, as this function will convert one PHY type to its
3000 * speed.
3001 * If no bit gets set, ICE_AQ_LINK_SPEED_UNKNOWN will be returned
3002 * If more than one bit gets set, ICE_AQ_LINK_SPEED_UNKNOWN will be returned
3003 */
3004static u16
3005ice_get_link_speed_based_on_phy_type(u64 phy_type_low, u64 phy_type_high)
3006{
3007 u16 speed_phy_type_high = ICE_AQ_LINK_SPEED_UNKNOWN;
3008 u16 speed_phy_type_low = ICE_AQ_LINK_SPEED_UNKNOWN;
3009
3010 switch (phy_type_low) {
3011 case ICE_PHY_TYPE_LOW_100BASE_TX:
3012 case ICE_PHY_TYPE_LOW_100M_SGMII:
3013 speed_phy_type_low = ICE_AQ_LINK_SPEED_100MB;
3014 break;
3015 case ICE_PHY_TYPE_LOW_1000BASE_T:
3016 case ICE_PHY_TYPE_LOW_1000BASE_SX:
3017 case ICE_PHY_TYPE_LOW_1000BASE_LX:
3018 case ICE_PHY_TYPE_LOW_1000BASE_KX:
3019 case ICE_PHY_TYPE_LOW_1G_SGMII:
3020 speed_phy_type_low = ICE_AQ_LINK_SPEED_1000MB;
3021 break;
3022 case ICE_PHY_TYPE_LOW_2500BASE_T:
3023 case ICE_PHY_TYPE_LOW_2500BASE_X:
3024 case ICE_PHY_TYPE_LOW_2500BASE_KX:
3025 speed_phy_type_low = ICE_AQ_LINK_SPEED_2500MB;
3026 break;
3027 case ICE_PHY_TYPE_LOW_5GBASE_T:
3028 case ICE_PHY_TYPE_LOW_5GBASE_KR:
3029 speed_phy_type_low = ICE_AQ_LINK_SPEED_5GB;
3030 break;
3031 case ICE_PHY_TYPE_LOW_10GBASE_T:
3032 case ICE_PHY_TYPE_LOW_10G_SFI_DA:
3033 case ICE_PHY_TYPE_LOW_10GBASE_SR:
3034 case ICE_PHY_TYPE_LOW_10GBASE_LR:
3035 case ICE_PHY_TYPE_LOW_10GBASE_KR_CR1:
3036 case ICE_PHY_TYPE_LOW_10G_SFI_AOC_ACC:
3037 case ICE_PHY_TYPE_LOW_10G_SFI_C2C:
3038 speed_phy_type_low = ICE_AQ_LINK_SPEED_10GB;
3039 break;
3040 case ICE_PHY_TYPE_LOW_25GBASE_T:
3041 case ICE_PHY_TYPE_LOW_25GBASE_CR:
3042 case ICE_PHY_TYPE_LOW_25GBASE_CR_S:
3043 case ICE_PHY_TYPE_LOW_25GBASE_CR1:
3044 case ICE_PHY_TYPE_LOW_25GBASE_SR:
3045 case ICE_PHY_TYPE_LOW_25GBASE_LR:
3046 case ICE_PHY_TYPE_LOW_25GBASE_KR:
3047 case ICE_PHY_TYPE_LOW_25GBASE_KR_S:
3048 case ICE_PHY_TYPE_LOW_25GBASE_KR1:
3049 case ICE_PHY_TYPE_LOW_25G_AUI_AOC_ACC:
3050 case ICE_PHY_TYPE_LOW_25G_AUI_C2C:
3051 speed_phy_type_low = ICE_AQ_LINK_SPEED_25GB;
3052 break;
3053 case ICE_PHY_TYPE_LOW_40GBASE_CR4:
3054 case ICE_PHY_TYPE_LOW_40GBASE_SR4:
3055 case ICE_PHY_TYPE_LOW_40GBASE_LR4:
3056 case ICE_PHY_TYPE_LOW_40GBASE_KR4:
3057 case ICE_PHY_TYPE_LOW_40G_XLAUI_AOC_ACC:
3058 case ICE_PHY_TYPE_LOW_40G_XLAUI:
3059 speed_phy_type_low = ICE_AQ_LINK_SPEED_40GB;
3060 break;
3061 case ICE_PHY_TYPE_LOW_50GBASE_CR2:
3062 case ICE_PHY_TYPE_LOW_50GBASE_SR2:
3063 case ICE_PHY_TYPE_LOW_50GBASE_LR2:
3064 case ICE_PHY_TYPE_LOW_50GBASE_KR2:
3065 case ICE_PHY_TYPE_LOW_50G_LAUI2_AOC_ACC:
3066 case ICE_PHY_TYPE_LOW_50G_LAUI2:
3067 case ICE_PHY_TYPE_LOW_50G_AUI2_AOC_ACC:
3068 case ICE_PHY_TYPE_LOW_50G_AUI2:
3069 case ICE_PHY_TYPE_LOW_50GBASE_CP:
3070 case ICE_PHY_TYPE_LOW_50GBASE_SR:
3071 case ICE_PHY_TYPE_LOW_50GBASE_FR:
3072 case ICE_PHY_TYPE_LOW_50GBASE_LR:
3073 case ICE_PHY_TYPE_LOW_50GBASE_KR_PAM4:
3074 case ICE_PHY_TYPE_LOW_50G_AUI1_AOC_ACC:
3075 case ICE_PHY_TYPE_LOW_50G_AUI1:
3076 speed_phy_type_low = ICE_AQ_LINK_SPEED_50GB;
3077 break;
3078 case ICE_PHY_TYPE_LOW_100GBASE_CR4:
3079 case ICE_PHY_TYPE_LOW_100GBASE_SR4:
3080 case ICE_PHY_TYPE_LOW_100GBASE_LR4:
3081 case ICE_PHY_TYPE_LOW_100GBASE_KR4:
3082 case ICE_PHY_TYPE_LOW_100G_CAUI4_AOC_ACC:
3083 case ICE_PHY_TYPE_LOW_100G_CAUI4:
3084 case ICE_PHY_TYPE_LOW_100G_AUI4_AOC_ACC:
3085 case ICE_PHY_TYPE_LOW_100G_AUI4:
3086 case ICE_PHY_TYPE_LOW_100GBASE_CR_PAM4:
3087 case ICE_PHY_TYPE_LOW_100GBASE_KR_PAM4:
3088 case ICE_PHY_TYPE_LOW_100GBASE_CP2:
3089 case ICE_PHY_TYPE_LOW_100GBASE_SR2:
3090 case ICE_PHY_TYPE_LOW_100GBASE_DR:
3091 speed_phy_type_low = ICE_AQ_LINK_SPEED_100GB;
3092 break;
3093 default:
3094 speed_phy_type_low = ICE_AQ_LINK_SPEED_UNKNOWN;
3095 break;
3096 }
3097
3098 switch (phy_type_high) {
3099 case ICE_PHY_TYPE_HIGH_100GBASE_KR2_PAM4:
3100 case ICE_PHY_TYPE_HIGH_100G_CAUI2_AOC_ACC:
3101 case ICE_PHY_TYPE_HIGH_100G_CAUI2:
3102 case ICE_PHY_TYPE_HIGH_100G_AUI2_AOC_ACC:
3103 case ICE_PHY_TYPE_HIGH_100G_AUI2:
3104 speed_phy_type_high = ICE_AQ_LINK_SPEED_100GB;
3105 break;
3106 default:
3107 speed_phy_type_high = ICE_AQ_LINK_SPEED_UNKNOWN;
3108 break;
3109 }
3110
3111 if (speed_phy_type_low == ICE_AQ_LINK_SPEED_UNKNOWN &&
3112 speed_phy_type_high == ICE_AQ_LINK_SPEED_UNKNOWN)
3113 return ICE_AQ_LINK_SPEED_UNKNOWN;
3114 else if (speed_phy_type_low != ICE_AQ_LINK_SPEED_UNKNOWN &&
3115 speed_phy_type_high != ICE_AQ_LINK_SPEED_UNKNOWN)
3116 return ICE_AQ_LINK_SPEED_UNKNOWN;
3117 else if (speed_phy_type_low != ICE_AQ_LINK_SPEED_UNKNOWN &&
3118 speed_phy_type_high == ICE_AQ_LINK_SPEED_UNKNOWN)
3119 return speed_phy_type_low;
3120 else
3121 return speed_phy_type_high;
3122}
3123
3124/**
3125 * ice_update_phy_type
3126 * @phy_type_low: pointer to the lower part of phy_type
3127 * @phy_type_high: pointer to the higher part of phy_type
3128 * @link_speeds_bitmap: targeted link speeds bitmap
3129 *
3130 * Note: For the link_speeds_bitmap structure, you can check it at
3131 * [ice_aqc_get_link_status->link_speed]. Caller can pass in
3132 * link_speeds_bitmap include multiple speeds.
3133 *
3134 * Each entry in this [phy_type_low, phy_type_high] structure will
3135 * present a certain link speed. This helper function will turn on bits
3136 * in [phy_type_low, phy_type_high] structure based on the value of
3137 * link_speeds_bitmap input parameter.
3138 */
3139void
3140ice_update_phy_type(u64 *phy_type_low, u64 *phy_type_high,
3141 u16 link_speeds_bitmap)
3142{
3143 u64 pt_high;
3144 u64 pt_low;
3145 int index;
3146 u16 speed;
3147
3148 /* We first check with low part of phy_type */
3149 for (index = 0; index <= ICE_PHY_TYPE_LOW_MAX_INDEX; index++) {
3150 pt_low = BIT_ULL(index);
3151 speed = ice_get_link_speed_based_on_phy_type(pt_low, 0);
3152
3153 if (link_speeds_bitmap & speed)
3154 *phy_type_low |= BIT_ULL(index);
3155 }
3156
3157 /* We then check with high part of phy_type */
3158 for (index = 0; index <= ICE_PHY_TYPE_HIGH_MAX_INDEX; index++) {
3159 pt_high = BIT_ULL(index);
3160 speed = ice_get_link_speed_based_on_phy_type(0, pt_high);
3161
3162 if (link_speeds_bitmap & speed)
3163 *phy_type_high |= BIT_ULL(index);
3164 }
3165}
3166
3167/**
3168 * ice_aq_set_phy_cfg
3169 * @hw: pointer to the HW struct
3170 * @pi: port info structure of the interested logical port
3171 * @cfg: structure with PHY configuration data to be set
3172 * @cd: pointer to command details structure or NULL
3173 *
3174 * Set the various PHY configuration parameters supported on the Port.
3175 * One or more of the Set PHY config parameters may be ignored in an MFP
3176 * mode as the PF may not have the privilege to set some of the PHY Config
3177 * parameters. This status will be indicated by the command response (0x0601).
3178 */
3179int
3180ice_aq_set_phy_cfg(struct ice_hw *hw, struct ice_port_info *pi,
3181 struct ice_aqc_set_phy_cfg_data *cfg, struct ice_sq_cd *cd)
3182{
3183 struct ice_aq_desc desc;
3184 int status;
3185
3186 if (!cfg)
3187 return -EINVAL;
3188
3189 /* Ensure that only valid bits of cfg->caps can be turned on. */
3190 if (cfg->caps & ~ICE_AQ_PHY_ENA_VALID_MASK) {
3191 ice_debug(hw, ICE_DBG_PHY, "Invalid bit is set in ice_aqc_set_phy_cfg_data->caps : 0x%x\n",
3192 cfg->caps);
3193
3194 cfg->caps &= ICE_AQ_PHY_ENA_VALID_MASK;
3195 }
3196
3197 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_phy_cfg);
3198 desc.params.set_phy.lport_num = pi->lport;
3199 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
3200
3201 ice_debug(hw, ICE_DBG_LINK, "set phy cfg\n");
3202 ice_debug(hw, ICE_DBG_LINK, " phy_type_low = 0x%llx\n",
3203 (unsigned long long)le64_to_cpu(cfg->phy_type_low));
3204 ice_debug(hw, ICE_DBG_LINK, " phy_type_high = 0x%llx\n",
3205 (unsigned long long)le64_to_cpu(cfg->phy_type_high));
3206 ice_debug(hw, ICE_DBG_LINK, " caps = 0x%x\n", cfg->caps);
3207 ice_debug(hw, ICE_DBG_LINK, " low_power_ctrl_an = 0x%x\n",
3208 cfg->low_power_ctrl_an);
3209 ice_debug(hw, ICE_DBG_LINK, " eee_cap = 0x%x\n", cfg->eee_cap);
3210 ice_debug(hw, ICE_DBG_LINK, " eeer_value = 0x%x\n", cfg->eeer_value);
3211 ice_debug(hw, ICE_DBG_LINK, " link_fec_opt = 0x%x\n",
3212 cfg->link_fec_opt);
3213
3214 status = ice_aq_send_cmd(hw, &desc, cfg, sizeof(*cfg), cd);
3215 if (hw->adminq.sq_last_status == ICE_AQ_RC_EMODE)
3216 status = 0;
3217
3218 if (!status)
3219 pi->phy.curr_user_phy_cfg = *cfg;
3220
3221 return status;
3222}
3223
3224/**
3225 * ice_update_link_info - update status of the HW network link
3226 * @pi: port info structure of the interested logical port
3227 */
3228int ice_update_link_info(struct ice_port_info *pi)
3229{
3230 struct ice_link_status *li;
3231 int status;
3232
3233 if (!pi)
3234 return -EINVAL;
3235
3236 li = &pi->phy.link_info;
3237
3238 status = ice_aq_get_link_info(pi, true, NULL, NULL);
3239 if (status)
3240 return status;
3241
3242 if (li->link_info & ICE_AQ_MEDIA_AVAILABLE) {
3243 struct ice_aqc_get_phy_caps_data *pcaps;
3244 struct ice_hw *hw;
3245
3246 hw = pi->hw;
3247 pcaps = devm_kzalloc(ice_hw_to_dev(hw), sizeof(*pcaps),
3248 GFP_KERNEL);
3249 if (!pcaps)
3250 return -ENOMEM;
3251
3252 status = ice_aq_get_phy_caps(pi, false, ICE_AQC_REPORT_TOPO_CAP_MEDIA,
3253 pcaps, NULL);
3254
3255 devm_kfree(ice_hw_to_dev(hw), pcaps);
3256 }
3257
3258 return status;
3259}
3260
3261/**
3262 * ice_cache_phy_user_req
3263 * @pi: port information structure
3264 * @cache_data: PHY logging data
3265 * @cache_mode: PHY logging mode
3266 *
3267 * Log the user request on (FC, FEC, SPEED) for later use.
3268 */
3269static void
3270ice_cache_phy_user_req(struct ice_port_info *pi,
3271 struct ice_phy_cache_mode_data cache_data,
3272 enum ice_phy_cache_mode cache_mode)
3273{
3274 if (!pi)
3275 return;
3276
3277 switch (cache_mode) {
3278 case ICE_FC_MODE:
3279 pi->phy.curr_user_fc_req = cache_data.data.curr_user_fc_req;
3280 break;
3281 case ICE_SPEED_MODE:
3282 pi->phy.curr_user_speed_req =
3283 cache_data.data.curr_user_speed_req;
3284 break;
3285 case ICE_FEC_MODE:
3286 pi->phy.curr_user_fec_req = cache_data.data.curr_user_fec_req;
3287 break;
3288 default:
3289 break;
3290 }
3291}
3292
3293/**
3294 * ice_caps_to_fc_mode
3295 * @caps: PHY capabilities
3296 *
3297 * Convert PHY FC capabilities to ice FC mode
3298 */
3299enum ice_fc_mode ice_caps_to_fc_mode(u8 caps)
3300{
3301 if (caps & ICE_AQC_PHY_EN_TX_LINK_PAUSE &&
3302 caps & ICE_AQC_PHY_EN_RX_LINK_PAUSE)
3303 return ICE_FC_FULL;
3304
3305 if (caps & ICE_AQC_PHY_EN_TX_LINK_PAUSE)
3306 return ICE_FC_TX_PAUSE;
3307
3308 if (caps & ICE_AQC_PHY_EN_RX_LINK_PAUSE)
3309 return ICE_FC_RX_PAUSE;
3310
3311 return ICE_FC_NONE;
3312}
3313
3314/**
3315 * ice_caps_to_fec_mode
3316 * @caps: PHY capabilities
3317 * @fec_options: Link FEC options
3318 *
3319 * Convert PHY FEC capabilities to ice FEC mode
3320 */
3321enum ice_fec_mode ice_caps_to_fec_mode(u8 caps, u8 fec_options)
3322{
3323 if (caps & ICE_AQC_PHY_EN_AUTO_FEC)
3324 return ICE_FEC_AUTO;
3325
3326 if (fec_options & (ICE_AQC_PHY_FEC_10G_KR_40G_KR4_EN |
3327 ICE_AQC_PHY_FEC_10G_KR_40G_KR4_REQ |
3328 ICE_AQC_PHY_FEC_25G_KR_CLAUSE74_EN |
3329 ICE_AQC_PHY_FEC_25G_KR_REQ))
3330 return ICE_FEC_BASER;
3331
3332 if (fec_options & (ICE_AQC_PHY_FEC_25G_RS_528_REQ |
3333 ICE_AQC_PHY_FEC_25G_RS_544_REQ |
3334 ICE_AQC_PHY_FEC_25G_RS_CLAUSE91_EN))
3335 return ICE_FEC_RS;
3336
3337 return ICE_FEC_NONE;
3338}
3339
3340/**
3341 * ice_cfg_phy_fc - Configure PHY FC data based on FC mode
3342 * @pi: port information structure
3343 * @cfg: PHY configuration data to set FC mode
3344 * @req_mode: FC mode to configure
3345 */
3346int
3347ice_cfg_phy_fc(struct ice_port_info *pi, struct ice_aqc_set_phy_cfg_data *cfg,
3348 enum ice_fc_mode req_mode)
3349{
3350 struct ice_phy_cache_mode_data cache_data;
3351 u8 pause_mask = 0x0;
3352
3353 if (!pi || !cfg)
3354 return -EINVAL;
3355
3356 switch (req_mode) {
3357 case ICE_FC_FULL:
3358 pause_mask |= ICE_AQC_PHY_EN_TX_LINK_PAUSE;
3359 pause_mask |= ICE_AQC_PHY_EN_RX_LINK_PAUSE;
3360 break;
3361 case ICE_FC_RX_PAUSE:
3362 pause_mask |= ICE_AQC_PHY_EN_RX_LINK_PAUSE;
3363 break;
3364 case ICE_FC_TX_PAUSE:
3365 pause_mask |= ICE_AQC_PHY_EN_TX_LINK_PAUSE;
3366 break;
3367 default:
3368 break;
3369 }
3370
3371 /* clear the old pause settings */
3372 cfg->caps &= ~(ICE_AQC_PHY_EN_TX_LINK_PAUSE |
3373 ICE_AQC_PHY_EN_RX_LINK_PAUSE);
3374
3375 /* set the new capabilities */
3376 cfg->caps |= pause_mask;
3377
3378 /* Cache user FC request */
3379 cache_data.data.curr_user_fc_req = req_mode;
3380 ice_cache_phy_user_req(pi, cache_data, ICE_FC_MODE);
3381
3382 return 0;
3383}
3384
3385/**
3386 * ice_set_fc
3387 * @pi: port information structure
3388 * @aq_failures: pointer to status code, specific to ice_set_fc routine
3389 * @ena_auto_link_update: enable automatic link update
3390 *
3391 * Set the requested flow control mode.
3392 */
3393int
3394ice_set_fc(struct ice_port_info *pi, u8 *aq_failures, bool ena_auto_link_update)
3395{
3396 struct ice_aqc_set_phy_cfg_data cfg = { 0 };
3397 struct ice_aqc_get_phy_caps_data *pcaps;
3398 struct ice_hw *hw;
3399 int status;
3400
3401 if (!pi || !aq_failures)
3402 return -EINVAL;
3403
3404 *aq_failures = 0;
3405 hw = pi->hw;
3406
3407 pcaps = devm_kzalloc(ice_hw_to_dev(hw), sizeof(*pcaps), GFP_KERNEL);
3408 if (!pcaps)
3409 return -ENOMEM;
3410
3411 /* Get the current PHY config */
3412 status = ice_aq_get_phy_caps(pi, false, ICE_AQC_REPORT_ACTIVE_CFG,
3413 pcaps, NULL);
3414 if (status) {
3415 *aq_failures = ICE_SET_FC_AQ_FAIL_GET;
3416 goto out;
3417 }
3418
3419 ice_copy_phy_caps_to_cfg(pi, pcaps, &cfg);
3420
3421 /* Configure the set PHY data */
3422 status = ice_cfg_phy_fc(pi, &cfg, pi->fc.req_mode);
3423 if (status)
3424 goto out;
3425
3426 /* If the capabilities have changed, then set the new config */
3427 if (cfg.caps != pcaps->caps) {
3428 int retry_count, retry_max = 10;
3429
3430 /* Auto restart link so settings take effect */
3431 if (ena_auto_link_update)
3432 cfg.caps |= ICE_AQ_PHY_ENA_AUTO_LINK_UPDT;
3433
3434 status = ice_aq_set_phy_cfg(hw, pi, &cfg, NULL);
3435 if (status) {
3436 *aq_failures = ICE_SET_FC_AQ_FAIL_SET;
3437 goto out;
3438 }
3439
3440 /* Update the link info
3441 * It sometimes takes a really long time for link to
3442 * come back from the atomic reset. Thus, we wait a
3443 * little bit.
3444 */
3445 for (retry_count = 0; retry_count < retry_max; retry_count++) {
3446 status = ice_update_link_info(pi);
3447
3448 if (!status)
3449 break;
3450
3451 mdelay(100);
3452 }
3453
3454 if (status)
3455 *aq_failures = ICE_SET_FC_AQ_FAIL_UPDATE;
3456 }
3457
3458out:
3459 devm_kfree(ice_hw_to_dev(hw), pcaps);
3460 return status;
3461}
3462
3463/**
3464 * ice_phy_caps_equals_cfg
3465 * @phy_caps: PHY capabilities
3466 * @phy_cfg: PHY configuration
3467 *
3468 * Helper function to determine if PHY capabilities matches PHY
3469 * configuration
3470 */
3471bool
3472ice_phy_caps_equals_cfg(struct ice_aqc_get_phy_caps_data *phy_caps,
3473 struct ice_aqc_set_phy_cfg_data *phy_cfg)
3474{
3475 u8 caps_mask, cfg_mask;
3476
3477 if (!phy_caps || !phy_cfg)
3478 return false;
3479
3480 /* These bits are not common between capabilities and configuration.
3481 * Do not use them to determine equality.
3482 */
3483 caps_mask = ICE_AQC_PHY_CAPS_MASK & ~(ICE_AQC_PHY_AN_MODE |
3484 ICE_AQC_GET_PHY_EN_MOD_QUAL);
3485 cfg_mask = ICE_AQ_PHY_ENA_VALID_MASK & ~ICE_AQ_PHY_ENA_AUTO_LINK_UPDT;
3486
3487 if (phy_caps->phy_type_low != phy_cfg->phy_type_low ||
3488 phy_caps->phy_type_high != phy_cfg->phy_type_high ||
3489 ((phy_caps->caps & caps_mask) != (phy_cfg->caps & cfg_mask)) ||
3490 phy_caps->low_power_ctrl_an != phy_cfg->low_power_ctrl_an ||
3491 phy_caps->eee_cap != phy_cfg->eee_cap ||
3492 phy_caps->eeer_value != phy_cfg->eeer_value ||
3493 phy_caps->link_fec_options != phy_cfg->link_fec_opt)
3494 return false;
3495
3496 return true;
3497}
3498
3499/**
3500 * ice_copy_phy_caps_to_cfg - Copy PHY ability data to configuration data
3501 * @pi: port information structure
3502 * @caps: PHY ability structure to copy date from
3503 * @cfg: PHY configuration structure to copy data to
3504 *
3505 * Helper function to copy AQC PHY get ability data to PHY set configuration
3506 * data structure
3507 */
3508void
3509ice_copy_phy_caps_to_cfg(struct ice_port_info *pi,
3510 struct ice_aqc_get_phy_caps_data *caps,
3511 struct ice_aqc_set_phy_cfg_data *cfg)
3512{
3513 if (!pi || !caps || !cfg)
3514 return;
3515
3516 memset(cfg, 0, sizeof(*cfg));
3517 cfg->phy_type_low = caps->phy_type_low;
3518 cfg->phy_type_high = caps->phy_type_high;
3519 cfg->caps = caps->caps;
3520 cfg->low_power_ctrl_an = caps->low_power_ctrl_an;
3521 cfg->eee_cap = caps->eee_cap;
3522 cfg->eeer_value = caps->eeer_value;
3523 cfg->link_fec_opt = caps->link_fec_options;
3524 cfg->module_compliance_enforcement =
3525 caps->module_compliance_enforcement;
3526}
3527
3528/**
3529 * ice_cfg_phy_fec - Configure PHY FEC data based on FEC mode
3530 * @pi: port information structure
3531 * @cfg: PHY configuration data to set FEC mode
3532 * @fec: FEC mode to configure
3533 */
3534int
3535ice_cfg_phy_fec(struct ice_port_info *pi, struct ice_aqc_set_phy_cfg_data *cfg,
3536 enum ice_fec_mode fec)
3537{
3538 struct ice_aqc_get_phy_caps_data *pcaps;
3539 struct ice_hw *hw;
3540 int status;
3541
3542 if (!pi || !cfg)
3543 return -EINVAL;
3544
3545 hw = pi->hw;
3546
3547 pcaps = kzalloc(sizeof(*pcaps), GFP_KERNEL);
3548 if (!pcaps)
3549 return -ENOMEM;
3550
3551 status = ice_aq_get_phy_caps(pi, false,
3552 (ice_fw_supports_report_dflt_cfg(hw) ?
3553 ICE_AQC_REPORT_DFLT_CFG :
3554 ICE_AQC_REPORT_TOPO_CAP_MEDIA), pcaps, NULL);
3555 if (status)
3556 goto out;
3557
3558 cfg->caps |= pcaps->caps & ICE_AQC_PHY_EN_AUTO_FEC;
3559 cfg->link_fec_opt = pcaps->link_fec_options;
3560
3561 switch (fec) {
3562 case ICE_FEC_BASER:
3563 /* Clear RS bits, and AND BASE-R ability
3564 * bits and OR request bits.
3565 */
3566 cfg->link_fec_opt &= ICE_AQC_PHY_FEC_10G_KR_40G_KR4_EN |
3567 ICE_AQC_PHY_FEC_25G_KR_CLAUSE74_EN;
3568 cfg->link_fec_opt |= ICE_AQC_PHY_FEC_10G_KR_40G_KR4_REQ |
3569 ICE_AQC_PHY_FEC_25G_KR_REQ;
3570 break;
3571 case ICE_FEC_RS:
3572 /* Clear BASE-R bits, and AND RS ability
3573 * bits and OR request bits.
3574 */
3575 cfg->link_fec_opt &= ICE_AQC_PHY_FEC_25G_RS_CLAUSE91_EN;
3576 cfg->link_fec_opt |= ICE_AQC_PHY_FEC_25G_RS_528_REQ |
3577 ICE_AQC_PHY_FEC_25G_RS_544_REQ;
3578 break;
3579 case ICE_FEC_NONE:
3580 /* Clear all FEC option bits. */
3581 cfg->link_fec_opt &= ~ICE_AQC_PHY_FEC_MASK;
3582 break;
3583 case ICE_FEC_AUTO:
3584 /* AND auto FEC bit, and all caps bits. */
3585 cfg->caps &= ICE_AQC_PHY_CAPS_MASK;
3586 cfg->link_fec_opt |= pcaps->link_fec_options;
3587 break;
3588 default:
3589 status = -EINVAL;
3590 break;
3591 }
3592
3593 if (fec == ICE_FEC_AUTO && ice_fw_supports_link_override(hw) &&
3594 !ice_fw_supports_report_dflt_cfg(hw)) {
3595 struct ice_link_default_override_tlv tlv = { 0 };
3596
3597 status = ice_get_link_default_override(&tlv, pi);
3598 if (status)
3599 goto out;
3600
3601 if (!(tlv.options & ICE_LINK_OVERRIDE_STRICT_MODE) &&
3602 (tlv.options & ICE_LINK_OVERRIDE_EN))
3603 cfg->link_fec_opt = tlv.fec_options;
3604 }
3605
3606out:
3607 kfree(pcaps);
3608
3609 return status;
3610}
3611
3612/**
3613 * ice_get_link_status - get status of the HW network link
3614 * @pi: port information structure
3615 * @link_up: pointer to bool (true/false = linkup/linkdown)
3616 *
3617 * Variable link_up is true if link is up, false if link is down.
3618 * The variable link_up is invalid if status is non zero. As a
3619 * result of this call, link status reporting becomes enabled
3620 */
3621int ice_get_link_status(struct ice_port_info *pi, bool *link_up)
3622{
3623 struct ice_phy_info *phy_info;
3624 int status = 0;
3625
3626 if (!pi || !link_up)
3627 return -EINVAL;
3628
3629 phy_info = &pi->phy;
3630
3631 if (phy_info->get_link_info) {
3632 status = ice_update_link_info(pi);
3633
3634 if (status)
3635 ice_debug(pi->hw, ICE_DBG_LINK, "get link status error, status = %d\n",
3636 status);
3637 }
3638
3639 *link_up = phy_info->link_info.link_info & ICE_AQ_LINK_UP;
3640
3641 return status;
3642}
3643
3644/**
3645 * ice_aq_set_link_restart_an
3646 * @pi: pointer to the port information structure
3647 * @ena_link: if true: enable link, if false: disable link
3648 * @cd: pointer to command details structure or NULL
3649 *
3650 * Sets up the link and restarts the Auto-Negotiation over the link.
3651 */
3652int
3653ice_aq_set_link_restart_an(struct ice_port_info *pi, bool ena_link,
3654 struct ice_sq_cd *cd)
3655{
3656 struct ice_aqc_restart_an *cmd;
3657 struct ice_aq_desc desc;
3658
3659 cmd = &desc.params.restart_an;
3660
3661 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_restart_an);
3662
3663 cmd->cmd_flags = ICE_AQC_RESTART_AN_LINK_RESTART;
3664 cmd->lport_num = pi->lport;
3665 if (ena_link)
3666 cmd->cmd_flags |= ICE_AQC_RESTART_AN_LINK_ENABLE;
3667 else
3668 cmd->cmd_flags &= ~ICE_AQC_RESTART_AN_LINK_ENABLE;
3669
3670 return ice_aq_send_cmd(pi->hw, &desc, NULL, 0, cd);
3671}
3672
3673/**
3674 * ice_aq_set_event_mask
3675 * @hw: pointer to the HW struct
3676 * @port_num: port number of the physical function
3677 * @mask: event mask to be set
3678 * @cd: pointer to command details structure or NULL
3679 *
3680 * Set event mask (0x0613)
3681 */
3682int
3683ice_aq_set_event_mask(struct ice_hw *hw, u8 port_num, u16 mask,
3684 struct ice_sq_cd *cd)
3685{
3686 struct ice_aqc_set_event_mask *cmd;
3687 struct ice_aq_desc desc;
3688
3689 cmd = &desc.params.set_event_mask;
3690
3691 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_event_mask);
3692
3693 cmd->lport_num = port_num;
3694
3695 cmd->event_mask = cpu_to_le16(mask);
3696 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3697}
3698
3699/**
3700 * ice_aq_set_mac_loopback
3701 * @hw: pointer to the HW struct
3702 * @ena_lpbk: Enable or Disable loopback
3703 * @cd: pointer to command details structure or NULL
3704 *
3705 * Enable/disable loopback on a given port
3706 */
3707int
3708ice_aq_set_mac_loopback(struct ice_hw *hw, bool ena_lpbk, struct ice_sq_cd *cd)
3709{
3710 struct ice_aqc_set_mac_lb *cmd;
3711 struct ice_aq_desc desc;
3712
3713 cmd = &desc.params.set_mac_lb;
3714
3715 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_mac_lb);
3716 if (ena_lpbk)
3717 cmd->lb_mode = ICE_AQ_MAC_LB_EN;
3718
3719 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3720}
3721
3722/**
3723 * ice_aq_set_port_id_led
3724 * @pi: pointer to the port information
3725 * @is_orig_mode: is this LED set to original mode (by the net-list)
3726 * @cd: pointer to command details structure or NULL
3727 *
3728 * Set LED value for the given port (0x06e9)
3729 */
3730int
3731ice_aq_set_port_id_led(struct ice_port_info *pi, bool is_orig_mode,
3732 struct ice_sq_cd *cd)
3733{
3734 struct ice_aqc_set_port_id_led *cmd;
3735 struct ice_hw *hw = pi->hw;
3736 struct ice_aq_desc desc;
3737
3738 cmd = &desc.params.set_port_id_led;
3739
3740 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_id_led);
3741
3742 if (is_orig_mode)
3743 cmd->ident_mode = ICE_AQC_PORT_IDENT_LED_ORIG;
3744 else
3745 cmd->ident_mode = ICE_AQC_PORT_IDENT_LED_BLINK;
3746
3747 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3748}
3749
3750/**
3751 * ice_aq_get_port_options
3752 * @hw: pointer to the HW struct
3753 * @options: buffer for the resultant port options
3754 * @option_count: input - size of the buffer in port options structures,
3755 * output - number of returned port options
3756 * @lport: logical port to call the command with (optional)
3757 * @lport_valid: when false, FW uses port owned by the PF instead of lport,
3758 * when PF owns more than 1 port it must be true
3759 * @active_option_idx: index of active port option in returned buffer
3760 * @active_option_valid: active option in returned buffer is valid
3761 * @pending_option_idx: index of pending port option in returned buffer
3762 * @pending_option_valid: pending option in returned buffer is valid
3763 *
3764 * Calls Get Port Options AQC (0x06ea) and verifies result.
3765 */
3766int
3767ice_aq_get_port_options(struct ice_hw *hw,
3768 struct ice_aqc_get_port_options_elem *options,
3769 u8 *option_count, u8 lport, bool lport_valid,
3770 u8 *active_option_idx, bool *active_option_valid,
3771 u8 *pending_option_idx, bool *pending_option_valid)
3772{
3773 struct ice_aqc_get_port_options *cmd;
3774 struct ice_aq_desc desc;
3775 int status;
3776 u8 i;
3777
3778 /* options buffer shall be able to hold max returned options */
3779 if (*option_count < ICE_AQC_PORT_OPT_COUNT_M)
3780 return -EINVAL;
3781
3782 cmd = &desc.params.get_port_options;
3783 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_port_options);
3784
3785 if (lport_valid)
3786 cmd->lport_num = lport;
3787 cmd->lport_num_valid = lport_valid;
3788
3789 status = ice_aq_send_cmd(hw, &desc, options,
3790 *option_count * sizeof(*options), NULL);
3791 if (status)
3792 return status;
3793
3794 /* verify direct FW response & set output parameters */
3795 *option_count = FIELD_GET(ICE_AQC_PORT_OPT_COUNT_M,
3796 cmd->port_options_count);
3797 ice_debug(hw, ICE_DBG_PHY, "options: %x\n", *option_count);
3798 *active_option_valid = FIELD_GET(ICE_AQC_PORT_OPT_VALID,
3799 cmd->port_options);
3800 if (*active_option_valid) {
3801 *active_option_idx = FIELD_GET(ICE_AQC_PORT_OPT_ACTIVE_M,
3802 cmd->port_options);
3803 if (*active_option_idx > (*option_count - 1))
3804 return -EIO;
3805 ice_debug(hw, ICE_DBG_PHY, "active idx: %x\n",
3806 *active_option_idx);
3807 }
3808
3809 *pending_option_valid = FIELD_GET(ICE_AQC_PENDING_PORT_OPT_VALID,
3810 cmd->pending_port_option_status);
3811 if (*pending_option_valid) {
3812 *pending_option_idx = FIELD_GET(ICE_AQC_PENDING_PORT_OPT_IDX_M,
3813 cmd->pending_port_option_status);
3814 if (*pending_option_idx > (*option_count - 1))
3815 return -EIO;
3816 ice_debug(hw, ICE_DBG_PHY, "pending idx: %x\n",
3817 *pending_option_idx);
3818 }
3819
3820 /* mask output options fields */
3821 for (i = 0; i < *option_count; i++) {
3822 options[i].pmd = FIELD_GET(ICE_AQC_PORT_OPT_PMD_COUNT_M,
3823 options[i].pmd);
3824 options[i].max_lane_speed = FIELD_GET(ICE_AQC_PORT_OPT_MAX_LANE_M,
3825 options[i].max_lane_speed);
3826 ice_debug(hw, ICE_DBG_PHY, "pmds: %x max speed: %x\n",
3827 options[i].pmd, options[i].max_lane_speed);
3828 }
3829
3830 return 0;
3831}
3832
3833/**
3834 * ice_aq_set_port_option
3835 * @hw: pointer to the HW struct
3836 * @lport: logical port to call the command with
3837 * @lport_valid: when false, FW uses port owned by the PF instead of lport,
3838 * when PF owns more than 1 port it must be true
3839 * @new_option: new port option to be written
3840 *
3841 * Calls Set Port Options AQC (0x06eb).
3842 */
3843int
3844ice_aq_set_port_option(struct ice_hw *hw, u8 lport, u8 lport_valid,
3845 u8 new_option)
3846{
3847 struct ice_aqc_set_port_option *cmd;
3848 struct ice_aq_desc desc;
3849
3850 if (new_option > ICE_AQC_PORT_OPT_COUNT_M)
3851 return -EINVAL;
3852
3853 cmd = &desc.params.set_port_option;
3854 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_option);
3855
3856 if (lport_valid)
3857 cmd->lport_num = lport;
3858
3859 cmd->lport_num_valid = lport_valid;
3860 cmd->selected_port_option = new_option;
3861
3862 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
3863}
3864
3865/**
3866 * ice_aq_sff_eeprom
3867 * @hw: pointer to the HW struct
3868 * @lport: bits [7:0] = logical port, bit [8] = logical port valid
3869 * @bus_addr: I2C bus address of the eeprom (typically 0xA0, 0=topo default)
3870 * @mem_addr: I2C offset. lower 8 bits for address, 8 upper bits zero padding.
3871 * @page: QSFP page
3872 * @set_page: set or ignore the page
3873 * @data: pointer to data buffer to be read/written to the I2C device.
3874 * @length: 1-16 for read, 1 for write.
3875 * @write: 0 read, 1 for write.
3876 * @cd: pointer to command details structure or NULL
3877 *
3878 * Read/Write SFF EEPROM (0x06EE)
3879 */
3880int
3881ice_aq_sff_eeprom(struct ice_hw *hw, u16 lport, u8 bus_addr,
3882 u16 mem_addr, u8 page, u8 set_page, u8 *data, u8 length,
3883 bool write, struct ice_sq_cd *cd)
3884{
3885 struct ice_aqc_sff_eeprom *cmd;
3886 struct ice_aq_desc desc;
3887 u16 i2c_bus_addr;
3888 int status;
3889
3890 if (!data || (mem_addr & 0xff00))
3891 return -EINVAL;
3892
3893 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_sff_eeprom);
3894 cmd = &desc.params.read_write_sff_param;
3895 desc.flags = cpu_to_le16(ICE_AQ_FLAG_RD);
3896 cmd->lport_num = (u8)(lport & 0xff);
3897 cmd->lport_num_valid = (u8)((lport >> 8) & 0x01);
3898 i2c_bus_addr = FIELD_PREP(ICE_AQC_SFF_I2CBUS_7BIT_M, bus_addr >> 1) |
3899 FIELD_PREP(ICE_AQC_SFF_SET_EEPROM_PAGE_M, set_page);
3900 if (write)
3901 i2c_bus_addr |= ICE_AQC_SFF_IS_WRITE;
3902 cmd->i2c_bus_addr = cpu_to_le16(i2c_bus_addr);
3903 cmd->i2c_mem_addr = cpu_to_le16(mem_addr & 0xff);
3904 cmd->eeprom_page = le16_encode_bits(page, ICE_AQC_SFF_EEPROM_PAGE_M);
3905
3906 status = ice_aq_send_cmd(hw, &desc, data, length, cd);
3907 return status;
3908}
3909
3910static enum ice_lut_size ice_lut_type_to_size(enum ice_lut_type type)
3911{
3912 switch (type) {
3913 case ICE_LUT_VSI:
3914 return ICE_LUT_VSI_SIZE;
3915 case ICE_LUT_GLOBAL:
3916 return ICE_LUT_GLOBAL_SIZE;
3917 case ICE_LUT_PF:
3918 return ICE_LUT_PF_SIZE;
3919 }
3920 WARN_ONCE(1, "incorrect type passed");
3921 return ICE_LUT_VSI_SIZE;
3922}
3923
3924static enum ice_aqc_lut_flags ice_lut_size_to_flag(enum ice_lut_size size)
3925{
3926 switch (size) {
3927 case ICE_LUT_VSI_SIZE:
3928 return ICE_AQC_LUT_SIZE_SMALL;
3929 case ICE_LUT_GLOBAL_SIZE:
3930 return ICE_AQC_LUT_SIZE_512;
3931 case ICE_LUT_PF_SIZE:
3932 return ICE_AQC_LUT_SIZE_2K;
3933 }
3934 WARN_ONCE(1, "incorrect size passed");
3935 return 0;
3936}
3937
3938/**
3939 * __ice_aq_get_set_rss_lut
3940 * @hw: pointer to the hardware structure
3941 * @params: RSS LUT parameters
3942 * @set: set true to set the table, false to get the table
3943 *
3944 * Internal function to get (0x0B05) or set (0x0B03) RSS look up table
3945 */
3946static int
3947__ice_aq_get_set_rss_lut(struct ice_hw *hw,
3948 struct ice_aq_get_set_rss_lut_params *params, bool set)
3949{
3950 u16 opcode, vsi_id, vsi_handle = params->vsi_handle, glob_lut_idx = 0;
3951 enum ice_lut_type lut_type = params->lut_type;
3952 struct ice_aqc_get_set_rss_lut *desc_params;
3953 enum ice_aqc_lut_flags flags;
3954 enum ice_lut_size lut_size;
3955 struct ice_aq_desc desc;
3956 u8 *lut = params->lut;
3957
3958
3959 if (!lut || !ice_is_vsi_valid(hw, vsi_handle))
3960 return -EINVAL;
3961
3962 lut_size = ice_lut_type_to_size(lut_type);
3963 if (lut_size > params->lut_size)
3964 return -EINVAL;
3965 else if (set && lut_size != params->lut_size)
3966 return -EINVAL;
3967
3968 opcode = set ? ice_aqc_opc_set_rss_lut : ice_aqc_opc_get_rss_lut;
3969 ice_fill_dflt_direct_cmd_desc(&desc, opcode);
3970 if (set)
3971 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
3972
3973 desc_params = &desc.params.get_set_rss_lut;
3974 vsi_id = ice_get_hw_vsi_num(hw, vsi_handle);
3975 desc_params->vsi_id = cpu_to_le16(vsi_id | ICE_AQC_RSS_VSI_VALID);
3976
3977 if (lut_type == ICE_LUT_GLOBAL)
3978 glob_lut_idx = FIELD_PREP(ICE_AQC_LUT_GLOBAL_IDX,
3979 params->global_lut_id);
3980
3981 flags = lut_type | glob_lut_idx | ice_lut_size_to_flag(lut_size);
3982 desc_params->flags = cpu_to_le16(flags);
3983
3984 return ice_aq_send_cmd(hw, &desc, lut, lut_size, NULL);
3985}
3986
3987/**
3988 * ice_aq_get_rss_lut
3989 * @hw: pointer to the hardware structure
3990 * @get_params: RSS LUT parameters used to specify which RSS LUT to get
3991 *
3992 * get the RSS lookup table, PF or VSI type
3993 */
3994int
3995ice_aq_get_rss_lut(struct ice_hw *hw, struct ice_aq_get_set_rss_lut_params *get_params)
3996{
3997 return __ice_aq_get_set_rss_lut(hw, get_params, false);
3998}
3999
4000/**
4001 * ice_aq_set_rss_lut
4002 * @hw: pointer to the hardware structure
4003 * @set_params: RSS LUT parameters used to specify how to set the RSS LUT
4004 *
4005 * set the RSS lookup table, PF or VSI type
4006 */
4007int
4008ice_aq_set_rss_lut(struct ice_hw *hw, struct ice_aq_get_set_rss_lut_params *set_params)
4009{
4010 return __ice_aq_get_set_rss_lut(hw, set_params, true);
4011}
4012
4013/**
4014 * __ice_aq_get_set_rss_key
4015 * @hw: pointer to the HW struct
4016 * @vsi_id: VSI FW index
4017 * @key: pointer to key info struct
4018 * @set: set true to set the key, false to get the key
4019 *
4020 * get (0x0B04) or set (0x0B02) the RSS key per VSI
4021 */
4022static int
4023__ice_aq_get_set_rss_key(struct ice_hw *hw, u16 vsi_id,
4024 struct ice_aqc_get_set_rss_keys *key, bool set)
4025{
4026 struct ice_aqc_get_set_rss_key *desc_params;
4027 u16 key_size = sizeof(*key);
4028 struct ice_aq_desc desc;
4029
4030 if (set) {
4031 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_rss_key);
4032 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4033 } else {
4034 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_rss_key);
4035 }
4036
4037 desc_params = &desc.params.get_set_rss_key;
4038 desc_params->vsi_id = cpu_to_le16(vsi_id | ICE_AQC_RSS_VSI_VALID);
4039
4040 return ice_aq_send_cmd(hw, &desc, key, key_size, NULL);
4041}
4042
4043/**
4044 * ice_aq_get_rss_key
4045 * @hw: pointer to the HW struct
4046 * @vsi_handle: software VSI handle
4047 * @key: pointer to key info struct
4048 *
4049 * get the RSS key per VSI
4050 */
4051int
4052ice_aq_get_rss_key(struct ice_hw *hw, u16 vsi_handle,
4053 struct ice_aqc_get_set_rss_keys *key)
4054{
4055 if (!ice_is_vsi_valid(hw, vsi_handle) || !key)
4056 return -EINVAL;
4057
4058 return __ice_aq_get_set_rss_key(hw, ice_get_hw_vsi_num(hw, vsi_handle),
4059 key, false);
4060}
4061
4062/**
4063 * ice_aq_set_rss_key
4064 * @hw: pointer to the HW struct
4065 * @vsi_handle: software VSI handle
4066 * @keys: pointer to key info struct
4067 *
4068 * set the RSS key per VSI
4069 */
4070int
4071ice_aq_set_rss_key(struct ice_hw *hw, u16 vsi_handle,
4072 struct ice_aqc_get_set_rss_keys *keys)
4073{
4074 if (!ice_is_vsi_valid(hw, vsi_handle) || !keys)
4075 return -EINVAL;
4076
4077 return __ice_aq_get_set_rss_key(hw, ice_get_hw_vsi_num(hw, vsi_handle),
4078 keys, true);
4079}
4080
4081/**
4082 * ice_aq_add_lan_txq
4083 * @hw: pointer to the hardware structure
4084 * @num_qgrps: Number of added queue groups
4085 * @qg_list: list of queue groups to be added
4086 * @buf_size: size of buffer for indirect command
4087 * @cd: pointer to command details structure or NULL
4088 *
4089 * Add Tx LAN queue (0x0C30)
4090 *
4091 * NOTE:
4092 * Prior to calling add Tx LAN queue:
4093 * Initialize the following as part of the Tx queue context:
4094 * Completion queue ID if the queue uses Completion queue, Quanta profile,
4095 * Cache profile and Packet shaper profile.
4096 *
4097 * After add Tx LAN queue AQ command is completed:
4098 * Interrupts should be associated with specific queues,
4099 * Association of Tx queue to Doorbell queue is not part of Add LAN Tx queue
4100 * flow.
4101 */
4102static int
4103ice_aq_add_lan_txq(struct ice_hw *hw, u8 num_qgrps,
4104 struct ice_aqc_add_tx_qgrp *qg_list, u16 buf_size,
4105 struct ice_sq_cd *cd)
4106{
4107 struct ice_aqc_add_tx_qgrp *list;
4108 struct ice_aqc_add_txqs *cmd;
4109 struct ice_aq_desc desc;
4110 u16 i, sum_size = 0;
4111
4112 cmd = &desc.params.add_txqs;
4113
4114 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_add_txqs);
4115
4116 if (!qg_list)
4117 return -EINVAL;
4118
4119 if (num_qgrps > ICE_LAN_TXQ_MAX_QGRPS)
4120 return -EINVAL;
4121
4122 for (i = 0, list = qg_list; i < num_qgrps; i++) {
4123 sum_size += struct_size(list, txqs, list->num_txqs);
4124 list = (struct ice_aqc_add_tx_qgrp *)(list->txqs +
4125 list->num_txqs);
4126 }
4127
4128 if (buf_size != sum_size)
4129 return -EINVAL;
4130
4131 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4132
4133 cmd->num_qgrps = num_qgrps;
4134
4135 return ice_aq_send_cmd(hw, &desc, qg_list, buf_size, cd);
4136}
4137
4138/**
4139 * ice_aq_dis_lan_txq
4140 * @hw: pointer to the hardware structure
4141 * @num_qgrps: number of groups in the list
4142 * @qg_list: the list of groups to disable
4143 * @buf_size: the total size of the qg_list buffer in bytes
4144 * @rst_src: if called due to reset, specifies the reset source
4145 * @vmvf_num: the relative VM or VF number that is undergoing the reset
4146 * @cd: pointer to command details structure or NULL
4147 *
4148 * Disable LAN Tx queue (0x0C31)
4149 */
4150static int
4151ice_aq_dis_lan_txq(struct ice_hw *hw, u8 num_qgrps,
4152 struct ice_aqc_dis_txq_item *qg_list, u16 buf_size,
4153 enum ice_disq_rst_src rst_src, u16 vmvf_num,
4154 struct ice_sq_cd *cd)
4155{
4156 struct ice_aqc_dis_txq_item *item;
4157 struct ice_aqc_dis_txqs *cmd;
4158 struct ice_aq_desc desc;
4159 u16 vmvf_and_timeout;
4160 u16 i, sz = 0;
4161 int status;
4162
4163 cmd = &desc.params.dis_txqs;
4164 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_dis_txqs);
4165
4166 /* qg_list can be NULL only in VM/VF reset flow */
4167 if (!qg_list && !rst_src)
4168 return -EINVAL;
4169
4170 if (num_qgrps > ICE_LAN_TXQ_MAX_QGRPS)
4171 return -EINVAL;
4172
4173 cmd->num_entries = num_qgrps;
4174
4175 vmvf_and_timeout = FIELD_PREP(ICE_AQC_Q_DIS_TIMEOUT_M, 5);
4176
4177 switch (rst_src) {
4178 case ICE_VM_RESET:
4179 cmd->cmd_type = ICE_AQC_Q_DIS_CMD_VM_RESET;
4180 vmvf_and_timeout |= vmvf_num & ICE_AQC_Q_DIS_VMVF_NUM_M;
4181 break;
4182 case ICE_VF_RESET:
4183 cmd->cmd_type = ICE_AQC_Q_DIS_CMD_VF_RESET;
4184 /* In this case, FW expects vmvf_num to be absolute VF ID */
4185 vmvf_and_timeout |= (vmvf_num + hw->func_caps.vf_base_id) &
4186 ICE_AQC_Q_DIS_VMVF_NUM_M;
4187 break;
4188 case ICE_NO_RESET:
4189 default:
4190 break;
4191 }
4192
4193 cmd->vmvf_and_timeout = cpu_to_le16(vmvf_and_timeout);
4194
4195 /* flush pipe on time out */
4196 cmd->cmd_type |= ICE_AQC_Q_DIS_CMD_FLUSH_PIPE;
4197 /* If no queue group info, we are in a reset flow. Issue the AQ */
4198 if (!qg_list)
4199 goto do_aq;
4200
4201 /* set RD bit to indicate that command buffer is provided by the driver
4202 * and it needs to be read by the firmware
4203 */
4204 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4205
4206 for (i = 0, item = qg_list; i < num_qgrps; i++) {
4207 u16 item_size = struct_size(item, q_id, item->num_qs);
4208
4209 /* If the num of queues is even, add 2 bytes of padding */
4210 if ((item->num_qs % 2) == 0)
4211 item_size += 2;
4212
4213 sz += item_size;
4214
4215 item = (struct ice_aqc_dis_txq_item *)((u8 *)item + item_size);
4216 }
4217
4218 if (buf_size != sz)
4219 return -EINVAL;
4220
4221do_aq:
4222 status = ice_aq_send_cmd(hw, &desc, qg_list, buf_size, cd);
4223 if (status) {
4224 if (!qg_list)
4225 ice_debug(hw, ICE_DBG_SCHED, "VM%d disable failed %d\n",
4226 vmvf_num, hw->adminq.sq_last_status);
4227 else
4228 ice_debug(hw, ICE_DBG_SCHED, "disable queue %d failed %d\n",
4229 le16_to_cpu(qg_list[0].q_id[0]),
4230 hw->adminq.sq_last_status);
4231 }
4232 return status;
4233}
4234
4235/**
4236 * ice_aq_cfg_lan_txq
4237 * @hw: pointer to the hardware structure
4238 * @buf: buffer for command
4239 * @buf_size: size of buffer in bytes
4240 * @num_qs: number of queues being configured
4241 * @oldport: origination lport
4242 * @newport: destination lport
4243 * @cd: pointer to command details structure or NULL
4244 *
4245 * Move/Configure LAN Tx queue (0x0C32)
4246 *
4247 * There is a better AQ command to use for moving nodes, so only coding
4248 * this one for configuring the node.
4249 */
4250int
4251ice_aq_cfg_lan_txq(struct ice_hw *hw, struct ice_aqc_cfg_txqs_buf *buf,
4252 u16 buf_size, u16 num_qs, u8 oldport, u8 newport,
4253 struct ice_sq_cd *cd)
4254{
4255 struct ice_aqc_cfg_txqs *cmd;
4256 struct ice_aq_desc desc;
4257 int status;
4258
4259 cmd = &desc.params.cfg_txqs;
4260 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_cfg_txqs);
4261 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4262
4263 if (!buf)
4264 return -EINVAL;
4265
4266 cmd->cmd_type = ICE_AQC_Q_CFG_TC_CHNG;
4267 cmd->num_qs = num_qs;
4268 cmd->port_num_chng = (oldport & ICE_AQC_Q_CFG_SRC_PRT_M);
4269 cmd->port_num_chng |= FIELD_PREP(ICE_AQC_Q_CFG_DST_PRT_M, newport);
4270 cmd->time_out = FIELD_PREP(ICE_AQC_Q_CFG_TIMEOUT_M, 5);
4271 cmd->blocked_cgds = 0;
4272
4273 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
4274 if (status)
4275 ice_debug(hw, ICE_DBG_SCHED, "Failed to reconfigure nodes %d\n",
4276 hw->adminq.sq_last_status);
4277 return status;
4278}
4279
4280/**
4281 * ice_aq_add_rdma_qsets
4282 * @hw: pointer to the hardware structure
4283 * @num_qset_grps: Number of RDMA Qset groups
4284 * @qset_list: list of Qset groups to be added
4285 * @buf_size: size of buffer for indirect command
4286 * @cd: pointer to command details structure or NULL
4287 *
4288 * Add Tx RDMA Qsets (0x0C33)
4289 */
4290static int
4291ice_aq_add_rdma_qsets(struct ice_hw *hw, u8 num_qset_grps,
4292 struct ice_aqc_add_rdma_qset_data *qset_list,
4293 u16 buf_size, struct ice_sq_cd *cd)
4294{
4295 struct ice_aqc_add_rdma_qset_data *list;
4296 struct ice_aqc_add_rdma_qset *cmd;
4297 struct ice_aq_desc desc;
4298 u16 i, sum_size = 0;
4299
4300 cmd = &desc.params.add_rdma_qset;
4301
4302 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_add_rdma_qset);
4303
4304 if (num_qset_grps > ICE_LAN_TXQ_MAX_QGRPS)
4305 return -EINVAL;
4306
4307 for (i = 0, list = qset_list; i < num_qset_grps; i++) {
4308 u16 num_qsets = le16_to_cpu(list->num_qsets);
4309
4310 sum_size += struct_size(list, rdma_qsets, num_qsets);
4311 list = (struct ice_aqc_add_rdma_qset_data *)(list->rdma_qsets +
4312 num_qsets);
4313 }
4314
4315 if (buf_size != sum_size)
4316 return -EINVAL;
4317
4318 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4319
4320 cmd->num_qset_grps = num_qset_grps;
4321
4322 return ice_aq_send_cmd(hw, &desc, qset_list, buf_size, cd);
4323}
4324
4325/* End of FW Admin Queue command wrappers */
4326
4327/**
4328 * ice_write_byte - write a byte to a packed context structure
4329 * @src_ctx: the context structure to read from
4330 * @dest_ctx: the context to be written to
4331 * @ce_info: a description of the struct to be filled
4332 */
4333static void
4334ice_write_byte(u8 *src_ctx, u8 *dest_ctx, const struct ice_ctx_ele *ce_info)
4335{
4336 u8 src_byte, dest_byte, mask;
4337 u8 *from, *dest;
4338 u16 shift_width;
4339
4340 /* copy from the next struct field */
4341 from = src_ctx + ce_info->offset;
4342
4343 /* prepare the bits and mask */
4344 shift_width = ce_info->lsb % 8;
4345 mask = (u8)(BIT(ce_info->width) - 1);
4346
4347 src_byte = *from;
4348 src_byte &= mask;
4349
4350 /* shift to correct alignment */
4351 mask <<= shift_width;
4352 src_byte <<= shift_width;
4353
4354 /* get the current bits from the target bit string */
4355 dest = dest_ctx + (ce_info->lsb / 8);
4356
4357 memcpy(&dest_byte, dest, sizeof(dest_byte));
4358
4359 dest_byte &= ~mask; /* get the bits not changing */
4360 dest_byte |= src_byte; /* add in the new bits */
4361
4362 /* put it all back */
4363 memcpy(dest, &dest_byte, sizeof(dest_byte));
4364}
4365
4366/**
4367 * ice_write_word - write a word to a packed context structure
4368 * @src_ctx: the context structure to read from
4369 * @dest_ctx: the context to be written to
4370 * @ce_info: a description of the struct to be filled
4371 */
4372static void
4373ice_write_word(u8 *src_ctx, u8 *dest_ctx, const struct ice_ctx_ele *ce_info)
4374{
4375 u16 src_word, mask;
4376 __le16 dest_word;
4377 u8 *from, *dest;
4378 u16 shift_width;
4379
4380 /* copy from the next struct field */
4381 from = src_ctx + ce_info->offset;
4382
4383 /* prepare the bits and mask */
4384 shift_width = ce_info->lsb % 8;
4385 mask = BIT(ce_info->width) - 1;
4386
4387 /* don't swizzle the bits until after the mask because the mask bits
4388 * will be in a different bit position on big endian machines
4389 */
4390 src_word = *(u16 *)from;
4391 src_word &= mask;
4392
4393 /* shift to correct alignment */
4394 mask <<= shift_width;
4395 src_word <<= shift_width;
4396
4397 /* get the current bits from the target bit string */
4398 dest = dest_ctx + (ce_info->lsb / 8);
4399
4400 memcpy(&dest_word, dest, sizeof(dest_word));
4401
4402 dest_word &= ~(cpu_to_le16(mask)); /* get the bits not changing */
4403 dest_word |= cpu_to_le16(src_word); /* add in the new bits */
4404
4405 /* put it all back */
4406 memcpy(dest, &dest_word, sizeof(dest_word));
4407}
4408
4409/**
4410 * ice_write_dword - write a dword to a packed context structure
4411 * @src_ctx: the context structure to read from
4412 * @dest_ctx: the context to be written to
4413 * @ce_info: a description of the struct to be filled
4414 */
4415static void
4416ice_write_dword(u8 *src_ctx, u8 *dest_ctx, const struct ice_ctx_ele *ce_info)
4417{
4418 u32 src_dword, mask;
4419 __le32 dest_dword;
4420 u8 *from, *dest;
4421 u16 shift_width;
4422
4423 /* copy from the next struct field */
4424 from = src_ctx + ce_info->offset;
4425
4426 /* prepare the bits and mask */
4427 shift_width = ce_info->lsb % 8;
4428
4429 /* if the field width is exactly 32 on an x86 machine, then the shift
4430 * operation will not work because the SHL instructions count is masked
4431 * to 5 bits so the shift will do nothing
4432 */
4433 if (ce_info->width < 32)
4434 mask = BIT(ce_info->width) - 1;
4435 else
4436 mask = (u32)~0;
4437
4438 /* don't swizzle the bits until after the mask because the mask bits
4439 * will be in a different bit position on big endian machines
4440 */
4441 src_dword = *(u32 *)from;
4442 src_dword &= mask;
4443
4444 /* shift to correct alignment */
4445 mask <<= shift_width;
4446 src_dword <<= shift_width;
4447
4448 /* get the current bits from the target bit string */
4449 dest = dest_ctx + (ce_info->lsb / 8);
4450
4451 memcpy(&dest_dword, dest, sizeof(dest_dword));
4452
4453 dest_dword &= ~(cpu_to_le32(mask)); /* get the bits not changing */
4454 dest_dword |= cpu_to_le32(src_dword); /* add in the new bits */
4455
4456 /* put it all back */
4457 memcpy(dest, &dest_dword, sizeof(dest_dword));
4458}
4459
4460/**
4461 * ice_write_qword - write a qword to a packed context structure
4462 * @src_ctx: the context structure to read from
4463 * @dest_ctx: the context to be written to
4464 * @ce_info: a description of the struct to be filled
4465 */
4466static void
4467ice_write_qword(u8 *src_ctx, u8 *dest_ctx, const struct ice_ctx_ele *ce_info)
4468{
4469 u64 src_qword, mask;
4470 __le64 dest_qword;
4471 u8 *from, *dest;
4472 u16 shift_width;
4473
4474 /* copy from the next struct field */
4475 from = src_ctx + ce_info->offset;
4476
4477 /* prepare the bits and mask */
4478 shift_width = ce_info->lsb % 8;
4479
4480 /* if the field width is exactly 64 on an x86 machine, then the shift
4481 * operation will not work because the SHL instructions count is masked
4482 * to 6 bits so the shift will do nothing
4483 */
4484 if (ce_info->width < 64)
4485 mask = BIT_ULL(ce_info->width) - 1;
4486 else
4487 mask = (u64)~0;
4488
4489 /* don't swizzle the bits until after the mask because the mask bits
4490 * will be in a different bit position on big endian machines
4491 */
4492 src_qword = *(u64 *)from;
4493 src_qword &= mask;
4494
4495 /* shift to correct alignment */
4496 mask <<= shift_width;
4497 src_qword <<= shift_width;
4498
4499 /* get the current bits from the target bit string */
4500 dest = dest_ctx + (ce_info->lsb / 8);
4501
4502 memcpy(&dest_qword, dest, sizeof(dest_qword));
4503
4504 dest_qword &= ~(cpu_to_le64(mask)); /* get the bits not changing */
4505 dest_qword |= cpu_to_le64(src_qword); /* add in the new bits */
4506
4507 /* put it all back */
4508 memcpy(dest, &dest_qword, sizeof(dest_qword));
4509}
4510
4511/**
4512 * ice_set_ctx - set context bits in packed structure
4513 * @hw: pointer to the hardware structure
4514 * @src_ctx: pointer to a generic non-packed context structure
4515 * @dest_ctx: pointer to memory for the packed structure
4516 * @ce_info: a description of the structure to be transformed
4517 */
4518int
4519ice_set_ctx(struct ice_hw *hw, u8 *src_ctx, u8 *dest_ctx,
4520 const struct ice_ctx_ele *ce_info)
4521{
4522 int f;
4523
4524 for (f = 0; ce_info[f].width; f++) {
4525 /* We have to deal with each element of the FW response
4526 * using the correct size so that we are correct regardless
4527 * of the endianness of the machine.
4528 */
4529 if (ce_info[f].width > (ce_info[f].size_of * BITS_PER_BYTE)) {
4530 ice_debug(hw, ICE_DBG_QCTX, "Field %d width of %d bits larger than size of %d byte(s) ... skipping write\n",
4531 f, ce_info[f].width, ce_info[f].size_of);
4532 continue;
4533 }
4534 switch (ce_info[f].size_of) {
4535 case sizeof(u8):
4536 ice_write_byte(src_ctx, dest_ctx, &ce_info[f]);
4537 break;
4538 case sizeof(u16):
4539 ice_write_word(src_ctx, dest_ctx, &ce_info[f]);
4540 break;
4541 case sizeof(u32):
4542 ice_write_dword(src_ctx, dest_ctx, &ce_info[f]);
4543 break;
4544 case sizeof(u64):
4545 ice_write_qword(src_ctx, dest_ctx, &ce_info[f]);
4546 break;
4547 default:
4548 return -EINVAL;
4549 }
4550 }
4551
4552 return 0;
4553}
4554
4555/**
4556 * ice_get_lan_q_ctx - get the LAN queue context for the given VSI and TC
4557 * @hw: pointer to the HW struct
4558 * @vsi_handle: software VSI handle
4559 * @tc: TC number
4560 * @q_handle: software queue handle
4561 */
4562struct ice_q_ctx *
4563ice_get_lan_q_ctx(struct ice_hw *hw, u16 vsi_handle, u8 tc, u16 q_handle)
4564{
4565 struct ice_vsi_ctx *vsi;
4566 struct ice_q_ctx *q_ctx;
4567
4568 vsi = ice_get_vsi_ctx(hw, vsi_handle);
4569 if (!vsi)
4570 return NULL;
4571 if (q_handle >= vsi->num_lan_q_entries[tc])
4572 return NULL;
4573 if (!vsi->lan_q_ctx[tc])
4574 return NULL;
4575 q_ctx = vsi->lan_q_ctx[tc];
4576 return &q_ctx[q_handle];
4577}
4578
4579/**
4580 * ice_ena_vsi_txq
4581 * @pi: port information structure
4582 * @vsi_handle: software VSI handle
4583 * @tc: TC number
4584 * @q_handle: software queue handle
4585 * @num_qgrps: Number of added queue groups
4586 * @buf: list of queue groups to be added
4587 * @buf_size: size of buffer for indirect command
4588 * @cd: pointer to command details structure or NULL
4589 *
4590 * This function adds one LAN queue
4591 */
4592int
4593ice_ena_vsi_txq(struct ice_port_info *pi, u16 vsi_handle, u8 tc, u16 q_handle,
4594 u8 num_qgrps, struct ice_aqc_add_tx_qgrp *buf, u16 buf_size,
4595 struct ice_sq_cd *cd)
4596{
4597 struct ice_aqc_txsched_elem_data node = { 0 };
4598 struct ice_sched_node *parent;
4599 struct ice_q_ctx *q_ctx;
4600 struct ice_hw *hw;
4601 int status;
4602
4603 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4604 return -EIO;
4605
4606 if (num_qgrps > 1 || buf->num_txqs > 1)
4607 return -ENOSPC;
4608
4609 hw = pi->hw;
4610
4611 if (!ice_is_vsi_valid(hw, vsi_handle))
4612 return -EINVAL;
4613
4614 mutex_lock(&pi->sched_lock);
4615
4616 q_ctx = ice_get_lan_q_ctx(hw, vsi_handle, tc, q_handle);
4617 if (!q_ctx) {
4618 ice_debug(hw, ICE_DBG_SCHED, "Enaq: invalid queue handle %d\n",
4619 q_handle);
4620 status = -EINVAL;
4621 goto ena_txq_exit;
4622 }
4623
4624 /* find a parent node */
4625 parent = ice_sched_get_free_qparent(pi, vsi_handle, tc,
4626 ICE_SCHED_NODE_OWNER_LAN);
4627 if (!parent) {
4628 status = -EINVAL;
4629 goto ena_txq_exit;
4630 }
4631
4632 buf->parent_teid = parent->info.node_teid;
4633 node.parent_teid = parent->info.node_teid;
4634 /* Mark that the values in the "generic" section as valid. The default
4635 * value in the "generic" section is zero. This means that :
4636 * - Scheduling mode is Bytes Per Second (BPS), indicated by Bit 0.
4637 * - 0 priority among siblings, indicated by Bit 1-3.
4638 * - WFQ, indicated by Bit 4.
4639 * - 0 Adjustment value is used in PSM credit update flow, indicated by
4640 * Bit 5-6.
4641 * - Bit 7 is reserved.
4642 * Without setting the generic section as valid in valid_sections, the
4643 * Admin queue command will fail with error code ICE_AQ_RC_EINVAL.
4644 */
4645 buf->txqs[0].info.valid_sections =
4646 ICE_AQC_ELEM_VALID_GENERIC | ICE_AQC_ELEM_VALID_CIR |
4647 ICE_AQC_ELEM_VALID_EIR;
4648 buf->txqs[0].info.generic = 0;
4649 buf->txqs[0].info.cir_bw.bw_profile_idx =
4650 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4651 buf->txqs[0].info.cir_bw.bw_alloc =
4652 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4653 buf->txqs[0].info.eir_bw.bw_profile_idx =
4654 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4655 buf->txqs[0].info.eir_bw.bw_alloc =
4656 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4657
4658 /* add the LAN queue */
4659 status = ice_aq_add_lan_txq(hw, num_qgrps, buf, buf_size, cd);
4660 if (status) {
4661 ice_debug(hw, ICE_DBG_SCHED, "enable queue %d failed %d\n",
4662 le16_to_cpu(buf->txqs[0].txq_id),
4663 hw->adminq.sq_last_status);
4664 goto ena_txq_exit;
4665 }
4666
4667 node.node_teid = buf->txqs[0].q_teid;
4668 node.data.elem_type = ICE_AQC_ELEM_TYPE_LEAF;
4669 q_ctx->q_handle = q_handle;
4670 q_ctx->q_teid = le32_to_cpu(node.node_teid);
4671
4672 /* add a leaf node into scheduler tree queue layer */
4673 status = ice_sched_add_node(pi, hw->num_tx_sched_layers - 1, &node, NULL);
4674 if (!status)
4675 status = ice_sched_replay_q_bw(pi, q_ctx);
4676
4677ena_txq_exit:
4678 mutex_unlock(&pi->sched_lock);
4679 return status;
4680}
4681
4682/**
4683 * ice_dis_vsi_txq
4684 * @pi: port information structure
4685 * @vsi_handle: software VSI handle
4686 * @tc: TC number
4687 * @num_queues: number of queues
4688 * @q_handles: pointer to software queue handle array
4689 * @q_ids: pointer to the q_id array
4690 * @q_teids: pointer to queue node teids
4691 * @rst_src: if called due to reset, specifies the reset source
4692 * @vmvf_num: the relative VM or VF number that is undergoing the reset
4693 * @cd: pointer to command details structure or NULL
4694 *
4695 * This function removes queues and their corresponding nodes in SW DB
4696 */
4697int
4698ice_dis_vsi_txq(struct ice_port_info *pi, u16 vsi_handle, u8 tc, u8 num_queues,
4699 u16 *q_handles, u16 *q_ids, u32 *q_teids,
4700 enum ice_disq_rst_src rst_src, u16 vmvf_num,
4701 struct ice_sq_cd *cd)
4702{
4703 DEFINE_FLEX(struct ice_aqc_dis_txq_item, qg_list, q_id, 1);
4704 u16 i, buf_size = __struct_size(qg_list);
4705 struct ice_q_ctx *q_ctx;
4706 int status = -ENOENT;
4707 struct ice_hw *hw;
4708
4709 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4710 return -EIO;
4711
4712 hw = pi->hw;
4713
4714 if (!num_queues) {
4715 /* if queue is disabled already yet the disable queue command
4716 * has to be sent to complete the VF reset, then call
4717 * ice_aq_dis_lan_txq without any queue information
4718 */
4719 if (rst_src)
4720 return ice_aq_dis_lan_txq(hw, 0, NULL, 0, rst_src,
4721 vmvf_num, NULL);
4722 return -EIO;
4723 }
4724
4725 mutex_lock(&pi->sched_lock);
4726
4727 for (i = 0; i < num_queues; i++) {
4728 struct ice_sched_node *node;
4729
4730 node = ice_sched_find_node_by_teid(pi->root, q_teids[i]);
4731 if (!node)
4732 continue;
4733 q_ctx = ice_get_lan_q_ctx(hw, vsi_handle, tc, q_handles[i]);
4734 if (!q_ctx) {
4735 ice_debug(hw, ICE_DBG_SCHED, "invalid queue handle%d\n",
4736 q_handles[i]);
4737 continue;
4738 }
4739 if (q_ctx->q_handle != q_handles[i]) {
4740 ice_debug(hw, ICE_DBG_SCHED, "Err:handles %d %d\n",
4741 q_ctx->q_handle, q_handles[i]);
4742 continue;
4743 }
4744 qg_list->parent_teid = node->info.parent_teid;
4745 qg_list->num_qs = 1;
4746 qg_list->q_id[0] = cpu_to_le16(q_ids[i]);
4747 status = ice_aq_dis_lan_txq(hw, 1, qg_list, buf_size, rst_src,
4748 vmvf_num, cd);
4749
4750 if (status)
4751 break;
4752 ice_free_sched_node(pi, node);
4753 q_ctx->q_handle = ICE_INVAL_Q_HANDLE;
4754 q_ctx->q_teid = ICE_INVAL_TEID;
4755 }
4756 mutex_unlock(&pi->sched_lock);
4757 return status;
4758}
4759
4760/**
4761 * ice_cfg_vsi_qs - configure the new/existing VSI queues
4762 * @pi: port information structure
4763 * @vsi_handle: software VSI handle
4764 * @tc_bitmap: TC bitmap
4765 * @maxqs: max queues array per TC
4766 * @owner: LAN or RDMA
4767 *
4768 * This function adds/updates the VSI queues per TC.
4769 */
4770static int
4771ice_cfg_vsi_qs(struct ice_port_info *pi, u16 vsi_handle, u8 tc_bitmap,
4772 u16 *maxqs, u8 owner)
4773{
4774 int status = 0;
4775 u8 i;
4776
4777 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4778 return -EIO;
4779
4780 if (!ice_is_vsi_valid(pi->hw, vsi_handle))
4781 return -EINVAL;
4782
4783 mutex_lock(&pi->sched_lock);
4784
4785 ice_for_each_traffic_class(i) {
4786 /* configuration is possible only if TC node is present */
4787 if (!ice_sched_get_tc_node(pi, i))
4788 continue;
4789
4790 status = ice_sched_cfg_vsi(pi, vsi_handle, i, maxqs[i], owner,
4791 ice_is_tc_ena(tc_bitmap, i));
4792 if (status)
4793 break;
4794 }
4795
4796 mutex_unlock(&pi->sched_lock);
4797 return status;
4798}
4799
4800/**
4801 * ice_cfg_vsi_lan - configure VSI LAN queues
4802 * @pi: port information structure
4803 * @vsi_handle: software VSI handle
4804 * @tc_bitmap: TC bitmap
4805 * @max_lanqs: max LAN queues array per TC
4806 *
4807 * This function adds/updates the VSI LAN queues per TC.
4808 */
4809int
4810ice_cfg_vsi_lan(struct ice_port_info *pi, u16 vsi_handle, u8 tc_bitmap,
4811 u16 *max_lanqs)
4812{
4813 return ice_cfg_vsi_qs(pi, vsi_handle, tc_bitmap, max_lanqs,
4814 ICE_SCHED_NODE_OWNER_LAN);
4815}
4816
4817/**
4818 * ice_cfg_vsi_rdma - configure the VSI RDMA queues
4819 * @pi: port information structure
4820 * @vsi_handle: software VSI handle
4821 * @tc_bitmap: TC bitmap
4822 * @max_rdmaqs: max RDMA queues array per TC
4823 *
4824 * This function adds/updates the VSI RDMA queues per TC.
4825 */
4826int
4827ice_cfg_vsi_rdma(struct ice_port_info *pi, u16 vsi_handle, u16 tc_bitmap,
4828 u16 *max_rdmaqs)
4829{
4830 return ice_cfg_vsi_qs(pi, vsi_handle, tc_bitmap, max_rdmaqs,
4831 ICE_SCHED_NODE_OWNER_RDMA);
4832}
4833
4834/**
4835 * ice_ena_vsi_rdma_qset
4836 * @pi: port information structure
4837 * @vsi_handle: software VSI handle
4838 * @tc: TC number
4839 * @rdma_qset: pointer to RDMA Qset
4840 * @num_qsets: number of RDMA Qsets
4841 * @qset_teid: pointer to Qset node TEIDs
4842 *
4843 * This function adds RDMA Qset
4844 */
4845int
4846ice_ena_vsi_rdma_qset(struct ice_port_info *pi, u16 vsi_handle, u8 tc,
4847 u16 *rdma_qset, u16 num_qsets, u32 *qset_teid)
4848{
4849 struct ice_aqc_txsched_elem_data node = { 0 };
4850 struct ice_aqc_add_rdma_qset_data *buf;
4851 struct ice_sched_node *parent;
4852 struct ice_hw *hw;
4853 u16 i, buf_size;
4854 int ret;
4855
4856 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4857 return -EIO;
4858 hw = pi->hw;
4859
4860 if (!ice_is_vsi_valid(hw, vsi_handle))
4861 return -EINVAL;
4862
4863 buf_size = struct_size(buf, rdma_qsets, num_qsets);
4864 buf = kzalloc(buf_size, GFP_KERNEL);
4865 if (!buf)
4866 return -ENOMEM;
4867 mutex_lock(&pi->sched_lock);
4868
4869 parent = ice_sched_get_free_qparent(pi, vsi_handle, tc,
4870 ICE_SCHED_NODE_OWNER_RDMA);
4871 if (!parent) {
4872 ret = -EINVAL;
4873 goto rdma_error_exit;
4874 }
4875 buf->parent_teid = parent->info.node_teid;
4876 node.parent_teid = parent->info.node_teid;
4877
4878 buf->num_qsets = cpu_to_le16(num_qsets);
4879 for (i = 0; i < num_qsets; i++) {
4880 buf->rdma_qsets[i].tx_qset_id = cpu_to_le16(rdma_qset[i]);
4881 buf->rdma_qsets[i].info.valid_sections =
4882 ICE_AQC_ELEM_VALID_GENERIC | ICE_AQC_ELEM_VALID_CIR |
4883 ICE_AQC_ELEM_VALID_EIR;
4884 buf->rdma_qsets[i].info.generic = 0;
4885 buf->rdma_qsets[i].info.cir_bw.bw_profile_idx =
4886 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4887 buf->rdma_qsets[i].info.cir_bw.bw_alloc =
4888 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4889 buf->rdma_qsets[i].info.eir_bw.bw_profile_idx =
4890 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4891 buf->rdma_qsets[i].info.eir_bw.bw_alloc =
4892 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4893 }
4894 ret = ice_aq_add_rdma_qsets(hw, 1, buf, buf_size, NULL);
4895 if (ret) {
4896 ice_debug(hw, ICE_DBG_RDMA, "add RDMA qset failed\n");
4897 goto rdma_error_exit;
4898 }
4899 node.data.elem_type = ICE_AQC_ELEM_TYPE_LEAF;
4900 for (i = 0; i < num_qsets; i++) {
4901 node.node_teid = buf->rdma_qsets[i].qset_teid;
4902 ret = ice_sched_add_node(pi, hw->num_tx_sched_layers - 1,
4903 &node, NULL);
4904 if (ret)
4905 break;
4906 qset_teid[i] = le32_to_cpu(node.node_teid);
4907 }
4908rdma_error_exit:
4909 mutex_unlock(&pi->sched_lock);
4910 kfree(buf);
4911 return ret;
4912}
4913
4914/**
4915 * ice_dis_vsi_rdma_qset - free RDMA resources
4916 * @pi: port_info struct
4917 * @count: number of RDMA Qsets to free
4918 * @qset_teid: TEID of Qset node
4919 * @q_id: list of queue IDs being disabled
4920 */
4921int
4922ice_dis_vsi_rdma_qset(struct ice_port_info *pi, u16 count, u32 *qset_teid,
4923 u16 *q_id)
4924{
4925 DEFINE_FLEX(struct ice_aqc_dis_txq_item, qg_list, q_id, 1);
4926 u16 qg_size = __struct_size(qg_list);
4927 struct ice_hw *hw;
4928 int status = 0;
4929 int i;
4930
4931 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4932 return -EIO;
4933
4934 hw = pi->hw;
4935
4936 mutex_lock(&pi->sched_lock);
4937
4938 for (i = 0; i < count; i++) {
4939 struct ice_sched_node *node;
4940
4941 node = ice_sched_find_node_by_teid(pi->root, qset_teid[i]);
4942 if (!node)
4943 continue;
4944
4945 qg_list->parent_teid = node->info.parent_teid;
4946 qg_list->num_qs = 1;
4947 qg_list->q_id[0] =
4948 cpu_to_le16(q_id[i] |
4949 ICE_AQC_Q_DIS_BUF_ELEM_TYPE_RDMA_QSET);
4950
4951 status = ice_aq_dis_lan_txq(hw, 1, qg_list, qg_size,
4952 ICE_NO_RESET, 0, NULL);
4953 if (status)
4954 break;
4955
4956 ice_free_sched_node(pi, node);
4957 }
4958
4959 mutex_unlock(&pi->sched_lock);
4960 return status;
4961}
4962
4963/**
4964 * ice_aq_get_cgu_abilities - get cgu abilities
4965 * @hw: pointer to the HW struct
4966 * @abilities: CGU abilities
4967 *
4968 * Get CGU abilities (0x0C61)
4969 * Return: 0 on success or negative value on failure.
4970 */
4971int
4972ice_aq_get_cgu_abilities(struct ice_hw *hw,
4973 struct ice_aqc_get_cgu_abilities *abilities)
4974{
4975 struct ice_aq_desc desc;
4976
4977 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_abilities);
4978 return ice_aq_send_cmd(hw, &desc, abilities, sizeof(*abilities), NULL);
4979}
4980
4981/**
4982 * ice_aq_set_input_pin_cfg - set input pin config
4983 * @hw: pointer to the HW struct
4984 * @input_idx: Input index
4985 * @flags1: Input flags
4986 * @flags2: Input flags
4987 * @freq: Frequency in Hz
4988 * @phase_delay: Delay in ps
4989 *
4990 * Set CGU input config (0x0C62)
4991 * Return: 0 on success or negative value on failure.
4992 */
4993int
4994ice_aq_set_input_pin_cfg(struct ice_hw *hw, u8 input_idx, u8 flags1, u8 flags2,
4995 u32 freq, s32 phase_delay)
4996{
4997 struct ice_aqc_set_cgu_input_config *cmd;
4998 struct ice_aq_desc desc;
4999
5000 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_input_config);
5001 cmd = &desc.params.set_cgu_input_config;
5002 cmd->input_idx = input_idx;
5003 cmd->flags1 = flags1;
5004 cmd->flags2 = flags2;
5005 cmd->freq = cpu_to_le32(freq);
5006 cmd->phase_delay = cpu_to_le32(phase_delay);
5007
5008 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5009}
5010
5011/**
5012 * ice_aq_get_input_pin_cfg - get input pin config
5013 * @hw: pointer to the HW struct
5014 * @input_idx: Input index
5015 * @status: Pin status
5016 * @type: Pin type
5017 * @flags1: Input flags
5018 * @flags2: Input flags
5019 * @freq: Frequency in Hz
5020 * @phase_delay: Delay in ps
5021 *
5022 * Get CGU input config (0x0C63)
5023 * Return: 0 on success or negative value on failure.
5024 */
5025int
5026ice_aq_get_input_pin_cfg(struct ice_hw *hw, u8 input_idx, u8 *status, u8 *type,
5027 u8 *flags1, u8 *flags2, u32 *freq, s32 *phase_delay)
5028{
5029 struct ice_aqc_get_cgu_input_config *cmd;
5030 struct ice_aq_desc desc;
5031 int ret;
5032
5033 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_input_config);
5034 cmd = &desc.params.get_cgu_input_config;
5035 cmd->input_idx = input_idx;
5036
5037 ret = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5038 if (!ret) {
5039 if (status)
5040 *status = cmd->status;
5041 if (type)
5042 *type = cmd->type;
5043 if (flags1)
5044 *flags1 = cmd->flags1;
5045 if (flags2)
5046 *flags2 = cmd->flags2;
5047 if (freq)
5048 *freq = le32_to_cpu(cmd->freq);
5049 if (phase_delay)
5050 *phase_delay = le32_to_cpu(cmd->phase_delay);
5051 }
5052
5053 return ret;
5054}
5055
5056/**
5057 * ice_aq_set_output_pin_cfg - set output pin config
5058 * @hw: pointer to the HW struct
5059 * @output_idx: Output index
5060 * @flags: Output flags
5061 * @src_sel: Index of DPLL block
5062 * @freq: Output frequency
5063 * @phase_delay: Output phase compensation
5064 *
5065 * Set CGU output config (0x0C64)
5066 * Return: 0 on success or negative value on failure.
5067 */
5068int
5069ice_aq_set_output_pin_cfg(struct ice_hw *hw, u8 output_idx, u8 flags,
5070 u8 src_sel, u32 freq, s32 phase_delay)
5071{
5072 struct ice_aqc_set_cgu_output_config *cmd;
5073 struct ice_aq_desc desc;
5074
5075 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_output_config);
5076 cmd = &desc.params.set_cgu_output_config;
5077 cmd->output_idx = output_idx;
5078 cmd->flags = flags;
5079 cmd->src_sel = src_sel;
5080 cmd->freq = cpu_to_le32(freq);
5081 cmd->phase_delay = cpu_to_le32(phase_delay);
5082
5083 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5084}
5085
5086/**
5087 * ice_aq_get_output_pin_cfg - get output pin config
5088 * @hw: pointer to the HW struct
5089 * @output_idx: Output index
5090 * @flags: Output flags
5091 * @src_sel: Internal DPLL source
5092 * @freq: Output frequency
5093 * @src_freq: Source frequency
5094 *
5095 * Get CGU output config (0x0C65)
5096 * Return: 0 on success or negative value on failure.
5097 */
5098int
5099ice_aq_get_output_pin_cfg(struct ice_hw *hw, u8 output_idx, u8 *flags,
5100 u8 *src_sel, u32 *freq, u32 *src_freq)
5101{
5102 struct ice_aqc_get_cgu_output_config *cmd;
5103 struct ice_aq_desc desc;
5104 int ret;
5105
5106 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_output_config);
5107 cmd = &desc.params.get_cgu_output_config;
5108 cmd->output_idx = output_idx;
5109
5110 ret = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5111 if (!ret) {
5112 if (flags)
5113 *flags = cmd->flags;
5114 if (src_sel)
5115 *src_sel = cmd->src_sel;
5116 if (freq)
5117 *freq = le32_to_cpu(cmd->freq);
5118 if (src_freq)
5119 *src_freq = le32_to_cpu(cmd->src_freq);
5120 }
5121
5122 return ret;
5123}
5124
5125/**
5126 * ice_aq_get_cgu_dpll_status - get dpll status
5127 * @hw: pointer to the HW struct
5128 * @dpll_num: DPLL index
5129 * @ref_state: Reference clock state
5130 * @config: current DPLL config
5131 * @dpll_state: current DPLL state
5132 * @phase_offset: Phase offset in ns
5133 * @eec_mode: EEC_mode
5134 *
5135 * Get CGU DPLL status (0x0C66)
5136 * Return: 0 on success or negative value on failure.
5137 */
5138int
5139ice_aq_get_cgu_dpll_status(struct ice_hw *hw, u8 dpll_num, u8 *ref_state,
5140 u8 *dpll_state, u8 *config, s64 *phase_offset,
5141 u8 *eec_mode)
5142{
5143 struct ice_aqc_get_cgu_dpll_status *cmd;
5144 struct ice_aq_desc desc;
5145 int status;
5146
5147 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_dpll_status);
5148 cmd = &desc.params.get_cgu_dpll_status;
5149 cmd->dpll_num = dpll_num;
5150
5151 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5152 if (!status) {
5153 *ref_state = cmd->ref_state;
5154 *dpll_state = cmd->dpll_state;
5155 *config = cmd->config;
5156 *phase_offset = le32_to_cpu(cmd->phase_offset_h);
5157 *phase_offset <<= 32;
5158 *phase_offset += le32_to_cpu(cmd->phase_offset_l);
5159 *phase_offset = sign_extend64(*phase_offset, 47);
5160 *eec_mode = cmd->eec_mode;
5161 }
5162
5163 return status;
5164}
5165
5166/**
5167 * ice_aq_set_cgu_dpll_config - set dpll config
5168 * @hw: pointer to the HW struct
5169 * @dpll_num: DPLL index
5170 * @ref_state: Reference clock state
5171 * @config: DPLL config
5172 * @eec_mode: EEC mode
5173 *
5174 * Set CGU DPLL config (0x0C67)
5175 * Return: 0 on success or negative value on failure.
5176 */
5177int
5178ice_aq_set_cgu_dpll_config(struct ice_hw *hw, u8 dpll_num, u8 ref_state,
5179 u8 config, u8 eec_mode)
5180{
5181 struct ice_aqc_set_cgu_dpll_config *cmd;
5182 struct ice_aq_desc desc;
5183
5184 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_dpll_config);
5185 cmd = &desc.params.set_cgu_dpll_config;
5186 cmd->dpll_num = dpll_num;
5187 cmd->ref_state = ref_state;
5188 cmd->config = config;
5189 cmd->eec_mode = eec_mode;
5190
5191 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5192}
5193
5194/**
5195 * ice_aq_set_cgu_ref_prio - set input reference priority
5196 * @hw: pointer to the HW struct
5197 * @dpll_num: DPLL index
5198 * @ref_idx: Reference pin index
5199 * @ref_priority: Reference input priority
5200 *
5201 * Set CGU reference priority (0x0C68)
5202 * Return: 0 on success or negative value on failure.
5203 */
5204int
5205ice_aq_set_cgu_ref_prio(struct ice_hw *hw, u8 dpll_num, u8 ref_idx,
5206 u8 ref_priority)
5207{
5208 struct ice_aqc_set_cgu_ref_prio *cmd;
5209 struct ice_aq_desc desc;
5210
5211 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_ref_prio);
5212 cmd = &desc.params.set_cgu_ref_prio;
5213 cmd->dpll_num = dpll_num;
5214 cmd->ref_idx = ref_idx;
5215 cmd->ref_priority = ref_priority;
5216
5217 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5218}
5219
5220/**
5221 * ice_aq_get_cgu_ref_prio - get input reference priority
5222 * @hw: pointer to the HW struct
5223 * @dpll_num: DPLL index
5224 * @ref_idx: Reference pin index
5225 * @ref_prio: Reference input priority
5226 *
5227 * Get CGU reference priority (0x0C69)
5228 * Return: 0 on success or negative value on failure.
5229 */
5230int
5231ice_aq_get_cgu_ref_prio(struct ice_hw *hw, u8 dpll_num, u8 ref_idx,
5232 u8 *ref_prio)
5233{
5234 struct ice_aqc_get_cgu_ref_prio *cmd;
5235 struct ice_aq_desc desc;
5236 int status;
5237
5238 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_ref_prio);
5239 cmd = &desc.params.get_cgu_ref_prio;
5240 cmd->dpll_num = dpll_num;
5241 cmd->ref_idx = ref_idx;
5242
5243 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5244 if (!status)
5245 *ref_prio = cmd->ref_priority;
5246
5247 return status;
5248}
5249
5250/**
5251 * ice_aq_get_cgu_info - get cgu info
5252 * @hw: pointer to the HW struct
5253 * @cgu_id: CGU ID
5254 * @cgu_cfg_ver: CGU config version
5255 * @cgu_fw_ver: CGU firmware version
5256 *
5257 * Get CGU info (0x0C6A)
5258 * Return: 0 on success or negative value on failure.
5259 */
5260int
5261ice_aq_get_cgu_info(struct ice_hw *hw, u32 *cgu_id, u32 *cgu_cfg_ver,
5262 u32 *cgu_fw_ver)
5263{
5264 struct ice_aqc_get_cgu_info *cmd;
5265 struct ice_aq_desc desc;
5266 int status;
5267
5268 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_info);
5269 cmd = &desc.params.get_cgu_info;
5270
5271 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5272 if (!status) {
5273 *cgu_id = le32_to_cpu(cmd->cgu_id);
5274 *cgu_cfg_ver = le32_to_cpu(cmd->cgu_cfg_ver);
5275 *cgu_fw_ver = le32_to_cpu(cmd->cgu_fw_ver);
5276 }
5277
5278 return status;
5279}
5280
5281/**
5282 * ice_aq_set_phy_rec_clk_out - set RCLK phy out
5283 * @hw: pointer to the HW struct
5284 * @phy_output: PHY reference clock output pin
5285 * @enable: GPIO state to be applied
5286 * @freq: PHY output frequency
5287 *
5288 * Set phy recovered clock as reference (0x0630)
5289 * Return: 0 on success or negative value on failure.
5290 */
5291int
5292ice_aq_set_phy_rec_clk_out(struct ice_hw *hw, u8 phy_output, bool enable,
5293 u32 *freq)
5294{
5295 struct ice_aqc_set_phy_rec_clk_out *cmd;
5296 struct ice_aq_desc desc;
5297 int status;
5298
5299 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_phy_rec_clk_out);
5300 cmd = &desc.params.set_phy_rec_clk_out;
5301 cmd->phy_output = phy_output;
5302 cmd->port_num = ICE_AQC_SET_PHY_REC_CLK_OUT_CURR_PORT;
5303 cmd->flags = enable & ICE_AQC_SET_PHY_REC_CLK_OUT_OUT_EN;
5304 cmd->freq = cpu_to_le32(*freq);
5305
5306 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5307 if (!status)
5308 *freq = le32_to_cpu(cmd->freq);
5309
5310 return status;
5311}
5312
5313/**
5314 * ice_aq_get_phy_rec_clk_out - get phy recovered signal info
5315 * @hw: pointer to the HW struct
5316 * @phy_output: PHY reference clock output pin
5317 * @port_num: Port number
5318 * @flags: PHY flags
5319 * @node_handle: PHY output frequency
5320 *
5321 * Get PHY recovered clock output info (0x0631)
5322 * Return: 0 on success or negative value on failure.
5323 */
5324int
5325ice_aq_get_phy_rec_clk_out(struct ice_hw *hw, u8 *phy_output, u8 *port_num,
5326 u8 *flags, u16 *node_handle)
5327{
5328 struct ice_aqc_get_phy_rec_clk_out *cmd;
5329 struct ice_aq_desc desc;
5330 int status;
5331
5332 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_phy_rec_clk_out);
5333 cmd = &desc.params.get_phy_rec_clk_out;
5334 cmd->phy_output = *phy_output;
5335
5336 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5337 if (!status) {
5338 *phy_output = cmd->phy_output;
5339 if (port_num)
5340 *port_num = cmd->port_num;
5341 if (flags)
5342 *flags = cmd->flags;
5343 if (node_handle)
5344 *node_handle = le16_to_cpu(cmd->node_handle);
5345 }
5346
5347 return status;
5348}
5349
5350/**
5351 * ice_aq_get_sensor_reading
5352 * @hw: pointer to the HW struct
5353 * @data: pointer to data to be read from the sensor
5354 *
5355 * Get sensor reading (0x0632)
5356 */
5357int ice_aq_get_sensor_reading(struct ice_hw *hw,
5358 struct ice_aqc_get_sensor_reading_resp *data)
5359{
5360 struct ice_aqc_get_sensor_reading *cmd;
5361 struct ice_aq_desc desc;
5362 int status;
5363
5364 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_sensor_reading);
5365 cmd = &desc.params.get_sensor_reading;
5366#define ICE_INTERNAL_TEMP_SENSOR_FORMAT 0
5367#define ICE_INTERNAL_TEMP_SENSOR 0
5368 cmd->sensor = ICE_INTERNAL_TEMP_SENSOR;
5369 cmd->format = ICE_INTERNAL_TEMP_SENSOR_FORMAT;
5370
5371 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5372 if (!status)
5373 memcpy(data, &desc.params.get_sensor_reading_resp,
5374 sizeof(*data));
5375
5376 return status;
5377}
5378
5379/**
5380 * ice_replay_pre_init - replay pre initialization
5381 * @hw: pointer to the HW struct
5382 *
5383 * Initializes required config data for VSI, FD, ACL, and RSS before replay.
5384 */
5385static int ice_replay_pre_init(struct ice_hw *hw)
5386{
5387 struct ice_switch_info *sw = hw->switch_info;
5388 u8 i;
5389
5390 /* Delete old entries from replay filter list head if there is any */
5391 ice_rm_all_sw_replay_rule_info(hw);
5392 /* In start of replay, move entries into replay_rules list, it
5393 * will allow adding rules entries back to filt_rules list,
5394 * which is operational list.
5395 */
5396 for (i = 0; i < ICE_MAX_NUM_RECIPES; i++)
5397 list_replace_init(&sw->recp_list[i].filt_rules,
5398 &sw->recp_list[i].filt_replay_rules);
5399 ice_sched_replay_agg_vsi_preinit(hw);
5400
5401 return 0;
5402}
5403
5404/**
5405 * ice_replay_vsi - replay VSI configuration
5406 * @hw: pointer to the HW struct
5407 * @vsi_handle: driver VSI handle
5408 *
5409 * Restore all VSI configuration after reset. It is required to call this
5410 * function with main VSI first.
5411 */
5412int ice_replay_vsi(struct ice_hw *hw, u16 vsi_handle)
5413{
5414 int status;
5415
5416 if (!ice_is_vsi_valid(hw, vsi_handle))
5417 return -EINVAL;
5418
5419 /* Replay pre-initialization if there is any */
5420 if (vsi_handle == ICE_MAIN_VSI_HANDLE) {
5421 status = ice_replay_pre_init(hw);
5422 if (status)
5423 return status;
5424 }
5425 /* Replay per VSI all RSS configurations */
5426 status = ice_replay_rss_cfg(hw, vsi_handle);
5427 if (status)
5428 return status;
5429 /* Replay per VSI all filters */
5430 status = ice_replay_vsi_all_fltr(hw, vsi_handle);
5431 if (!status)
5432 status = ice_replay_vsi_agg(hw, vsi_handle);
5433 return status;
5434}
5435
5436/**
5437 * ice_replay_post - post replay configuration cleanup
5438 * @hw: pointer to the HW struct
5439 *
5440 * Post replay cleanup.
5441 */
5442void ice_replay_post(struct ice_hw *hw)
5443{
5444 /* Delete old entries from replay filter list head */
5445 ice_rm_all_sw_replay_rule_info(hw);
5446 ice_sched_replay_agg(hw);
5447}
5448
5449/**
5450 * ice_stat_update40 - read 40 bit stat from the chip and update stat values
5451 * @hw: ptr to the hardware info
5452 * @reg: offset of 64 bit HW register to read from
5453 * @prev_stat_loaded: bool to specify if previous stats are loaded
5454 * @prev_stat: ptr to previous loaded stat value
5455 * @cur_stat: ptr to current stat value
5456 */
5457void
5458ice_stat_update40(struct ice_hw *hw, u32 reg, bool prev_stat_loaded,
5459 u64 *prev_stat, u64 *cur_stat)
5460{
5461 u64 new_data = rd64(hw, reg) & (BIT_ULL(40) - 1);
5462
5463 /* device stats are not reset at PFR, they likely will not be zeroed
5464 * when the driver starts. Thus, save the value from the first read
5465 * without adding to the statistic value so that we report stats which
5466 * count up from zero.
5467 */
5468 if (!prev_stat_loaded) {
5469 *prev_stat = new_data;
5470 return;
5471 }
5472
5473 /* Calculate the difference between the new and old values, and then
5474 * add it to the software stat value.
5475 */
5476 if (new_data >= *prev_stat)
5477 *cur_stat += new_data - *prev_stat;
5478 else
5479 /* to manage the potential roll-over */
5480 *cur_stat += (new_data + BIT_ULL(40)) - *prev_stat;
5481
5482 /* Update the previously stored value to prepare for next read */
5483 *prev_stat = new_data;
5484}
5485
5486/**
5487 * ice_stat_update32 - read 32 bit stat from the chip and update stat values
5488 * @hw: ptr to the hardware info
5489 * @reg: offset of HW register to read from
5490 * @prev_stat_loaded: bool to specify if previous stats are loaded
5491 * @prev_stat: ptr to previous loaded stat value
5492 * @cur_stat: ptr to current stat value
5493 */
5494void
5495ice_stat_update32(struct ice_hw *hw, u32 reg, bool prev_stat_loaded,
5496 u64 *prev_stat, u64 *cur_stat)
5497{
5498 u32 new_data;
5499
5500 new_data = rd32(hw, reg);
5501
5502 /* device stats are not reset at PFR, they likely will not be zeroed
5503 * when the driver starts. Thus, save the value from the first read
5504 * without adding to the statistic value so that we report stats which
5505 * count up from zero.
5506 */
5507 if (!prev_stat_loaded) {
5508 *prev_stat = new_data;
5509 return;
5510 }
5511
5512 /* Calculate the difference between the new and old values, and then
5513 * add it to the software stat value.
5514 */
5515 if (new_data >= *prev_stat)
5516 *cur_stat += new_data - *prev_stat;
5517 else
5518 /* to manage the potential roll-over */
5519 *cur_stat += (new_data + BIT_ULL(32)) - *prev_stat;
5520
5521 /* Update the previously stored value to prepare for next read */
5522 *prev_stat = new_data;
5523}
5524
5525/**
5526 * ice_sched_query_elem - query element information from HW
5527 * @hw: pointer to the HW struct
5528 * @node_teid: node TEID to be queried
5529 * @buf: buffer to element information
5530 *
5531 * This function queries HW element information
5532 */
5533int
5534ice_sched_query_elem(struct ice_hw *hw, u32 node_teid,
5535 struct ice_aqc_txsched_elem_data *buf)
5536{
5537 u16 buf_size, num_elem_ret = 0;
5538 int status;
5539
5540 buf_size = sizeof(*buf);
5541 memset(buf, 0, buf_size);
5542 buf->node_teid = cpu_to_le32(node_teid);
5543 status = ice_aq_query_sched_elems(hw, 1, buf, buf_size, &num_elem_ret,
5544 NULL);
5545 if (status || num_elem_ret != 1)
5546 ice_debug(hw, ICE_DBG_SCHED, "query element failed\n");
5547 return status;
5548}
5549
5550/**
5551 * ice_aq_read_i2c
5552 * @hw: pointer to the hw struct
5553 * @topo_addr: topology address for a device to communicate with
5554 * @bus_addr: 7-bit I2C bus address
5555 * @addr: I2C memory address (I2C offset) with up to 16 bits
5556 * @params: I2C parameters: bit [7] - Repeated start,
5557 * bits [6:5] data offset size,
5558 * bit [4] - I2C address type,
5559 * bits [3:0] - data size to read (0-16 bytes)
5560 * @data: pointer to data (0 to 16 bytes) to be read from the I2C device
5561 * @cd: pointer to command details structure or NULL
5562 *
5563 * Read I2C (0x06E2)
5564 */
5565int
5566ice_aq_read_i2c(struct ice_hw *hw, struct ice_aqc_link_topo_addr topo_addr,
5567 u16 bus_addr, __le16 addr, u8 params, u8 *data,
5568 struct ice_sq_cd *cd)
5569{
5570 struct ice_aq_desc desc = { 0 };
5571 struct ice_aqc_i2c *cmd;
5572 u8 data_size;
5573 int status;
5574
5575 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_read_i2c);
5576 cmd = &desc.params.read_write_i2c;
5577
5578 if (!data)
5579 return -EINVAL;
5580
5581 data_size = FIELD_GET(ICE_AQC_I2C_DATA_SIZE_M, params);
5582
5583 cmd->i2c_bus_addr = cpu_to_le16(bus_addr);
5584 cmd->topo_addr = topo_addr;
5585 cmd->i2c_params = params;
5586 cmd->i2c_addr = addr;
5587
5588 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5589 if (!status) {
5590 struct ice_aqc_read_i2c_resp *resp;
5591 u8 i;
5592
5593 resp = &desc.params.read_i2c_resp;
5594 for (i = 0; i < data_size; i++) {
5595 *data = resp->i2c_data[i];
5596 data++;
5597 }
5598 }
5599
5600 return status;
5601}
5602
5603/**
5604 * ice_aq_write_i2c
5605 * @hw: pointer to the hw struct
5606 * @topo_addr: topology address for a device to communicate with
5607 * @bus_addr: 7-bit I2C bus address
5608 * @addr: I2C memory address (I2C offset) with up to 16 bits
5609 * @params: I2C parameters: bit [4] - I2C address type, bits [3:0] - data size to write (0-7 bytes)
5610 * @data: pointer to data (0 to 4 bytes) to be written to the I2C device
5611 * @cd: pointer to command details structure or NULL
5612 *
5613 * Write I2C (0x06E3)
5614 *
5615 * * Return:
5616 * * 0 - Successful write to the i2c device
5617 * * -EINVAL - Data size greater than 4 bytes
5618 * * -EIO - FW error
5619 */
5620int
5621ice_aq_write_i2c(struct ice_hw *hw, struct ice_aqc_link_topo_addr topo_addr,
5622 u16 bus_addr, __le16 addr, u8 params, const u8 *data,
5623 struct ice_sq_cd *cd)
5624{
5625 struct ice_aq_desc desc = { 0 };
5626 struct ice_aqc_i2c *cmd;
5627 u8 data_size;
5628
5629 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_write_i2c);
5630 cmd = &desc.params.read_write_i2c;
5631
5632 data_size = FIELD_GET(ICE_AQC_I2C_DATA_SIZE_M, params);
5633
5634 /* data_size limited to 4 */
5635 if (data_size > 4)
5636 return -EINVAL;
5637
5638 cmd->i2c_bus_addr = cpu_to_le16(bus_addr);
5639 cmd->topo_addr = topo_addr;
5640 cmd->i2c_params = params;
5641 cmd->i2c_addr = addr;
5642
5643 memcpy(cmd->i2c_data, data, data_size);
5644
5645 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5646}
5647
5648/**
5649 * ice_aq_set_gpio
5650 * @hw: pointer to the hw struct
5651 * @gpio_ctrl_handle: GPIO controller node handle
5652 * @pin_idx: IO Number of the GPIO that needs to be set
5653 * @value: SW provide IO value to set in the LSB
5654 * @cd: pointer to command details structure or NULL
5655 *
5656 * Sends 0x06EC AQ command to set the GPIO pin state that's part of the topology
5657 */
5658int
5659ice_aq_set_gpio(struct ice_hw *hw, u16 gpio_ctrl_handle, u8 pin_idx, bool value,
5660 struct ice_sq_cd *cd)
5661{
5662 struct ice_aqc_gpio *cmd;
5663 struct ice_aq_desc desc;
5664
5665 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_gpio);
5666 cmd = &desc.params.read_write_gpio;
5667 cmd->gpio_ctrl_handle = cpu_to_le16(gpio_ctrl_handle);
5668 cmd->gpio_num = pin_idx;
5669 cmd->gpio_val = value ? 1 : 0;
5670
5671 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5672}
5673
5674/**
5675 * ice_aq_get_gpio
5676 * @hw: pointer to the hw struct
5677 * @gpio_ctrl_handle: GPIO controller node handle
5678 * @pin_idx: IO Number of the GPIO that needs to be set
5679 * @value: IO value read
5680 * @cd: pointer to command details structure or NULL
5681 *
5682 * Sends 0x06ED AQ command to get the value of a GPIO signal which is part of
5683 * the topology
5684 */
5685int
5686ice_aq_get_gpio(struct ice_hw *hw, u16 gpio_ctrl_handle, u8 pin_idx,
5687 bool *value, struct ice_sq_cd *cd)
5688{
5689 struct ice_aqc_gpio *cmd;
5690 struct ice_aq_desc desc;
5691 int status;
5692
5693 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_gpio);
5694 cmd = &desc.params.read_write_gpio;
5695 cmd->gpio_ctrl_handle = cpu_to_le16(gpio_ctrl_handle);
5696 cmd->gpio_num = pin_idx;
5697
5698 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5699 if (status)
5700 return status;
5701
5702 *value = !!cmd->gpio_val;
5703 return 0;
5704}
5705
5706/**
5707 * ice_is_fw_api_min_ver
5708 * @hw: pointer to the hardware structure
5709 * @maj: major version
5710 * @min: minor version
5711 * @patch: patch version
5712 *
5713 * Checks if the firmware API is minimum version
5714 */
5715static bool ice_is_fw_api_min_ver(struct ice_hw *hw, u8 maj, u8 min, u8 patch)
5716{
5717 if (hw->api_maj_ver == maj) {
5718 if (hw->api_min_ver > min)
5719 return true;
5720 if (hw->api_min_ver == min && hw->api_patch >= patch)
5721 return true;
5722 } else if (hw->api_maj_ver > maj) {
5723 return true;
5724 }
5725
5726 return false;
5727}
5728
5729/**
5730 * ice_fw_supports_link_override
5731 * @hw: pointer to the hardware structure
5732 *
5733 * Checks if the firmware supports link override
5734 */
5735bool ice_fw_supports_link_override(struct ice_hw *hw)
5736{
5737 return ice_is_fw_api_min_ver(hw, ICE_FW_API_LINK_OVERRIDE_MAJ,
5738 ICE_FW_API_LINK_OVERRIDE_MIN,
5739 ICE_FW_API_LINK_OVERRIDE_PATCH);
5740}
5741
5742/**
5743 * ice_get_link_default_override
5744 * @ldo: pointer to the link default override struct
5745 * @pi: pointer to the port info struct
5746 *
5747 * Gets the link default override for a port
5748 */
5749int
5750ice_get_link_default_override(struct ice_link_default_override_tlv *ldo,
5751 struct ice_port_info *pi)
5752{
5753 u16 i, tlv, tlv_len, tlv_start, buf, offset;
5754 struct ice_hw *hw = pi->hw;
5755 int status;
5756
5757 status = ice_get_pfa_module_tlv(hw, &tlv, &tlv_len,
5758 ICE_SR_LINK_DEFAULT_OVERRIDE_PTR);
5759 if (status) {
5760 ice_debug(hw, ICE_DBG_INIT, "Failed to read link override TLV.\n");
5761 return status;
5762 }
5763
5764 /* Each port has its own config; calculate for our port */
5765 tlv_start = tlv + pi->lport * ICE_SR_PFA_LINK_OVERRIDE_WORDS +
5766 ICE_SR_PFA_LINK_OVERRIDE_OFFSET;
5767
5768 /* link options first */
5769 status = ice_read_sr_word(hw, tlv_start, &buf);
5770 if (status) {
5771 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5772 return status;
5773 }
5774 ldo->options = FIELD_GET(ICE_LINK_OVERRIDE_OPT_M, buf);
5775 ldo->phy_config = (buf & ICE_LINK_OVERRIDE_PHY_CFG_M) >>
5776 ICE_LINK_OVERRIDE_PHY_CFG_S;
5777
5778 /* link PHY config */
5779 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_FEC_OFFSET;
5780 status = ice_read_sr_word(hw, offset, &buf);
5781 if (status) {
5782 ice_debug(hw, ICE_DBG_INIT, "Failed to read override phy config.\n");
5783 return status;
5784 }
5785 ldo->fec_options = buf & ICE_LINK_OVERRIDE_FEC_OPT_M;
5786
5787 /* PHY types low */
5788 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_PHY_OFFSET;
5789 for (i = 0; i < ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS; i++) {
5790 status = ice_read_sr_word(hw, (offset + i), &buf);
5791 if (status) {
5792 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5793 return status;
5794 }
5795 /* shift 16 bits at a time to fill 64 bits */
5796 ldo->phy_type_low |= ((u64)buf << (i * 16));
5797 }
5798
5799 /* PHY types high */
5800 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_PHY_OFFSET +
5801 ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS;
5802 for (i = 0; i < ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS; i++) {
5803 status = ice_read_sr_word(hw, (offset + i), &buf);
5804 if (status) {
5805 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5806 return status;
5807 }
5808 /* shift 16 bits at a time to fill 64 bits */
5809 ldo->phy_type_high |= ((u64)buf << (i * 16));
5810 }
5811
5812 return status;
5813}
5814
5815/**
5816 * ice_is_phy_caps_an_enabled - check if PHY capabilities autoneg is enabled
5817 * @caps: get PHY capability data
5818 */
5819bool ice_is_phy_caps_an_enabled(struct ice_aqc_get_phy_caps_data *caps)
5820{
5821 if (caps->caps & ICE_AQC_PHY_AN_MODE ||
5822 caps->low_power_ctrl_an & (ICE_AQC_PHY_AN_EN_CLAUSE28 |
5823 ICE_AQC_PHY_AN_EN_CLAUSE73 |
5824 ICE_AQC_PHY_AN_EN_CLAUSE37))
5825 return true;
5826
5827 return false;
5828}
5829
5830/**
5831 * ice_aq_set_lldp_mib - Set the LLDP MIB
5832 * @hw: pointer to the HW struct
5833 * @mib_type: Local, Remote or both Local and Remote MIBs
5834 * @buf: pointer to the caller-supplied buffer to store the MIB block
5835 * @buf_size: size of the buffer (in bytes)
5836 * @cd: pointer to command details structure or NULL
5837 *
5838 * Set the LLDP MIB. (0x0A08)
5839 */
5840int
5841ice_aq_set_lldp_mib(struct ice_hw *hw, u8 mib_type, void *buf, u16 buf_size,
5842 struct ice_sq_cd *cd)
5843{
5844 struct ice_aqc_lldp_set_local_mib *cmd;
5845 struct ice_aq_desc desc;
5846
5847 cmd = &desc.params.lldp_set_mib;
5848
5849 if (buf_size == 0 || !buf)
5850 return -EINVAL;
5851
5852 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_set_local_mib);
5853
5854 desc.flags |= cpu_to_le16((u16)ICE_AQ_FLAG_RD);
5855 desc.datalen = cpu_to_le16(buf_size);
5856
5857 cmd->type = mib_type;
5858 cmd->length = cpu_to_le16(buf_size);
5859
5860 return ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
5861}
5862
5863/**
5864 * ice_fw_supports_lldp_fltr_ctrl - check NVM version supports lldp_fltr_ctrl
5865 * @hw: pointer to HW struct
5866 */
5867bool ice_fw_supports_lldp_fltr_ctrl(struct ice_hw *hw)
5868{
5869 if (hw->mac_type != ICE_MAC_E810)
5870 return false;
5871
5872 return ice_is_fw_api_min_ver(hw, ICE_FW_API_LLDP_FLTR_MAJ,
5873 ICE_FW_API_LLDP_FLTR_MIN,
5874 ICE_FW_API_LLDP_FLTR_PATCH);
5875}
5876
5877/**
5878 * ice_lldp_fltr_add_remove - add or remove a LLDP Rx switch filter
5879 * @hw: pointer to HW struct
5880 * @vsi_num: absolute HW index for VSI
5881 * @add: boolean for if adding or removing a filter
5882 */
5883int
5884ice_lldp_fltr_add_remove(struct ice_hw *hw, u16 vsi_num, bool add)
5885{
5886 struct ice_aqc_lldp_filter_ctrl *cmd;
5887 struct ice_aq_desc desc;
5888
5889 cmd = &desc.params.lldp_filter_ctrl;
5890
5891 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_filter_ctrl);
5892
5893 if (add)
5894 cmd->cmd_flags = ICE_AQC_LLDP_FILTER_ACTION_ADD;
5895 else
5896 cmd->cmd_flags = ICE_AQC_LLDP_FILTER_ACTION_DELETE;
5897
5898 cmd->vsi_num = cpu_to_le16(vsi_num);
5899
5900 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5901}
5902
5903/**
5904 * ice_lldp_execute_pending_mib - execute LLDP pending MIB request
5905 * @hw: pointer to HW struct
5906 */
5907int ice_lldp_execute_pending_mib(struct ice_hw *hw)
5908{
5909 struct ice_aq_desc desc;
5910
5911 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_execute_pending_mib);
5912
5913 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5914}
5915
5916/**
5917 * ice_fw_supports_report_dflt_cfg
5918 * @hw: pointer to the hardware structure
5919 *
5920 * Checks if the firmware supports report default configuration
5921 */
5922bool ice_fw_supports_report_dflt_cfg(struct ice_hw *hw)
5923{
5924 return ice_is_fw_api_min_ver(hw, ICE_FW_API_REPORT_DFLT_CFG_MAJ,
5925 ICE_FW_API_REPORT_DFLT_CFG_MIN,
5926 ICE_FW_API_REPORT_DFLT_CFG_PATCH);
5927}
5928
5929/* each of the indexes into the following array match the speed of a return
5930 * value from the list of AQ returned speeds like the range:
5931 * ICE_AQ_LINK_SPEED_10MB .. ICE_AQ_LINK_SPEED_100GB excluding
5932 * ICE_AQ_LINK_SPEED_UNKNOWN which is BIT(15) and maps to BIT(14) in this
5933 * array. The array is defined as 15 elements long because the link_speed
5934 * returned by the firmware is a 16 bit * value, but is indexed
5935 * by [fls(speed) - 1]
5936 */
5937static const u32 ice_aq_to_link_speed[] = {
5938 SPEED_10, /* BIT(0) */
5939 SPEED_100,
5940 SPEED_1000,
5941 SPEED_2500,
5942 SPEED_5000,
5943 SPEED_10000,
5944 SPEED_20000,
5945 SPEED_25000,
5946 SPEED_40000,
5947 SPEED_50000,
5948 SPEED_100000, /* BIT(10) */
5949 SPEED_200000,
5950};
5951
5952/**
5953 * ice_get_link_speed - get integer speed from table
5954 * @index: array index from fls(aq speed) - 1
5955 *
5956 * Returns: u32 value containing integer speed
5957 */
5958u32 ice_get_link_speed(u16 index)
5959{
5960 if (index >= ARRAY_SIZE(ice_aq_to_link_speed))
5961 return 0;
5962
5963 return ice_aq_to_link_speed[index];
5964}
1// SPDX-License-Identifier: GPL-2.0
2/* Copyright (c) 2018-2023, Intel Corporation. */
3
4#include "ice_common.h"
5#include "ice_sched.h"
6#include "ice_adminq_cmd.h"
7#include "ice_flow.h"
8#include "ice_ptp_hw.h"
9
10#define ICE_PF_RESET_WAIT_COUNT 300
11#define ICE_MAX_NETLIST_SIZE 10
12
13static const char * const ice_link_mode_str_low[] = {
14 [0] = "100BASE_TX",
15 [1] = "100M_SGMII",
16 [2] = "1000BASE_T",
17 [3] = "1000BASE_SX",
18 [4] = "1000BASE_LX",
19 [5] = "1000BASE_KX",
20 [6] = "1G_SGMII",
21 [7] = "2500BASE_T",
22 [8] = "2500BASE_X",
23 [9] = "2500BASE_KX",
24 [10] = "5GBASE_T",
25 [11] = "5GBASE_KR",
26 [12] = "10GBASE_T",
27 [13] = "10G_SFI_DA",
28 [14] = "10GBASE_SR",
29 [15] = "10GBASE_LR",
30 [16] = "10GBASE_KR_CR1",
31 [17] = "10G_SFI_AOC_ACC",
32 [18] = "10G_SFI_C2C",
33 [19] = "25GBASE_T",
34 [20] = "25GBASE_CR",
35 [21] = "25GBASE_CR_S",
36 [22] = "25GBASE_CR1",
37 [23] = "25GBASE_SR",
38 [24] = "25GBASE_LR",
39 [25] = "25GBASE_KR",
40 [26] = "25GBASE_KR_S",
41 [27] = "25GBASE_KR1",
42 [28] = "25G_AUI_AOC_ACC",
43 [29] = "25G_AUI_C2C",
44 [30] = "40GBASE_CR4",
45 [31] = "40GBASE_SR4",
46 [32] = "40GBASE_LR4",
47 [33] = "40GBASE_KR4",
48 [34] = "40G_XLAUI_AOC_ACC",
49 [35] = "40G_XLAUI",
50 [36] = "50GBASE_CR2",
51 [37] = "50GBASE_SR2",
52 [38] = "50GBASE_LR2",
53 [39] = "50GBASE_KR2",
54 [40] = "50G_LAUI2_AOC_ACC",
55 [41] = "50G_LAUI2",
56 [42] = "50G_AUI2_AOC_ACC",
57 [43] = "50G_AUI2",
58 [44] = "50GBASE_CP",
59 [45] = "50GBASE_SR",
60 [46] = "50GBASE_FR",
61 [47] = "50GBASE_LR",
62 [48] = "50GBASE_KR_PAM4",
63 [49] = "50G_AUI1_AOC_ACC",
64 [50] = "50G_AUI1",
65 [51] = "100GBASE_CR4",
66 [52] = "100GBASE_SR4",
67 [53] = "100GBASE_LR4",
68 [54] = "100GBASE_KR4",
69 [55] = "100G_CAUI4_AOC_ACC",
70 [56] = "100G_CAUI4",
71 [57] = "100G_AUI4_AOC_ACC",
72 [58] = "100G_AUI4",
73 [59] = "100GBASE_CR_PAM4",
74 [60] = "100GBASE_KR_PAM4",
75 [61] = "100GBASE_CP2",
76 [62] = "100GBASE_SR2",
77 [63] = "100GBASE_DR",
78};
79
80static const char * const ice_link_mode_str_high[] = {
81 [0] = "100GBASE_KR2_PAM4",
82 [1] = "100G_CAUI2_AOC_ACC",
83 [2] = "100G_CAUI2",
84 [3] = "100G_AUI2_AOC_ACC",
85 [4] = "100G_AUI2",
86};
87
88/**
89 * ice_dump_phy_type - helper function to dump phy_type
90 * @hw: pointer to the HW structure
91 * @low: 64 bit value for phy_type_low
92 * @high: 64 bit value for phy_type_high
93 * @prefix: prefix string to differentiate multiple dumps
94 */
95static void
96ice_dump_phy_type(struct ice_hw *hw, u64 low, u64 high, const char *prefix)
97{
98 ice_debug(hw, ICE_DBG_PHY, "%s: phy_type_low: 0x%016llx\n", prefix, low);
99
100 for (u32 i = 0; i < BITS_PER_TYPE(typeof(low)); i++) {
101 if (low & BIT_ULL(i))
102 ice_debug(hw, ICE_DBG_PHY, "%s: bit(%d): %s\n",
103 prefix, i, ice_link_mode_str_low[i]);
104 }
105
106 ice_debug(hw, ICE_DBG_PHY, "%s: phy_type_high: 0x%016llx\n", prefix, high);
107
108 for (u32 i = 0; i < BITS_PER_TYPE(typeof(high)); i++) {
109 if (high & BIT_ULL(i))
110 ice_debug(hw, ICE_DBG_PHY, "%s: bit(%d): %s\n",
111 prefix, i, ice_link_mode_str_high[i]);
112 }
113}
114
115/**
116 * ice_set_mac_type - Sets MAC type
117 * @hw: pointer to the HW structure
118 *
119 * This function sets the MAC type of the adapter based on the
120 * vendor ID and device ID stored in the HW structure.
121 */
122static int ice_set_mac_type(struct ice_hw *hw)
123{
124 if (hw->vendor_id != PCI_VENDOR_ID_INTEL)
125 return -ENODEV;
126
127 switch (hw->device_id) {
128 case ICE_DEV_ID_E810C_BACKPLANE:
129 case ICE_DEV_ID_E810C_QSFP:
130 case ICE_DEV_ID_E810C_SFP:
131 case ICE_DEV_ID_E810_XXV_BACKPLANE:
132 case ICE_DEV_ID_E810_XXV_QSFP:
133 case ICE_DEV_ID_E810_XXV_SFP:
134 hw->mac_type = ICE_MAC_E810;
135 break;
136 case ICE_DEV_ID_E823C_10G_BASE_T:
137 case ICE_DEV_ID_E823C_BACKPLANE:
138 case ICE_DEV_ID_E823C_QSFP:
139 case ICE_DEV_ID_E823C_SFP:
140 case ICE_DEV_ID_E823C_SGMII:
141 case ICE_DEV_ID_E822C_10G_BASE_T:
142 case ICE_DEV_ID_E822C_BACKPLANE:
143 case ICE_DEV_ID_E822C_QSFP:
144 case ICE_DEV_ID_E822C_SFP:
145 case ICE_DEV_ID_E822C_SGMII:
146 case ICE_DEV_ID_E822L_10G_BASE_T:
147 case ICE_DEV_ID_E822L_BACKPLANE:
148 case ICE_DEV_ID_E822L_SFP:
149 case ICE_DEV_ID_E822L_SGMII:
150 case ICE_DEV_ID_E823L_10G_BASE_T:
151 case ICE_DEV_ID_E823L_1GBE:
152 case ICE_DEV_ID_E823L_BACKPLANE:
153 case ICE_DEV_ID_E823L_QSFP:
154 case ICE_DEV_ID_E823L_SFP:
155 hw->mac_type = ICE_MAC_GENERIC;
156 break;
157 case ICE_DEV_ID_E825C_BACKPLANE:
158 case ICE_DEV_ID_E825C_QSFP:
159 case ICE_DEV_ID_E825C_SFP:
160 case ICE_DEV_ID_E825C_SGMII:
161 hw->mac_type = ICE_MAC_GENERIC_3K_E825;
162 break;
163 case ICE_DEV_ID_E830_BACKPLANE:
164 case ICE_DEV_ID_E830_QSFP56:
165 case ICE_DEV_ID_E830_SFP:
166 case ICE_DEV_ID_E830_SFP_DD:
167 hw->mac_type = ICE_MAC_E830;
168 break;
169 default:
170 hw->mac_type = ICE_MAC_UNKNOWN;
171 break;
172 }
173
174 ice_debug(hw, ICE_DBG_INIT, "mac_type: %d\n", hw->mac_type);
175 return 0;
176}
177
178/**
179 * ice_is_generic_mac - check if device's mac_type is generic
180 * @hw: pointer to the hardware structure
181 *
182 * Return: true if mac_type is generic (with SBQ support), false if not
183 */
184bool ice_is_generic_mac(struct ice_hw *hw)
185{
186 return (hw->mac_type == ICE_MAC_GENERIC ||
187 hw->mac_type == ICE_MAC_GENERIC_3K_E825);
188}
189
190/**
191 * ice_is_e810
192 * @hw: pointer to the hardware structure
193 *
194 * returns true if the device is E810 based, false if not.
195 */
196bool ice_is_e810(struct ice_hw *hw)
197{
198 return hw->mac_type == ICE_MAC_E810;
199}
200
201/**
202 * ice_is_e810t
203 * @hw: pointer to the hardware structure
204 *
205 * returns true if the device is E810T based, false if not.
206 */
207bool ice_is_e810t(struct ice_hw *hw)
208{
209 switch (hw->device_id) {
210 case ICE_DEV_ID_E810C_SFP:
211 switch (hw->subsystem_device_id) {
212 case ICE_SUBDEV_ID_E810T:
213 case ICE_SUBDEV_ID_E810T2:
214 case ICE_SUBDEV_ID_E810T3:
215 case ICE_SUBDEV_ID_E810T4:
216 case ICE_SUBDEV_ID_E810T6:
217 case ICE_SUBDEV_ID_E810T7:
218 return true;
219 }
220 break;
221 case ICE_DEV_ID_E810C_QSFP:
222 switch (hw->subsystem_device_id) {
223 case ICE_SUBDEV_ID_E810T2:
224 case ICE_SUBDEV_ID_E810T3:
225 case ICE_SUBDEV_ID_E810T5:
226 return true;
227 }
228 break;
229 default:
230 break;
231 }
232
233 return false;
234}
235
236/**
237 * ice_is_e823
238 * @hw: pointer to the hardware structure
239 *
240 * returns true if the device is E823-L or E823-C based, false if not.
241 */
242bool ice_is_e823(struct ice_hw *hw)
243{
244 switch (hw->device_id) {
245 case ICE_DEV_ID_E823L_BACKPLANE:
246 case ICE_DEV_ID_E823L_SFP:
247 case ICE_DEV_ID_E823L_10G_BASE_T:
248 case ICE_DEV_ID_E823L_1GBE:
249 case ICE_DEV_ID_E823L_QSFP:
250 case ICE_DEV_ID_E823C_BACKPLANE:
251 case ICE_DEV_ID_E823C_QSFP:
252 case ICE_DEV_ID_E823C_SFP:
253 case ICE_DEV_ID_E823C_10G_BASE_T:
254 case ICE_DEV_ID_E823C_SGMII:
255 return true;
256 default:
257 return false;
258 }
259}
260
261/**
262 * ice_is_e825c - Check if a device is E825C family device
263 * @hw: pointer to the hardware structure
264 *
265 * Return: true if the device is E825-C based, false if not.
266 */
267bool ice_is_e825c(struct ice_hw *hw)
268{
269 switch (hw->device_id) {
270 case ICE_DEV_ID_E825C_BACKPLANE:
271 case ICE_DEV_ID_E825C_QSFP:
272 case ICE_DEV_ID_E825C_SFP:
273 case ICE_DEV_ID_E825C_SGMII:
274 return true;
275 default:
276 return false;
277 }
278}
279
280/**
281 * ice_clear_pf_cfg - Clear PF configuration
282 * @hw: pointer to the hardware structure
283 *
284 * Clears any existing PF configuration (VSIs, VSI lists, switch rules, port
285 * configuration, flow director filters, etc.).
286 */
287int ice_clear_pf_cfg(struct ice_hw *hw)
288{
289 struct ice_aq_desc desc;
290
291 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_clear_pf_cfg);
292
293 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
294}
295
296/**
297 * ice_aq_manage_mac_read - manage MAC address read command
298 * @hw: pointer to the HW struct
299 * @buf: a virtual buffer to hold the manage MAC read response
300 * @buf_size: Size of the virtual buffer
301 * @cd: pointer to command details structure or NULL
302 *
303 * This function is used to return per PF station MAC address (0x0107).
304 * NOTE: Upon successful completion of this command, MAC address information
305 * is returned in user specified buffer. Please interpret user specified
306 * buffer as "manage_mac_read" response.
307 * Response such as various MAC addresses are stored in HW struct (port.mac)
308 * ice_discover_dev_caps is expected to be called before this function is
309 * called.
310 */
311static int
312ice_aq_manage_mac_read(struct ice_hw *hw, void *buf, u16 buf_size,
313 struct ice_sq_cd *cd)
314{
315 struct ice_aqc_manage_mac_read_resp *resp;
316 struct ice_aqc_manage_mac_read *cmd;
317 struct ice_aq_desc desc;
318 int status;
319 u16 flags;
320 u8 i;
321
322 cmd = &desc.params.mac_read;
323
324 if (buf_size < sizeof(*resp))
325 return -EINVAL;
326
327 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_manage_mac_read);
328
329 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
330 if (status)
331 return status;
332
333 resp = buf;
334 flags = le16_to_cpu(cmd->flags) & ICE_AQC_MAN_MAC_READ_M;
335
336 if (!(flags & ICE_AQC_MAN_MAC_LAN_ADDR_VALID)) {
337 ice_debug(hw, ICE_DBG_LAN, "got invalid MAC address\n");
338 return -EIO;
339 }
340
341 /* A single port can report up to two (LAN and WoL) addresses */
342 for (i = 0; i < cmd->num_addr; i++)
343 if (resp[i].addr_type == ICE_AQC_MAN_MAC_ADDR_TYPE_LAN) {
344 ether_addr_copy(hw->port_info->mac.lan_addr,
345 resp[i].mac_addr);
346 ether_addr_copy(hw->port_info->mac.perm_addr,
347 resp[i].mac_addr);
348 break;
349 }
350
351 return 0;
352}
353
354/**
355 * ice_aq_get_phy_caps - returns PHY capabilities
356 * @pi: port information structure
357 * @qual_mods: report qualified modules
358 * @report_mode: report mode capabilities
359 * @pcaps: structure for PHY capabilities to be filled
360 * @cd: pointer to command details structure or NULL
361 *
362 * Returns the various PHY capabilities supported on the Port (0x0600)
363 */
364int
365ice_aq_get_phy_caps(struct ice_port_info *pi, bool qual_mods, u8 report_mode,
366 struct ice_aqc_get_phy_caps_data *pcaps,
367 struct ice_sq_cd *cd)
368{
369 struct ice_aqc_get_phy_caps *cmd;
370 u16 pcaps_size = sizeof(*pcaps);
371 struct ice_aq_desc desc;
372 const char *prefix;
373 struct ice_hw *hw;
374 int status;
375
376 cmd = &desc.params.get_phy;
377
378 if (!pcaps || (report_mode & ~ICE_AQC_REPORT_MODE_M) || !pi)
379 return -EINVAL;
380 hw = pi->hw;
381
382 if (report_mode == ICE_AQC_REPORT_DFLT_CFG &&
383 !ice_fw_supports_report_dflt_cfg(hw))
384 return -EINVAL;
385
386 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_phy_caps);
387
388 if (qual_mods)
389 cmd->param0 |= cpu_to_le16(ICE_AQC_GET_PHY_RQM);
390
391 cmd->param0 |= cpu_to_le16(report_mode);
392 status = ice_aq_send_cmd(hw, &desc, pcaps, pcaps_size, cd);
393
394 ice_debug(hw, ICE_DBG_LINK, "get phy caps dump\n");
395
396 switch (report_mode) {
397 case ICE_AQC_REPORT_TOPO_CAP_MEDIA:
398 prefix = "phy_caps_media";
399 break;
400 case ICE_AQC_REPORT_TOPO_CAP_NO_MEDIA:
401 prefix = "phy_caps_no_media";
402 break;
403 case ICE_AQC_REPORT_ACTIVE_CFG:
404 prefix = "phy_caps_active";
405 break;
406 case ICE_AQC_REPORT_DFLT_CFG:
407 prefix = "phy_caps_default";
408 break;
409 default:
410 prefix = "phy_caps_invalid";
411 }
412
413 ice_dump_phy_type(hw, le64_to_cpu(pcaps->phy_type_low),
414 le64_to_cpu(pcaps->phy_type_high), prefix);
415
416 ice_debug(hw, ICE_DBG_LINK, "%s: report_mode = 0x%x\n",
417 prefix, report_mode);
418 ice_debug(hw, ICE_DBG_LINK, "%s: caps = 0x%x\n", prefix, pcaps->caps);
419 ice_debug(hw, ICE_DBG_LINK, "%s: low_power_ctrl_an = 0x%x\n", prefix,
420 pcaps->low_power_ctrl_an);
421 ice_debug(hw, ICE_DBG_LINK, "%s: eee_cap = 0x%x\n", prefix,
422 pcaps->eee_cap);
423 ice_debug(hw, ICE_DBG_LINK, "%s: eeer_value = 0x%x\n", prefix,
424 pcaps->eeer_value);
425 ice_debug(hw, ICE_DBG_LINK, "%s: link_fec_options = 0x%x\n", prefix,
426 pcaps->link_fec_options);
427 ice_debug(hw, ICE_DBG_LINK, "%s: module_compliance_enforcement = 0x%x\n",
428 prefix, pcaps->module_compliance_enforcement);
429 ice_debug(hw, ICE_DBG_LINK, "%s: extended_compliance_code = 0x%x\n",
430 prefix, pcaps->extended_compliance_code);
431 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[0] = 0x%x\n", prefix,
432 pcaps->module_type[0]);
433 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[1] = 0x%x\n", prefix,
434 pcaps->module_type[1]);
435 ice_debug(hw, ICE_DBG_LINK, "%s: module_type[2] = 0x%x\n", prefix,
436 pcaps->module_type[2]);
437
438 if (!status && report_mode == ICE_AQC_REPORT_TOPO_CAP_MEDIA) {
439 pi->phy.phy_type_low = le64_to_cpu(pcaps->phy_type_low);
440 pi->phy.phy_type_high = le64_to_cpu(pcaps->phy_type_high);
441 memcpy(pi->phy.link_info.module_type, &pcaps->module_type,
442 sizeof(pi->phy.link_info.module_type));
443 }
444
445 return status;
446}
447
448/**
449 * ice_aq_get_link_topo_handle - get link topology node return status
450 * @pi: port information structure
451 * @node_type: requested node type
452 * @cd: pointer to command details structure or NULL
453 *
454 * Get link topology node return status for specified node type (0x06E0)
455 *
456 * Node type cage can be used to determine if cage is present. If AQC
457 * returns error (ENOENT), then no cage present. If no cage present, then
458 * connection type is backplane or BASE-T.
459 */
460static int
461ice_aq_get_link_topo_handle(struct ice_port_info *pi, u8 node_type,
462 struct ice_sq_cd *cd)
463{
464 struct ice_aqc_get_link_topo *cmd;
465 struct ice_aq_desc desc;
466
467 cmd = &desc.params.get_link_topo;
468
469 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_topo);
470
471 cmd->addr.topo_params.node_type_ctx =
472 (ICE_AQC_LINK_TOPO_NODE_CTX_PORT <<
473 ICE_AQC_LINK_TOPO_NODE_CTX_S);
474
475 /* set node type */
476 cmd->addr.topo_params.node_type_ctx |=
477 (ICE_AQC_LINK_TOPO_NODE_TYPE_M & node_type);
478
479 return ice_aq_send_cmd(pi->hw, &desc, NULL, 0, cd);
480}
481
482/**
483 * ice_aq_get_netlist_node
484 * @hw: pointer to the hw struct
485 * @cmd: get_link_topo AQ structure
486 * @node_part_number: output node part number if node found
487 * @node_handle: output node handle parameter if node found
488 *
489 * Get netlist node handle.
490 */
491int
492ice_aq_get_netlist_node(struct ice_hw *hw, struct ice_aqc_get_link_topo *cmd,
493 u8 *node_part_number, u16 *node_handle)
494{
495 struct ice_aq_desc desc;
496
497 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_topo);
498 desc.params.get_link_topo = *cmd;
499
500 if (ice_aq_send_cmd(hw, &desc, NULL, 0, NULL))
501 return -EINTR;
502
503 if (node_handle)
504 *node_handle =
505 le16_to_cpu(desc.params.get_link_topo.addr.handle);
506 if (node_part_number)
507 *node_part_number = desc.params.get_link_topo.node_part_num;
508
509 return 0;
510}
511
512/**
513 * ice_find_netlist_node
514 * @hw: pointer to the hw struct
515 * @node_type_ctx: type of netlist node to look for
516 * @node_part_number: node part number to look for
517 * @node_handle: output parameter if node found - optional
518 *
519 * Scan the netlist for a node handle of the given node type and part number.
520 *
521 * If node_handle is non-NULL it will be modified on function exit. It is only
522 * valid if the function returns zero, and should be ignored on any non-zero
523 * return value.
524 *
525 * Returns: 0 if the node is found, -ENOENT if no handle was found, and
526 * a negative error code on failure to access the AQ.
527 */
528static int ice_find_netlist_node(struct ice_hw *hw, u8 node_type_ctx,
529 u8 node_part_number, u16 *node_handle)
530{
531 u8 idx;
532
533 for (idx = 0; idx < ICE_MAX_NETLIST_SIZE; idx++) {
534 struct ice_aqc_get_link_topo cmd = {};
535 u8 rec_node_part_number;
536 int status;
537
538 cmd.addr.topo_params.node_type_ctx =
539 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_TYPE_M,
540 node_type_ctx);
541 cmd.addr.topo_params.index = idx;
542
543 status = ice_aq_get_netlist_node(hw, &cmd,
544 &rec_node_part_number,
545 node_handle);
546 if (status)
547 return status;
548
549 if (rec_node_part_number == node_part_number)
550 return 0;
551 }
552
553 return -ENOENT;
554}
555
556/**
557 * ice_is_media_cage_present
558 * @pi: port information structure
559 *
560 * Returns true if media cage is present, else false. If no cage, then
561 * media type is backplane or BASE-T.
562 */
563static bool ice_is_media_cage_present(struct ice_port_info *pi)
564{
565 /* Node type cage can be used to determine if cage is present. If AQC
566 * returns error (ENOENT), then no cage present. If no cage present then
567 * connection type is backplane or BASE-T.
568 */
569 return !ice_aq_get_link_topo_handle(pi,
570 ICE_AQC_LINK_TOPO_NODE_TYPE_CAGE,
571 NULL);
572}
573
574/**
575 * ice_get_media_type - Gets media type
576 * @pi: port information structure
577 */
578static enum ice_media_type ice_get_media_type(struct ice_port_info *pi)
579{
580 struct ice_link_status *hw_link_info;
581
582 if (!pi)
583 return ICE_MEDIA_UNKNOWN;
584
585 hw_link_info = &pi->phy.link_info;
586 if (hw_link_info->phy_type_low && hw_link_info->phy_type_high)
587 /* If more than one media type is selected, report unknown */
588 return ICE_MEDIA_UNKNOWN;
589
590 if (hw_link_info->phy_type_low) {
591 /* 1G SGMII is a special case where some DA cable PHYs
592 * may show this as an option when it really shouldn't
593 * be since SGMII is meant to be between a MAC and a PHY
594 * in a backplane. Try to detect this case and handle it
595 */
596 if (hw_link_info->phy_type_low == ICE_PHY_TYPE_LOW_1G_SGMII &&
597 (hw_link_info->module_type[ICE_AQC_MOD_TYPE_IDENT] ==
598 ICE_AQC_MOD_TYPE_BYTE1_SFP_PLUS_CU_ACTIVE ||
599 hw_link_info->module_type[ICE_AQC_MOD_TYPE_IDENT] ==
600 ICE_AQC_MOD_TYPE_BYTE1_SFP_PLUS_CU_PASSIVE))
601 return ICE_MEDIA_DA;
602
603 switch (hw_link_info->phy_type_low) {
604 case ICE_PHY_TYPE_LOW_1000BASE_SX:
605 case ICE_PHY_TYPE_LOW_1000BASE_LX:
606 case ICE_PHY_TYPE_LOW_10GBASE_SR:
607 case ICE_PHY_TYPE_LOW_10GBASE_LR:
608 case ICE_PHY_TYPE_LOW_10G_SFI_C2C:
609 case ICE_PHY_TYPE_LOW_25GBASE_SR:
610 case ICE_PHY_TYPE_LOW_25GBASE_LR:
611 case ICE_PHY_TYPE_LOW_40GBASE_SR4:
612 case ICE_PHY_TYPE_LOW_40GBASE_LR4:
613 case ICE_PHY_TYPE_LOW_50GBASE_SR2:
614 case ICE_PHY_TYPE_LOW_50GBASE_LR2:
615 case ICE_PHY_TYPE_LOW_50GBASE_SR:
616 case ICE_PHY_TYPE_LOW_50GBASE_FR:
617 case ICE_PHY_TYPE_LOW_50GBASE_LR:
618 case ICE_PHY_TYPE_LOW_100GBASE_SR4:
619 case ICE_PHY_TYPE_LOW_100GBASE_LR4:
620 case ICE_PHY_TYPE_LOW_100GBASE_SR2:
621 case ICE_PHY_TYPE_LOW_100GBASE_DR:
622 case ICE_PHY_TYPE_LOW_10G_SFI_AOC_ACC:
623 case ICE_PHY_TYPE_LOW_25G_AUI_AOC_ACC:
624 case ICE_PHY_TYPE_LOW_40G_XLAUI_AOC_ACC:
625 case ICE_PHY_TYPE_LOW_50G_LAUI2_AOC_ACC:
626 case ICE_PHY_TYPE_LOW_50G_AUI2_AOC_ACC:
627 case ICE_PHY_TYPE_LOW_50G_AUI1_AOC_ACC:
628 case ICE_PHY_TYPE_LOW_100G_CAUI4_AOC_ACC:
629 case ICE_PHY_TYPE_LOW_100G_AUI4_AOC_ACC:
630 return ICE_MEDIA_FIBER;
631 case ICE_PHY_TYPE_LOW_100BASE_TX:
632 case ICE_PHY_TYPE_LOW_1000BASE_T:
633 case ICE_PHY_TYPE_LOW_2500BASE_T:
634 case ICE_PHY_TYPE_LOW_5GBASE_T:
635 case ICE_PHY_TYPE_LOW_10GBASE_T:
636 case ICE_PHY_TYPE_LOW_25GBASE_T:
637 return ICE_MEDIA_BASET;
638 case ICE_PHY_TYPE_LOW_10G_SFI_DA:
639 case ICE_PHY_TYPE_LOW_25GBASE_CR:
640 case ICE_PHY_TYPE_LOW_25GBASE_CR_S:
641 case ICE_PHY_TYPE_LOW_25GBASE_CR1:
642 case ICE_PHY_TYPE_LOW_40GBASE_CR4:
643 case ICE_PHY_TYPE_LOW_50GBASE_CR2:
644 case ICE_PHY_TYPE_LOW_50GBASE_CP:
645 case ICE_PHY_TYPE_LOW_100GBASE_CR4:
646 case ICE_PHY_TYPE_LOW_100GBASE_CR_PAM4:
647 case ICE_PHY_TYPE_LOW_100GBASE_CP2:
648 return ICE_MEDIA_DA;
649 case ICE_PHY_TYPE_LOW_25G_AUI_C2C:
650 case ICE_PHY_TYPE_LOW_40G_XLAUI:
651 case ICE_PHY_TYPE_LOW_50G_LAUI2:
652 case ICE_PHY_TYPE_LOW_50G_AUI2:
653 case ICE_PHY_TYPE_LOW_50G_AUI1:
654 case ICE_PHY_TYPE_LOW_100G_AUI4:
655 case ICE_PHY_TYPE_LOW_100G_CAUI4:
656 if (ice_is_media_cage_present(pi))
657 return ICE_MEDIA_DA;
658 fallthrough;
659 case ICE_PHY_TYPE_LOW_1000BASE_KX:
660 case ICE_PHY_TYPE_LOW_2500BASE_KX:
661 case ICE_PHY_TYPE_LOW_2500BASE_X:
662 case ICE_PHY_TYPE_LOW_5GBASE_KR:
663 case ICE_PHY_TYPE_LOW_10GBASE_KR_CR1:
664 case ICE_PHY_TYPE_LOW_25GBASE_KR:
665 case ICE_PHY_TYPE_LOW_25GBASE_KR1:
666 case ICE_PHY_TYPE_LOW_25GBASE_KR_S:
667 case ICE_PHY_TYPE_LOW_40GBASE_KR4:
668 case ICE_PHY_TYPE_LOW_50GBASE_KR_PAM4:
669 case ICE_PHY_TYPE_LOW_50GBASE_KR2:
670 case ICE_PHY_TYPE_LOW_100GBASE_KR4:
671 case ICE_PHY_TYPE_LOW_100GBASE_KR_PAM4:
672 return ICE_MEDIA_BACKPLANE;
673 }
674 } else {
675 switch (hw_link_info->phy_type_high) {
676 case ICE_PHY_TYPE_HIGH_100G_AUI2:
677 case ICE_PHY_TYPE_HIGH_100G_CAUI2:
678 if (ice_is_media_cage_present(pi))
679 return ICE_MEDIA_DA;
680 fallthrough;
681 case ICE_PHY_TYPE_HIGH_100GBASE_KR2_PAM4:
682 return ICE_MEDIA_BACKPLANE;
683 case ICE_PHY_TYPE_HIGH_100G_CAUI2_AOC_ACC:
684 case ICE_PHY_TYPE_HIGH_100G_AUI2_AOC_ACC:
685 return ICE_MEDIA_FIBER;
686 }
687 }
688 return ICE_MEDIA_UNKNOWN;
689}
690
691/**
692 * ice_get_link_status_datalen
693 * @hw: pointer to the HW struct
694 *
695 * Returns datalength for the Get Link Status AQ command, which is bigger for
696 * newer adapter families handled by ice driver.
697 */
698static u16 ice_get_link_status_datalen(struct ice_hw *hw)
699{
700 switch (hw->mac_type) {
701 case ICE_MAC_E830:
702 return ICE_AQC_LS_DATA_SIZE_V2;
703 case ICE_MAC_E810:
704 default:
705 return ICE_AQC_LS_DATA_SIZE_V1;
706 }
707}
708
709/**
710 * ice_aq_get_link_info
711 * @pi: port information structure
712 * @ena_lse: enable/disable LinkStatusEvent reporting
713 * @link: pointer to link status structure - optional
714 * @cd: pointer to command details structure or NULL
715 *
716 * Get Link Status (0x607). Returns the link status of the adapter.
717 */
718int
719ice_aq_get_link_info(struct ice_port_info *pi, bool ena_lse,
720 struct ice_link_status *link, struct ice_sq_cd *cd)
721{
722 struct ice_aqc_get_link_status_data link_data = { 0 };
723 struct ice_aqc_get_link_status *resp;
724 struct ice_link_status *li_old, *li;
725 enum ice_media_type *hw_media_type;
726 struct ice_fc_info *hw_fc_info;
727 bool tx_pause, rx_pause;
728 struct ice_aq_desc desc;
729 struct ice_hw *hw;
730 u16 cmd_flags;
731 int status;
732
733 if (!pi)
734 return -EINVAL;
735 hw = pi->hw;
736 li_old = &pi->phy.link_info_old;
737 hw_media_type = &pi->phy.media_type;
738 li = &pi->phy.link_info;
739 hw_fc_info = &pi->fc;
740
741 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_link_status);
742 cmd_flags = (ena_lse) ? ICE_AQ_LSE_ENA : ICE_AQ_LSE_DIS;
743 resp = &desc.params.get_link_status;
744 resp->cmd_flags = cpu_to_le16(cmd_flags);
745 resp->lport_num = pi->lport;
746
747 status = ice_aq_send_cmd(hw, &desc, &link_data,
748 ice_get_link_status_datalen(hw), cd);
749 if (status)
750 return status;
751
752 /* save off old link status information */
753 *li_old = *li;
754
755 /* update current link status information */
756 li->link_speed = le16_to_cpu(link_data.link_speed);
757 li->phy_type_low = le64_to_cpu(link_data.phy_type_low);
758 li->phy_type_high = le64_to_cpu(link_data.phy_type_high);
759 *hw_media_type = ice_get_media_type(pi);
760 li->link_info = link_data.link_info;
761 li->link_cfg_err = link_data.link_cfg_err;
762 li->an_info = link_data.an_info;
763 li->ext_info = link_data.ext_info;
764 li->max_frame_size = le16_to_cpu(link_data.max_frame_size);
765 li->fec_info = link_data.cfg & ICE_AQ_FEC_MASK;
766 li->topo_media_conflict = link_data.topo_media_conflict;
767 li->pacing = link_data.cfg & (ICE_AQ_CFG_PACING_M |
768 ICE_AQ_CFG_PACING_TYPE_M);
769
770 /* update fc info */
771 tx_pause = !!(link_data.an_info & ICE_AQ_LINK_PAUSE_TX);
772 rx_pause = !!(link_data.an_info & ICE_AQ_LINK_PAUSE_RX);
773 if (tx_pause && rx_pause)
774 hw_fc_info->current_mode = ICE_FC_FULL;
775 else if (tx_pause)
776 hw_fc_info->current_mode = ICE_FC_TX_PAUSE;
777 else if (rx_pause)
778 hw_fc_info->current_mode = ICE_FC_RX_PAUSE;
779 else
780 hw_fc_info->current_mode = ICE_FC_NONE;
781
782 li->lse_ena = !!(resp->cmd_flags & cpu_to_le16(ICE_AQ_LSE_IS_ENABLED));
783
784 ice_debug(hw, ICE_DBG_LINK, "get link info\n");
785 ice_debug(hw, ICE_DBG_LINK, " link_speed = 0x%x\n", li->link_speed);
786 ice_debug(hw, ICE_DBG_LINK, " phy_type_low = 0x%llx\n",
787 (unsigned long long)li->phy_type_low);
788 ice_debug(hw, ICE_DBG_LINK, " phy_type_high = 0x%llx\n",
789 (unsigned long long)li->phy_type_high);
790 ice_debug(hw, ICE_DBG_LINK, " media_type = 0x%x\n", *hw_media_type);
791 ice_debug(hw, ICE_DBG_LINK, " link_info = 0x%x\n", li->link_info);
792 ice_debug(hw, ICE_DBG_LINK, " link_cfg_err = 0x%x\n", li->link_cfg_err);
793 ice_debug(hw, ICE_DBG_LINK, " an_info = 0x%x\n", li->an_info);
794 ice_debug(hw, ICE_DBG_LINK, " ext_info = 0x%x\n", li->ext_info);
795 ice_debug(hw, ICE_DBG_LINK, " fec_info = 0x%x\n", li->fec_info);
796 ice_debug(hw, ICE_DBG_LINK, " lse_ena = 0x%x\n", li->lse_ena);
797 ice_debug(hw, ICE_DBG_LINK, " max_frame = 0x%x\n",
798 li->max_frame_size);
799 ice_debug(hw, ICE_DBG_LINK, " pacing = 0x%x\n", li->pacing);
800
801 /* save link status information */
802 if (link)
803 *link = *li;
804
805 /* flag cleared so calling functions don't call AQ again */
806 pi->phy.get_link_info = false;
807
808 return 0;
809}
810
811/**
812 * ice_fill_tx_timer_and_fc_thresh
813 * @hw: pointer to the HW struct
814 * @cmd: pointer to MAC cfg structure
815 *
816 * Add Tx timer and FC refresh threshold info to Set MAC Config AQ command
817 * descriptor
818 */
819static void
820ice_fill_tx_timer_and_fc_thresh(struct ice_hw *hw,
821 struct ice_aqc_set_mac_cfg *cmd)
822{
823 u32 val, fc_thres_m;
824
825 /* We read back the transmit timer and FC threshold value of
826 * LFC. Thus, we will use index =
827 * PRTMAC_HSEC_CTL_TX_PAUSE_QUANTA_MAX_INDEX.
828 *
829 * Also, because we are operating on transmit timer and FC
830 * threshold of LFC, we don't turn on any bit in tx_tmr_priority
831 */
832#define E800_IDX_OF_LFC E800_PRTMAC_HSEC_CTL_TX_PS_QNT_MAX
833#define E800_REFRESH_TMR E800_PRTMAC_HSEC_CTL_TX_PS_RFSH_TMR
834
835 if (hw->mac_type == ICE_MAC_E830) {
836 /* Retrieve the transmit timer */
837 val = rd32(hw, E830_PRTMAC_CL01_PS_QNT);
838 cmd->tx_tmr_value =
839 le16_encode_bits(val, E830_PRTMAC_CL01_PS_QNT_CL0_M);
840
841 /* Retrieve the fc threshold */
842 val = rd32(hw, E830_PRTMAC_CL01_QNT_THR);
843 fc_thres_m = E830_PRTMAC_CL01_QNT_THR_CL0_M;
844 } else {
845 /* Retrieve the transmit timer */
846 val = rd32(hw,
847 E800_PRTMAC_HSEC_CTL_TX_PS_QNT(E800_IDX_OF_LFC));
848 cmd->tx_tmr_value =
849 le16_encode_bits(val,
850 E800_PRTMAC_HSEC_CTL_TX_PS_QNT_M);
851
852 /* Retrieve the fc threshold */
853 val = rd32(hw,
854 E800_REFRESH_TMR(E800_IDX_OF_LFC));
855 fc_thres_m = E800_PRTMAC_HSEC_CTL_TX_PS_RFSH_TMR_M;
856 }
857 cmd->fc_refresh_threshold = le16_encode_bits(val, fc_thres_m);
858}
859
860/**
861 * ice_aq_set_mac_cfg
862 * @hw: pointer to the HW struct
863 * @max_frame_size: Maximum Frame Size to be supported
864 * @cd: pointer to command details structure or NULL
865 *
866 * Set MAC configuration (0x0603)
867 */
868int
869ice_aq_set_mac_cfg(struct ice_hw *hw, u16 max_frame_size, struct ice_sq_cd *cd)
870{
871 struct ice_aqc_set_mac_cfg *cmd;
872 struct ice_aq_desc desc;
873
874 cmd = &desc.params.set_mac_cfg;
875
876 if (max_frame_size == 0)
877 return -EINVAL;
878
879 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_mac_cfg);
880
881 cmd->max_frame_size = cpu_to_le16(max_frame_size);
882
883 ice_fill_tx_timer_and_fc_thresh(hw, cmd);
884
885 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
886}
887
888/**
889 * ice_init_fltr_mgmt_struct - initializes filter management list and locks
890 * @hw: pointer to the HW struct
891 */
892static int ice_init_fltr_mgmt_struct(struct ice_hw *hw)
893{
894 struct ice_switch_info *sw;
895 int status;
896
897 hw->switch_info = devm_kzalloc(ice_hw_to_dev(hw),
898 sizeof(*hw->switch_info), GFP_KERNEL);
899 sw = hw->switch_info;
900
901 if (!sw)
902 return -ENOMEM;
903
904 INIT_LIST_HEAD(&sw->vsi_list_map_head);
905 sw->prof_res_bm_init = 0;
906
907 status = ice_init_def_sw_recp(hw);
908 if (status) {
909 devm_kfree(ice_hw_to_dev(hw), hw->switch_info);
910 return status;
911 }
912 return 0;
913}
914
915/**
916 * ice_cleanup_fltr_mgmt_struct - cleanup filter management list and locks
917 * @hw: pointer to the HW struct
918 */
919static void ice_cleanup_fltr_mgmt_struct(struct ice_hw *hw)
920{
921 struct ice_switch_info *sw = hw->switch_info;
922 struct ice_vsi_list_map_info *v_pos_map;
923 struct ice_vsi_list_map_info *v_tmp_map;
924 struct ice_sw_recipe *recps;
925 u8 i;
926
927 list_for_each_entry_safe(v_pos_map, v_tmp_map, &sw->vsi_list_map_head,
928 list_entry) {
929 list_del(&v_pos_map->list_entry);
930 devm_kfree(ice_hw_to_dev(hw), v_pos_map);
931 }
932 recps = sw->recp_list;
933 for (i = 0; i < ICE_MAX_NUM_RECIPES; i++) {
934 struct ice_recp_grp_entry *rg_entry, *tmprg_entry;
935
936 recps[i].root_rid = i;
937 list_for_each_entry_safe(rg_entry, tmprg_entry,
938 &recps[i].rg_list, l_entry) {
939 list_del(&rg_entry->l_entry);
940 devm_kfree(ice_hw_to_dev(hw), rg_entry);
941 }
942
943 if (recps[i].adv_rule) {
944 struct ice_adv_fltr_mgmt_list_entry *tmp_entry;
945 struct ice_adv_fltr_mgmt_list_entry *lst_itr;
946
947 mutex_destroy(&recps[i].filt_rule_lock);
948 list_for_each_entry_safe(lst_itr, tmp_entry,
949 &recps[i].filt_rules,
950 list_entry) {
951 list_del(&lst_itr->list_entry);
952 devm_kfree(ice_hw_to_dev(hw), lst_itr->lkups);
953 devm_kfree(ice_hw_to_dev(hw), lst_itr);
954 }
955 } else {
956 struct ice_fltr_mgmt_list_entry *lst_itr, *tmp_entry;
957
958 mutex_destroy(&recps[i].filt_rule_lock);
959 list_for_each_entry_safe(lst_itr, tmp_entry,
960 &recps[i].filt_rules,
961 list_entry) {
962 list_del(&lst_itr->list_entry);
963 devm_kfree(ice_hw_to_dev(hw), lst_itr);
964 }
965 }
966 devm_kfree(ice_hw_to_dev(hw), recps[i].root_buf);
967 }
968 ice_rm_all_sw_replay_rule_info(hw);
969 devm_kfree(ice_hw_to_dev(hw), sw->recp_list);
970 devm_kfree(ice_hw_to_dev(hw), sw);
971}
972
973/**
974 * ice_get_itr_intrl_gran
975 * @hw: pointer to the HW struct
976 *
977 * Determines the ITR/INTRL granularities based on the maximum aggregate
978 * bandwidth according to the device's configuration during power-on.
979 */
980static void ice_get_itr_intrl_gran(struct ice_hw *hw)
981{
982 u8 max_agg_bw = FIELD_GET(GL_PWR_MODE_CTL_CAR_MAX_BW_M,
983 rd32(hw, GL_PWR_MODE_CTL));
984
985 switch (max_agg_bw) {
986 case ICE_MAX_AGG_BW_200G:
987 case ICE_MAX_AGG_BW_100G:
988 case ICE_MAX_AGG_BW_50G:
989 hw->itr_gran = ICE_ITR_GRAN_ABOVE_25;
990 hw->intrl_gran = ICE_INTRL_GRAN_ABOVE_25;
991 break;
992 case ICE_MAX_AGG_BW_25G:
993 hw->itr_gran = ICE_ITR_GRAN_MAX_25;
994 hw->intrl_gran = ICE_INTRL_GRAN_MAX_25;
995 break;
996 }
997}
998
999/**
1000 * ice_init_hw - main hardware initialization routine
1001 * @hw: pointer to the hardware structure
1002 */
1003int ice_init_hw(struct ice_hw *hw)
1004{
1005 struct ice_aqc_get_phy_caps_data *pcaps __free(kfree) = NULL;
1006 void *mac_buf __free(kfree) = NULL;
1007 u16 mac_buf_len;
1008 int status;
1009
1010 /* Set MAC type based on DeviceID */
1011 status = ice_set_mac_type(hw);
1012 if (status)
1013 return status;
1014
1015 hw->pf_id = FIELD_GET(PF_FUNC_RID_FUNC_NUM_M, rd32(hw, PF_FUNC_RID));
1016
1017 status = ice_reset(hw, ICE_RESET_PFR);
1018 if (status)
1019 return status;
1020
1021 ice_get_itr_intrl_gran(hw);
1022
1023 status = ice_create_all_ctrlq(hw);
1024 if (status)
1025 goto err_unroll_cqinit;
1026
1027 status = ice_fwlog_init(hw);
1028 if (status)
1029 ice_debug(hw, ICE_DBG_FW_LOG, "Error initializing FW logging: %d\n",
1030 status);
1031
1032 status = ice_clear_pf_cfg(hw);
1033 if (status)
1034 goto err_unroll_cqinit;
1035
1036 /* Set bit to enable Flow Director filters */
1037 wr32(hw, PFQF_FD_ENA, PFQF_FD_ENA_FD_ENA_M);
1038 INIT_LIST_HEAD(&hw->fdir_list_head);
1039
1040 ice_clear_pxe_mode(hw);
1041
1042 status = ice_init_nvm(hw);
1043 if (status)
1044 goto err_unroll_cqinit;
1045
1046 status = ice_get_caps(hw);
1047 if (status)
1048 goto err_unroll_cqinit;
1049
1050 if (!hw->port_info)
1051 hw->port_info = devm_kzalloc(ice_hw_to_dev(hw),
1052 sizeof(*hw->port_info),
1053 GFP_KERNEL);
1054 if (!hw->port_info) {
1055 status = -ENOMEM;
1056 goto err_unroll_cqinit;
1057 }
1058
1059 /* set the back pointer to HW */
1060 hw->port_info->hw = hw;
1061
1062 /* Initialize port_info struct with switch configuration data */
1063 status = ice_get_initial_sw_cfg(hw);
1064 if (status)
1065 goto err_unroll_alloc;
1066
1067 hw->evb_veb = true;
1068
1069 /* init xarray for identifying scheduling nodes uniquely */
1070 xa_init_flags(&hw->port_info->sched_node_ids, XA_FLAGS_ALLOC);
1071
1072 /* Query the allocated resources for Tx scheduler */
1073 status = ice_sched_query_res_alloc(hw);
1074 if (status) {
1075 ice_debug(hw, ICE_DBG_SCHED, "Failed to get scheduler allocated resources\n");
1076 goto err_unroll_alloc;
1077 }
1078 ice_sched_get_psm_clk_freq(hw);
1079
1080 /* Initialize port_info struct with scheduler data */
1081 status = ice_sched_init_port(hw->port_info);
1082 if (status)
1083 goto err_unroll_sched;
1084
1085 pcaps = kzalloc(sizeof(*pcaps), GFP_KERNEL);
1086 if (!pcaps) {
1087 status = -ENOMEM;
1088 goto err_unroll_sched;
1089 }
1090
1091 /* Initialize port_info struct with PHY capabilities */
1092 status = ice_aq_get_phy_caps(hw->port_info, false,
1093 ICE_AQC_REPORT_TOPO_CAP_MEDIA, pcaps,
1094 NULL);
1095 if (status)
1096 dev_warn(ice_hw_to_dev(hw), "Get PHY capabilities failed status = %d, continuing anyway\n",
1097 status);
1098
1099 /* Initialize port_info struct with link information */
1100 status = ice_aq_get_link_info(hw->port_info, false, NULL, NULL);
1101 if (status)
1102 goto err_unroll_sched;
1103
1104 /* need a valid SW entry point to build a Tx tree */
1105 if (!hw->sw_entry_point_layer) {
1106 ice_debug(hw, ICE_DBG_SCHED, "invalid sw entry point\n");
1107 status = -EIO;
1108 goto err_unroll_sched;
1109 }
1110 INIT_LIST_HEAD(&hw->agg_list);
1111 /* Initialize max burst size */
1112 if (!hw->max_burst_size)
1113 ice_cfg_rl_burst_size(hw, ICE_SCHED_DFLT_BURST_SIZE);
1114
1115 status = ice_init_fltr_mgmt_struct(hw);
1116 if (status)
1117 goto err_unroll_sched;
1118
1119 /* Get MAC information */
1120 /* A single port can report up to two (LAN and WoL) addresses */
1121 mac_buf = kcalloc(2, sizeof(struct ice_aqc_manage_mac_read_resp),
1122 GFP_KERNEL);
1123 if (!mac_buf) {
1124 status = -ENOMEM;
1125 goto err_unroll_fltr_mgmt_struct;
1126 }
1127
1128 mac_buf_len = 2 * sizeof(struct ice_aqc_manage_mac_read_resp);
1129 status = ice_aq_manage_mac_read(hw, mac_buf, mac_buf_len, NULL);
1130
1131 if (status)
1132 goto err_unroll_fltr_mgmt_struct;
1133 /* enable jumbo frame support at MAC level */
1134 status = ice_aq_set_mac_cfg(hw, ICE_AQ_SET_MAC_FRAME_SIZE_MAX, NULL);
1135 if (status)
1136 goto err_unroll_fltr_mgmt_struct;
1137 /* Obtain counter base index which would be used by flow director */
1138 status = ice_alloc_fd_res_cntr(hw, &hw->fd_ctr_base);
1139 if (status)
1140 goto err_unroll_fltr_mgmt_struct;
1141 status = ice_init_hw_tbls(hw);
1142 if (status)
1143 goto err_unroll_fltr_mgmt_struct;
1144 mutex_init(&hw->tnl_lock);
1145 return 0;
1146
1147err_unroll_fltr_mgmt_struct:
1148 ice_cleanup_fltr_mgmt_struct(hw);
1149err_unroll_sched:
1150 ice_sched_cleanup_all(hw);
1151err_unroll_alloc:
1152 devm_kfree(ice_hw_to_dev(hw), hw->port_info);
1153err_unroll_cqinit:
1154 ice_destroy_all_ctrlq(hw);
1155 return status;
1156}
1157
1158/**
1159 * ice_deinit_hw - unroll initialization operations done by ice_init_hw
1160 * @hw: pointer to the hardware structure
1161 *
1162 * This should be called only during nominal operation, not as a result of
1163 * ice_init_hw() failing since ice_init_hw() will take care of unrolling
1164 * applicable initializations if it fails for any reason.
1165 */
1166void ice_deinit_hw(struct ice_hw *hw)
1167{
1168 ice_free_fd_res_cntr(hw, hw->fd_ctr_base);
1169 ice_cleanup_fltr_mgmt_struct(hw);
1170
1171 ice_sched_cleanup_all(hw);
1172 ice_sched_clear_agg(hw);
1173 ice_free_seg(hw);
1174 ice_free_hw_tbls(hw);
1175 mutex_destroy(&hw->tnl_lock);
1176
1177 ice_fwlog_deinit(hw);
1178 ice_destroy_all_ctrlq(hw);
1179
1180 /* Clear VSI contexts if not already cleared */
1181 ice_clear_all_vsi_ctx(hw);
1182}
1183
1184/**
1185 * ice_check_reset - Check to see if a global reset is complete
1186 * @hw: pointer to the hardware structure
1187 */
1188int ice_check_reset(struct ice_hw *hw)
1189{
1190 u32 cnt, reg = 0, grst_timeout, uld_mask;
1191
1192 /* Poll for Device Active state in case a recent CORER, GLOBR,
1193 * or EMPR has occurred. The grst delay value is in 100ms units.
1194 * Add 1sec for outstanding AQ commands that can take a long time.
1195 */
1196 grst_timeout = FIELD_GET(GLGEN_RSTCTL_GRSTDEL_M,
1197 rd32(hw, GLGEN_RSTCTL)) + 10;
1198
1199 for (cnt = 0; cnt < grst_timeout; cnt++) {
1200 mdelay(100);
1201 reg = rd32(hw, GLGEN_RSTAT);
1202 if (!(reg & GLGEN_RSTAT_DEVSTATE_M))
1203 break;
1204 }
1205
1206 if (cnt == grst_timeout) {
1207 ice_debug(hw, ICE_DBG_INIT, "Global reset polling failed to complete.\n");
1208 return -EIO;
1209 }
1210
1211#define ICE_RESET_DONE_MASK (GLNVM_ULD_PCIER_DONE_M |\
1212 GLNVM_ULD_PCIER_DONE_1_M |\
1213 GLNVM_ULD_CORER_DONE_M |\
1214 GLNVM_ULD_GLOBR_DONE_M |\
1215 GLNVM_ULD_POR_DONE_M |\
1216 GLNVM_ULD_POR_DONE_1_M |\
1217 GLNVM_ULD_PCIER_DONE_2_M)
1218
1219 uld_mask = ICE_RESET_DONE_MASK | (hw->func_caps.common_cap.rdma ?
1220 GLNVM_ULD_PE_DONE_M : 0);
1221
1222 /* Device is Active; check Global Reset processes are done */
1223 for (cnt = 0; cnt < ICE_PF_RESET_WAIT_COUNT; cnt++) {
1224 reg = rd32(hw, GLNVM_ULD) & uld_mask;
1225 if (reg == uld_mask) {
1226 ice_debug(hw, ICE_DBG_INIT, "Global reset processes done. %d\n", cnt);
1227 break;
1228 }
1229 mdelay(10);
1230 }
1231
1232 if (cnt == ICE_PF_RESET_WAIT_COUNT) {
1233 ice_debug(hw, ICE_DBG_INIT, "Wait for Reset Done timed out. GLNVM_ULD = 0x%x\n",
1234 reg);
1235 return -EIO;
1236 }
1237
1238 return 0;
1239}
1240
1241/**
1242 * ice_pf_reset - Reset the PF
1243 * @hw: pointer to the hardware structure
1244 *
1245 * If a global reset has been triggered, this function checks
1246 * for its completion and then issues the PF reset
1247 */
1248static int ice_pf_reset(struct ice_hw *hw)
1249{
1250 u32 cnt, reg;
1251
1252 /* If at function entry a global reset was already in progress, i.e.
1253 * state is not 'device active' or any of the reset done bits are not
1254 * set in GLNVM_ULD, there is no need for a PF Reset; poll until the
1255 * global reset is done.
1256 */
1257 if ((rd32(hw, GLGEN_RSTAT) & GLGEN_RSTAT_DEVSTATE_M) ||
1258 (rd32(hw, GLNVM_ULD) & ICE_RESET_DONE_MASK) ^ ICE_RESET_DONE_MASK) {
1259 /* poll on global reset currently in progress until done */
1260 if (ice_check_reset(hw))
1261 return -EIO;
1262
1263 return 0;
1264 }
1265
1266 /* Reset the PF */
1267 reg = rd32(hw, PFGEN_CTRL);
1268
1269 wr32(hw, PFGEN_CTRL, (reg | PFGEN_CTRL_PFSWR_M));
1270
1271 /* Wait for the PFR to complete. The wait time is the global config lock
1272 * timeout plus the PFR timeout which will account for a possible reset
1273 * that is occurring during a download package operation.
1274 */
1275 for (cnt = 0; cnt < ICE_GLOBAL_CFG_LOCK_TIMEOUT +
1276 ICE_PF_RESET_WAIT_COUNT; cnt++) {
1277 reg = rd32(hw, PFGEN_CTRL);
1278 if (!(reg & PFGEN_CTRL_PFSWR_M))
1279 break;
1280
1281 mdelay(1);
1282 }
1283
1284 if (cnt == ICE_PF_RESET_WAIT_COUNT) {
1285 ice_debug(hw, ICE_DBG_INIT, "PF reset polling failed to complete.\n");
1286 return -EIO;
1287 }
1288
1289 return 0;
1290}
1291
1292/**
1293 * ice_reset - Perform different types of reset
1294 * @hw: pointer to the hardware structure
1295 * @req: reset request
1296 *
1297 * This function triggers a reset as specified by the req parameter.
1298 *
1299 * Note:
1300 * If anything other than a PF reset is triggered, PXE mode is restored.
1301 * This has to be cleared using ice_clear_pxe_mode again, once the AQ
1302 * interface has been restored in the rebuild flow.
1303 */
1304int ice_reset(struct ice_hw *hw, enum ice_reset_req req)
1305{
1306 u32 val = 0;
1307
1308 switch (req) {
1309 case ICE_RESET_PFR:
1310 return ice_pf_reset(hw);
1311 case ICE_RESET_CORER:
1312 ice_debug(hw, ICE_DBG_INIT, "CoreR requested\n");
1313 val = GLGEN_RTRIG_CORER_M;
1314 break;
1315 case ICE_RESET_GLOBR:
1316 ice_debug(hw, ICE_DBG_INIT, "GlobalR requested\n");
1317 val = GLGEN_RTRIG_GLOBR_M;
1318 break;
1319 default:
1320 return -EINVAL;
1321 }
1322
1323 val |= rd32(hw, GLGEN_RTRIG);
1324 wr32(hw, GLGEN_RTRIG, val);
1325 ice_flush(hw);
1326
1327 /* wait for the FW to be ready */
1328 return ice_check_reset(hw);
1329}
1330
1331/**
1332 * ice_copy_rxq_ctx_to_hw
1333 * @hw: pointer to the hardware structure
1334 * @ice_rxq_ctx: pointer to the rxq context
1335 * @rxq_index: the index of the Rx queue
1336 *
1337 * Copies rxq context from dense structure to HW register space
1338 */
1339static int
1340ice_copy_rxq_ctx_to_hw(struct ice_hw *hw, u8 *ice_rxq_ctx, u32 rxq_index)
1341{
1342 u8 i;
1343
1344 if (!ice_rxq_ctx)
1345 return -EINVAL;
1346
1347 if (rxq_index > QRX_CTRL_MAX_INDEX)
1348 return -EINVAL;
1349
1350 /* Copy each dword separately to HW */
1351 for (i = 0; i < ICE_RXQ_CTX_SIZE_DWORDS; i++) {
1352 wr32(hw, QRX_CONTEXT(i, rxq_index),
1353 *((u32 *)(ice_rxq_ctx + (i * sizeof(u32)))));
1354
1355 ice_debug(hw, ICE_DBG_QCTX, "qrxdata[%d]: %08X\n", i,
1356 *((u32 *)(ice_rxq_ctx + (i * sizeof(u32)))));
1357 }
1358
1359 return 0;
1360}
1361
1362/* LAN Rx Queue Context */
1363static const struct ice_ctx_ele ice_rlan_ctx_info[] = {
1364 /* Field Width LSB */
1365 ICE_CTX_STORE(ice_rlan_ctx, head, 13, 0),
1366 ICE_CTX_STORE(ice_rlan_ctx, cpuid, 8, 13),
1367 ICE_CTX_STORE(ice_rlan_ctx, base, 57, 32),
1368 ICE_CTX_STORE(ice_rlan_ctx, qlen, 13, 89),
1369 ICE_CTX_STORE(ice_rlan_ctx, dbuf, 7, 102),
1370 ICE_CTX_STORE(ice_rlan_ctx, hbuf, 5, 109),
1371 ICE_CTX_STORE(ice_rlan_ctx, dtype, 2, 114),
1372 ICE_CTX_STORE(ice_rlan_ctx, dsize, 1, 116),
1373 ICE_CTX_STORE(ice_rlan_ctx, crcstrip, 1, 117),
1374 ICE_CTX_STORE(ice_rlan_ctx, l2tsel, 1, 119),
1375 ICE_CTX_STORE(ice_rlan_ctx, hsplit_0, 4, 120),
1376 ICE_CTX_STORE(ice_rlan_ctx, hsplit_1, 2, 124),
1377 ICE_CTX_STORE(ice_rlan_ctx, showiv, 1, 127),
1378 ICE_CTX_STORE(ice_rlan_ctx, rxmax, 14, 174),
1379 ICE_CTX_STORE(ice_rlan_ctx, tphrdesc_ena, 1, 193),
1380 ICE_CTX_STORE(ice_rlan_ctx, tphwdesc_ena, 1, 194),
1381 ICE_CTX_STORE(ice_rlan_ctx, tphdata_ena, 1, 195),
1382 ICE_CTX_STORE(ice_rlan_ctx, tphhead_ena, 1, 196),
1383 ICE_CTX_STORE(ice_rlan_ctx, lrxqthresh, 3, 198),
1384 ICE_CTX_STORE(ice_rlan_ctx, prefena, 1, 201),
1385 { 0 }
1386};
1387
1388/**
1389 * ice_write_rxq_ctx
1390 * @hw: pointer to the hardware structure
1391 * @rlan_ctx: pointer to the rxq context
1392 * @rxq_index: the index of the Rx queue
1393 *
1394 * Converts rxq context from sparse to dense structure and then writes
1395 * it to HW register space and enables the hardware to prefetch descriptors
1396 * instead of only fetching them on demand
1397 */
1398int ice_write_rxq_ctx(struct ice_hw *hw, struct ice_rlan_ctx *rlan_ctx,
1399 u32 rxq_index)
1400{
1401 u8 ctx_buf[ICE_RXQ_CTX_SZ] = { 0 };
1402
1403 if (!rlan_ctx)
1404 return -EINVAL;
1405
1406 rlan_ctx->prefena = 1;
1407
1408 ice_set_ctx(hw, (u8 *)rlan_ctx, ctx_buf, ice_rlan_ctx_info);
1409 return ice_copy_rxq_ctx_to_hw(hw, ctx_buf, rxq_index);
1410}
1411
1412/* LAN Tx Queue Context */
1413const struct ice_ctx_ele ice_tlan_ctx_info[] = {
1414 /* Field Width LSB */
1415 ICE_CTX_STORE(ice_tlan_ctx, base, 57, 0),
1416 ICE_CTX_STORE(ice_tlan_ctx, port_num, 3, 57),
1417 ICE_CTX_STORE(ice_tlan_ctx, cgd_num, 5, 60),
1418 ICE_CTX_STORE(ice_tlan_ctx, pf_num, 3, 65),
1419 ICE_CTX_STORE(ice_tlan_ctx, vmvf_num, 10, 68),
1420 ICE_CTX_STORE(ice_tlan_ctx, vmvf_type, 2, 78),
1421 ICE_CTX_STORE(ice_tlan_ctx, src_vsi, 10, 80),
1422 ICE_CTX_STORE(ice_tlan_ctx, tsyn_ena, 1, 90),
1423 ICE_CTX_STORE(ice_tlan_ctx, internal_usage_flag, 1, 91),
1424 ICE_CTX_STORE(ice_tlan_ctx, alt_vlan, 1, 92),
1425 ICE_CTX_STORE(ice_tlan_ctx, cpuid, 8, 93),
1426 ICE_CTX_STORE(ice_tlan_ctx, wb_mode, 1, 101),
1427 ICE_CTX_STORE(ice_tlan_ctx, tphrd_desc, 1, 102),
1428 ICE_CTX_STORE(ice_tlan_ctx, tphrd, 1, 103),
1429 ICE_CTX_STORE(ice_tlan_ctx, tphwr_desc, 1, 104),
1430 ICE_CTX_STORE(ice_tlan_ctx, cmpq_id, 9, 105),
1431 ICE_CTX_STORE(ice_tlan_ctx, qnum_in_func, 14, 114),
1432 ICE_CTX_STORE(ice_tlan_ctx, itr_notification_mode, 1, 128),
1433 ICE_CTX_STORE(ice_tlan_ctx, adjust_prof_id, 6, 129),
1434 ICE_CTX_STORE(ice_tlan_ctx, qlen, 13, 135),
1435 ICE_CTX_STORE(ice_tlan_ctx, quanta_prof_idx, 4, 148),
1436 ICE_CTX_STORE(ice_tlan_ctx, tso_ena, 1, 152),
1437 ICE_CTX_STORE(ice_tlan_ctx, tso_qnum, 11, 153),
1438 ICE_CTX_STORE(ice_tlan_ctx, legacy_int, 1, 164),
1439 ICE_CTX_STORE(ice_tlan_ctx, drop_ena, 1, 165),
1440 ICE_CTX_STORE(ice_tlan_ctx, cache_prof_idx, 2, 166),
1441 ICE_CTX_STORE(ice_tlan_ctx, pkt_shaper_prof_idx, 3, 168),
1442 ICE_CTX_STORE(ice_tlan_ctx, int_q_state, 122, 171),
1443 { 0 }
1444};
1445
1446/* Sideband Queue command wrappers */
1447
1448/**
1449 * ice_sbq_send_cmd - send Sideband Queue command to Sideband Queue
1450 * @hw: pointer to the HW struct
1451 * @desc: descriptor describing the command
1452 * @buf: buffer to use for indirect commands (NULL for direct commands)
1453 * @buf_size: size of buffer for indirect commands (0 for direct commands)
1454 * @cd: pointer to command details structure
1455 */
1456static int
1457ice_sbq_send_cmd(struct ice_hw *hw, struct ice_sbq_cmd_desc *desc,
1458 void *buf, u16 buf_size, struct ice_sq_cd *cd)
1459{
1460 return ice_sq_send_cmd(hw, ice_get_sbq(hw),
1461 (struct ice_aq_desc *)desc, buf, buf_size, cd);
1462}
1463
1464/**
1465 * ice_sbq_rw_reg - Fill Sideband Queue command
1466 * @hw: pointer to the HW struct
1467 * @in: message info to be filled in descriptor
1468 */
1469int ice_sbq_rw_reg(struct ice_hw *hw, struct ice_sbq_msg_input *in)
1470{
1471 struct ice_sbq_cmd_desc desc = {0};
1472 struct ice_sbq_msg_req msg = {0};
1473 u16 msg_len;
1474 int status;
1475
1476 msg_len = sizeof(msg);
1477
1478 msg.dest_dev = in->dest_dev;
1479 msg.opcode = in->opcode;
1480 msg.flags = ICE_SBQ_MSG_FLAGS;
1481 msg.sbe_fbe = ICE_SBQ_MSG_SBE_FBE;
1482 msg.msg_addr_low = cpu_to_le16(in->msg_addr_low);
1483 msg.msg_addr_high = cpu_to_le32(in->msg_addr_high);
1484
1485 if (in->opcode)
1486 msg.data = cpu_to_le32(in->data);
1487 else
1488 /* data read comes back in completion, so shorten the struct by
1489 * sizeof(msg.data)
1490 */
1491 msg_len -= sizeof(msg.data);
1492
1493 desc.flags = cpu_to_le16(ICE_AQ_FLAG_RD);
1494 desc.opcode = cpu_to_le16(ice_sbq_opc_neigh_dev_req);
1495 desc.param0.cmd_len = cpu_to_le16(msg_len);
1496 status = ice_sbq_send_cmd(hw, &desc, &msg, msg_len, NULL);
1497 if (!status && !in->opcode)
1498 in->data = le32_to_cpu
1499 (((struct ice_sbq_msg_cmpl *)&msg)->data);
1500 return status;
1501}
1502
1503/* FW Admin Queue command wrappers */
1504
1505/* Software lock/mutex that is meant to be held while the Global Config Lock
1506 * in firmware is acquired by the software to prevent most (but not all) types
1507 * of AQ commands from being sent to FW
1508 */
1509DEFINE_MUTEX(ice_global_cfg_lock_sw);
1510
1511/**
1512 * ice_should_retry_sq_send_cmd
1513 * @opcode: AQ opcode
1514 *
1515 * Decide if we should retry the send command routine for the ATQ, depending
1516 * on the opcode.
1517 */
1518static bool ice_should_retry_sq_send_cmd(u16 opcode)
1519{
1520 switch (opcode) {
1521 case ice_aqc_opc_get_link_topo:
1522 case ice_aqc_opc_lldp_stop:
1523 case ice_aqc_opc_lldp_start:
1524 case ice_aqc_opc_lldp_filter_ctrl:
1525 return true;
1526 }
1527
1528 return false;
1529}
1530
1531/**
1532 * ice_sq_send_cmd_retry - send command to Control Queue (ATQ)
1533 * @hw: pointer to the HW struct
1534 * @cq: pointer to the specific Control queue
1535 * @desc: prefilled descriptor describing the command
1536 * @buf: buffer to use for indirect commands (or NULL for direct commands)
1537 * @buf_size: size of buffer for indirect commands (or 0 for direct commands)
1538 * @cd: pointer to command details structure
1539 *
1540 * Retry sending the FW Admin Queue command, multiple times, to the FW Admin
1541 * Queue if the EBUSY AQ error is returned.
1542 */
1543static int
1544ice_sq_send_cmd_retry(struct ice_hw *hw, struct ice_ctl_q_info *cq,
1545 struct ice_aq_desc *desc, void *buf, u16 buf_size,
1546 struct ice_sq_cd *cd)
1547{
1548 struct ice_aq_desc desc_cpy;
1549 bool is_cmd_for_retry;
1550 u8 idx = 0;
1551 u16 opcode;
1552 int status;
1553
1554 opcode = le16_to_cpu(desc->opcode);
1555 is_cmd_for_retry = ice_should_retry_sq_send_cmd(opcode);
1556 memset(&desc_cpy, 0, sizeof(desc_cpy));
1557
1558 if (is_cmd_for_retry) {
1559 /* All retryable cmds are direct, without buf. */
1560 WARN_ON(buf);
1561
1562 memcpy(&desc_cpy, desc, sizeof(desc_cpy));
1563 }
1564
1565 do {
1566 status = ice_sq_send_cmd(hw, cq, desc, buf, buf_size, cd);
1567
1568 if (!is_cmd_for_retry || !status ||
1569 hw->adminq.sq_last_status != ICE_AQ_RC_EBUSY)
1570 break;
1571
1572 memcpy(desc, &desc_cpy, sizeof(desc_cpy));
1573
1574 msleep(ICE_SQ_SEND_DELAY_TIME_MS);
1575
1576 } while (++idx < ICE_SQ_SEND_MAX_EXECUTE);
1577
1578 return status;
1579}
1580
1581/**
1582 * ice_aq_send_cmd - send FW Admin Queue command to FW Admin Queue
1583 * @hw: pointer to the HW struct
1584 * @desc: descriptor describing the command
1585 * @buf: buffer to use for indirect commands (NULL for direct commands)
1586 * @buf_size: size of buffer for indirect commands (0 for direct commands)
1587 * @cd: pointer to command details structure
1588 *
1589 * Helper function to send FW Admin Queue commands to the FW Admin Queue.
1590 */
1591int
1592ice_aq_send_cmd(struct ice_hw *hw, struct ice_aq_desc *desc, void *buf,
1593 u16 buf_size, struct ice_sq_cd *cd)
1594{
1595 struct ice_aqc_req_res *cmd = &desc->params.res_owner;
1596 bool lock_acquired = false;
1597 int status;
1598
1599 /* When a package download is in process (i.e. when the firmware's
1600 * Global Configuration Lock resource is held), only the Download
1601 * Package, Get Version, Get Package Info List, Upload Section,
1602 * Update Package, Set Port Parameters, Get/Set VLAN Mode Parameters,
1603 * Add Recipe, Set Recipes to Profile Association, Get Recipe, and Get
1604 * Recipes to Profile Association, and Release Resource (with resource
1605 * ID set to Global Config Lock) AdminQ commands are allowed; all others
1606 * must block until the package download completes and the Global Config
1607 * Lock is released. See also ice_acquire_global_cfg_lock().
1608 */
1609 switch (le16_to_cpu(desc->opcode)) {
1610 case ice_aqc_opc_download_pkg:
1611 case ice_aqc_opc_get_pkg_info_list:
1612 case ice_aqc_opc_get_ver:
1613 case ice_aqc_opc_upload_section:
1614 case ice_aqc_opc_update_pkg:
1615 case ice_aqc_opc_set_port_params:
1616 case ice_aqc_opc_get_vlan_mode_parameters:
1617 case ice_aqc_opc_set_vlan_mode_parameters:
1618 case ice_aqc_opc_add_recipe:
1619 case ice_aqc_opc_recipe_to_profile:
1620 case ice_aqc_opc_get_recipe:
1621 case ice_aqc_opc_get_recipe_to_profile:
1622 break;
1623 case ice_aqc_opc_release_res:
1624 if (le16_to_cpu(cmd->res_id) == ICE_AQC_RES_ID_GLBL_LOCK)
1625 break;
1626 fallthrough;
1627 default:
1628 mutex_lock(&ice_global_cfg_lock_sw);
1629 lock_acquired = true;
1630 break;
1631 }
1632
1633 status = ice_sq_send_cmd_retry(hw, &hw->adminq, desc, buf, buf_size, cd);
1634 if (lock_acquired)
1635 mutex_unlock(&ice_global_cfg_lock_sw);
1636
1637 return status;
1638}
1639
1640/**
1641 * ice_aq_get_fw_ver
1642 * @hw: pointer to the HW struct
1643 * @cd: pointer to command details structure or NULL
1644 *
1645 * Get the firmware version (0x0001) from the admin queue commands
1646 */
1647int ice_aq_get_fw_ver(struct ice_hw *hw, struct ice_sq_cd *cd)
1648{
1649 struct ice_aqc_get_ver *resp;
1650 struct ice_aq_desc desc;
1651 int status;
1652
1653 resp = &desc.params.get_ver;
1654
1655 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_ver);
1656
1657 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1658
1659 if (!status) {
1660 hw->fw_branch = resp->fw_branch;
1661 hw->fw_maj_ver = resp->fw_major;
1662 hw->fw_min_ver = resp->fw_minor;
1663 hw->fw_patch = resp->fw_patch;
1664 hw->fw_build = le32_to_cpu(resp->fw_build);
1665 hw->api_branch = resp->api_branch;
1666 hw->api_maj_ver = resp->api_major;
1667 hw->api_min_ver = resp->api_minor;
1668 hw->api_patch = resp->api_patch;
1669 }
1670
1671 return status;
1672}
1673
1674/**
1675 * ice_aq_send_driver_ver
1676 * @hw: pointer to the HW struct
1677 * @dv: driver's major, minor version
1678 * @cd: pointer to command details structure or NULL
1679 *
1680 * Send the driver version (0x0002) to the firmware
1681 */
1682int
1683ice_aq_send_driver_ver(struct ice_hw *hw, struct ice_driver_ver *dv,
1684 struct ice_sq_cd *cd)
1685{
1686 struct ice_aqc_driver_ver *cmd;
1687 struct ice_aq_desc desc;
1688 u16 len;
1689
1690 cmd = &desc.params.driver_ver;
1691
1692 if (!dv)
1693 return -EINVAL;
1694
1695 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_driver_ver);
1696
1697 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
1698 cmd->major_ver = dv->major_ver;
1699 cmd->minor_ver = dv->minor_ver;
1700 cmd->build_ver = dv->build_ver;
1701 cmd->subbuild_ver = dv->subbuild_ver;
1702
1703 len = 0;
1704 while (len < sizeof(dv->driver_string) &&
1705 isascii(dv->driver_string[len]) && dv->driver_string[len])
1706 len++;
1707
1708 return ice_aq_send_cmd(hw, &desc, dv->driver_string, len, cd);
1709}
1710
1711/**
1712 * ice_aq_q_shutdown
1713 * @hw: pointer to the HW struct
1714 * @unloading: is the driver unloading itself
1715 *
1716 * Tell the Firmware that we're shutting down the AdminQ and whether
1717 * or not the driver is unloading as well (0x0003).
1718 */
1719int ice_aq_q_shutdown(struct ice_hw *hw, bool unloading)
1720{
1721 struct ice_aqc_q_shutdown *cmd;
1722 struct ice_aq_desc desc;
1723
1724 cmd = &desc.params.q_shutdown;
1725
1726 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_q_shutdown);
1727
1728 if (unloading)
1729 cmd->driver_unloading = ICE_AQC_DRIVER_UNLOADING;
1730
1731 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
1732}
1733
1734/**
1735 * ice_aq_req_res
1736 * @hw: pointer to the HW struct
1737 * @res: resource ID
1738 * @access: access type
1739 * @sdp_number: resource number
1740 * @timeout: the maximum time in ms that the driver may hold the resource
1741 * @cd: pointer to command details structure or NULL
1742 *
1743 * Requests common resource using the admin queue commands (0x0008).
1744 * When attempting to acquire the Global Config Lock, the driver can
1745 * learn of three states:
1746 * 1) 0 - acquired lock, and can perform download package
1747 * 2) -EIO - did not get lock, driver should fail to load
1748 * 3) -EALREADY - did not get lock, but another driver has
1749 * successfully downloaded the package; the driver does
1750 * not have to download the package and can continue
1751 * loading
1752 *
1753 * Note that if the caller is in an acquire lock, perform action, release lock
1754 * phase of operation, it is possible that the FW may detect a timeout and issue
1755 * a CORER. In this case, the driver will receive a CORER interrupt and will
1756 * have to determine its cause. The calling thread that is handling this flow
1757 * will likely get an error propagated back to it indicating the Download
1758 * Package, Update Package or the Release Resource AQ commands timed out.
1759 */
1760static int
1761ice_aq_req_res(struct ice_hw *hw, enum ice_aq_res_ids res,
1762 enum ice_aq_res_access_type access, u8 sdp_number, u32 *timeout,
1763 struct ice_sq_cd *cd)
1764{
1765 struct ice_aqc_req_res *cmd_resp;
1766 struct ice_aq_desc desc;
1767 int status;
1768
1769 cmd_resp = &desc.params.res_owner;
1770
1771 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_req_res);
1772
1773 cmd_resp->res_id = cpu_to_le16(res);
1774 cmd_resp->access_type = cpu_to_le16(access);
1775 cmd_resp->res_number = cpu_to_le32(sdp_number);
1776 cmd_resp->timeout = cpu_to_le32(*timeout);
1777 *timeout = 0;
1778
1779 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1780
1781 /* The completion specifies the maximum time in ms that the driver
1782 * may hold the resource in the Timeout field.
1783 */
1784
1785 /* Global config lock response utilizes an additional status field.
1786 *
1787 * If the Global config lock resource is held by some other driver, the
1788 * command completes with ICE_AQ_RES_GLBL_IN_PROG in the status field
1789 * and the timeout field indicates the maximum time the current owner
1790 * of the resource has to free it.
1791 */
1792 if (res == ICE_GLOBAL_CFG_LOCK_RES_ID) {
1793 if (le16_to_cpu(cmd_resp->status) == ICE_AQ_RES_GLBL_SUCCESS) {
1794 *timeout = le32_to_cpu(cmd_resp->timeout);
1795 return 0;
1796 } else if (le16_to_cpu(cmd_resp->status) ==
1797 ICE_AQ_RES_GLBL_IN_PROG) {
1798 *timeout = le32_to_cpu(cmd_resp->timeout);
1799 return -EIO;
1800 } else if (le16_to_cpu(cmd_resp->status) ==
1801 ICE_AQ_RES_GLBL_DONE) {
1802 return -EALREADY;
1803 }
1804
1805 /* invalid FW response, force a timeout immediately */
1806 *timeout = 0;
1807 return -EIO;
1808 }
1809
1810 /* If the resource is held by some other driver, the command completes
1811 * with a busy return value and the timeout field indicates the maximum
1812 * time the current owner of the resource has to free it.
1813 */
1814 if (!status || hw->adminq.sq_last_status == ICE_AQ_RC_EBUSY)
1815 *timeout = le32_to_cpu(cmd_resp->timeout);
1816
1817 return status;
1818}
1819
1820/**
1821 * ice_aq_release_res
1822 * @hw: pointer to the HW struct
1823 * @res: resource ID
1824 * @sdp_number: resource number
1825 * @cd: pointer to command details structure or NULL
1826 *
1827 * release common resource using the admin queue commands (0x0009)
1828 */
1829static int
1830ice_aq_release_res(struct ice_hw *hw, enum ice_aq_res_ids res, u8 sdp_number,
1831 struct ice_sq_cd *cd)
1832{
1833 struct ice_aqc_req_res *cmd;
1834 struct ice_aq_desc desc;
1835
1836 cmd = &desc.params.res_owner;
1837
1838 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_release_res);
1839
1840 cmd->res_id = cpu_to_le16(res);
1841 cmd->res_number = cpu_to_le32(sdp_number);
1842
1843 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
1844}
1845
1846/**
1847 * ice_acquire_res
1848 * @hw: pointer to the HW structure
1849 * @res: resource ID
1850 * @access: access type (read or write)
1851 * @timeout: timeout in milliseconds
1852 *
1853 * This function will attempt to acquire the ownership of a resource.
1854 */
1855int
1856ice_acquire_res(struct ice_hw *hw, enum ice_aq_res_ids res,
1857 enum ice_aq_res_access_type access, u32 timeout)
1858{
1859#define ICE_RES_POLLING_DELAY_MS 10
1860 u32 delay = ICE_RES_POLLING_DELAY_MS;
1861 u32 time_left = timeout;
1862 int status;
1863
1864 status = ice_aq_req_res(hw, res, access, 0, &time_left, NULL);
1865
1866 /* A return code of -EALREADY means that another driver has
1867 * previously acquired the resource and performed any necessary updates;
1868 * in this case the caller does not obtain the resource and has no
1869 * further work to do.
1870 */
1871 if (status == -EALREADY)
1872 goto ice_acquire_res_exit;
1873
1874 if (status)
1875 ice_debug(hw, ICE_DBG_RES, "resource %d acquire type %d failed.\n", res, access);
1876
1877 /* If necessary, poll until the current lock owner timeouts */
1878 timeout = time_left;
1879 while (status && timeout && time_left) {
1880 mdelay(delay);
1881 timeout = (timeout > delay) ? timeout - delay : 0;
1882 status = ice_aq_req_res(hw, res, access, 0, &time_left, NULL);
1883
1884 if (status == -EALREADY)
1885 /* lock free, but no work to do */
1886 break;
1887
1888 if (!status)
1889 /* lock acquired */
1890 break;
1891 }
1892 if (status && status != -EALREADY)
1893 ice_debug(hw, ICE_DBG_RES, "resource acquire timed out.\n");
1894
1895ice_acquire_res_exit:
1896 if (status == -EALREADY) {
1897 if (access == ICE_RES_WRITE)
1898 ice_debug(hw, ICE_DBG_RES, "resource indicates no work to do.\n");
1899 else
1900 ice_debug(hw, ICE_DBG_RES, "Warning: -EALREADY not expected\n");
1901 }
1902 return status;
1903}
1904
1905/**
1906 * ice_release_res
1907 * @hw: pointer to the HW structure
1908 * @res: resource ID
1909 *
1910 * This function will release a resource using the proper Admin Command.
1911 */
1912void ice_release_res(struct ice_hw *hw, enum ice_aq_res_ids res)
1913{
1914 unsigned long timeout;
1915 int status;
1916
1917 /* there are some rare cases when trying to release the resource
1918 * results in an admin queue timeout, so handle them correctly
1919 */
1920 timeout = jiffies + 10 * ICE_CTL_Q_SQ_CMD_TIMEOUT;
1921 do {
1922 status = ice_aq_release_res(hw, res, 0, NULL);
1923 if (status != -EIO)
1924 break;
1925 usleep_range(1000, 2000);
1926 } while (time_before(jiffies, timeout));
1927}
1928
1929/**
1930 * ice_aq_alloc_free_res - command to allocate/free resources
1931 * @hw: pointer to the HW struct
1932 * @buf: Indirect buffer to hold data parameters and response
1933 * @buf_size: size of buffer for indirect commands
1934 * @opc: pass in the command opcode
1935 *
1936 * Helper function to allocate/free resources using the admin queue commands
1937 */
1938int ice_aq_alloc_free_res(struct ice_hw *hw,
1939 struct ice_aqc_alloc_free_res_elem *buf, u16 buf_size,
1940 enum ice_adminq_opc opc)
1941{
1942 struct ice_aqc_alloc_free_res_cmd *cmd;
1943 struct ice_aq_desc desc;
1944
1945 cmd = &desc.params.sw_res_ctrl;
1946
1947 if (!buf || buf_size < flex_array_size(buf, elem, 1))
1948 return -EINVAL;
1949
1950 ice_fill_dflt_direct_cmd_desc(&desc, opc);
1951
1952 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
1953
1954 cmd->num_entries = cpu_to_le16(1);
1955
1956 return ice_aq_send_cmd(hw, &desc, buf, buf_size, NULL);
1957}
1958
1959/**
1960 * ice_alloc_hw_res - allocate resource
1961 * @hw: pointer to the HW struct
1962 * @type: type of resource
1963 * @num: number of resources to allocate
1964 * @btm: allocate from bottom
1965 * @res: pointer to array that will receive the resources
1966 */
1967int
1968ice_alloc_hw_res(struct ice_hw *hw, u16 type, u16 num, bool btm, u16 *res)
1969{
1970 struct ice_aqc_alloc_free_res_elem *buf;
1971 u16 buf_len;
1972 int status;
1973
1974 buf_len = struct_size(buf, elem, num);
1975 buf = kzalloc(buf_len, GFP_KERNEL);
1976 if (!buf)
1977 return -ENOMEM;
1978
1979 /* Prepare buffer to allocate resource. */
1980 buf->num_elems = cpu_to_le16(num);
1981 buf->res_type = cpu_to_le16(type | ICE_AQC_RES_TYPE_FLAG_DEDICATED |
1982 ICE_AQC_RES_TYPE_FLAG_IGNORE_INDEX);
1983 if (btm)
1984 buf->res_type |= cpu_to_le16(ICE_AQC_RES_TYPE_FLAG_SCAN_BOTTOM);
1985
1986 status = ice_aq_alloc_free_res(hw, buf, buf_len, ice_aqc_opc_alloc_res);
1987 if (status)
1988 goto ice_alloc_res_exit;
1989
1990 memcpy(res, buf->elem, sizeof(*buf->elem) * num);
1991
1992ice_alloc_res_exit:
1993 kfree(buf);
1994 return status;
1995}
1996
1997/**
1998 * ice_free_hw_res - free allocated HW resource
1999 * @hw: pointer to the HW struct
2000 * @type: type of resource to free
2001 * @num: number of resources
2002 * @res: pointer to array that contains the resources to free
2003 */
2004int ice_free_hw_res(struct ice_hw *hw, u16 type, u16 num, u16 *res)
2005{
2006 struct ice_aqc_alloc_free_res_elem *buf;
2007 u16 buf_len;
2008 int status;
2009
2010 buf_len = struct_size(buf, elem, num);
2011 buf = kzalloc(buf_len, GFP_KERNEL);
2012 if (!buf)
2013 return -ENOMEM;
2014
2015 /* Prepare buffer to free resource. */
2016 buf->num_elems = cpu_to_le16(num);
2017 buf->res_type = cpu_to_le16(type);
2018 memcpy(buf->elem, res, sizeof(*buf->elem) * num);
2019
2020 status = ice_aq_alloc_free_res(hw, buf, buf_len, ice_aqc_opc_free_res);
2021 if (status)
2022 ice_debug(hw, ICE_DBG_SW, "CQ CMD Buffer:\n");
2023
2024 kfree(buf);
2025 return status;
2026}
2027
2028/**
2029 * ice_get_num_per_func - determine number of resources per PF
2030 * @hw: pointer to the HW structure
2031 * @max: value to be evenly split between each PF
2032 *
2033 * Determine the number of valid functions by going through the bitmap returned
2034 * from parsing capabilities and use this to calculate the number of resources
2035 * per PF based on the max value passed in.
2036 */
2037static u32 ice_get_num_per_func(struct ice_hw *hw, u32 max)
2038{
2039 u8 funcs;
2040
2041#define ICE_CAPS_VALID_FUNCS_M 0xFF
2042 funcs = hweight8(hw->dev_caps.common_cap.valid_functions &
2043 ICE_CAPS_VALID_FUNCS_M);
2044
2045 if (!funcs)
2046 return 0;
2047
2048 return max / funcs;
2049}
2050
2051/**
2052 * ice_parse_common_caps - parse common device/function capabilities
2053 * @hw: pointer to the HW struct
2054 * @caps: pointer to common capabilities structure
2055 * @elem: the capability element to parse
2056 * @prefix: message prefix for tracing capabilities
2057 *
2058 * Given a capability element, extract relevant details into the common
2059 * capability structure.
2060 *
2061 * Returns: true if the capability matches one of the common capability ids,
2062 * false otherwise.
2063 */
2064static bool
2065ice_parse_common_caps(struct ice_hw *hw, struct ice_hw_common_caps *caps,
2066 struct ice_aqc_list_caps_elem *elem, const char *prefix)
2067{
2068 u32 logical_id = le32_to_cpu(elem->logical_id);
2069 u32 phys_id = le32_to_cpu(elem->phys_id);
2070 u32 number = le32_to_cpu(elem->number);
2071 u16 cap = le16_to_cpu(elem->cap);
2072 bool found = true;
2073
2074 switch (cap) {
2075 case ICE_AQC_CAPS_VALID_FUNCTIONS:
2076 caps->valid_functions = number;
2077 ice_debug(hw, ICE_DBG_INIT, "%s: valid_functions (bitmap) = %d\n", prefix,
2078 caps->valid_functions);
2079 break;
2080 case ICE_AQC_CAPS_SRIOV:
2081 caps->sr_iov_1_1 = (number == 1);
2082 ice_debug(hw, ICE_DBG_INIT, "%s: sr_iov_1_1 = %d\n", prefix,
2083 caps->sr_iov_1_1);
2084 break;
2085 case ICE_AQC_CAPS_DCB:
2086 caps->dcb = (number == 1);
2087 caps->active_tc_bitmap = logical_id;
2088 caps->maxtc = phys_id;
2089 ice_debug(hw, ICE_DBG_INIT, "%s: dcb = %d\n", prefix, caps->dcb);
2090 ice_debug(hw, ICE_DBG_INIT, "%s: active_tc_bitmap = %d\n", prefix,
2091 caps->active_tc_bitmap);
2092 ice_debug(hw, ICE_DBG_INIT, "%s: maxtc = %d\n", prefix, caps->maxtc);
2093 break;
2094 case ICE_AQC_CAPS_RSS:
2095 caps->rss_table_size = number;
2096 caps->rss_table_entry_width = logical_id;
2097 ice_debug(hw, ICE_DBG_INIT, "%s: rss_table_size = %d\n", prefix,
2098 caps->rss_table_size);
2099 ice_debug(hw, ICE_DBG_INIT, "%s: rss_table_entry_width = %d\n", prefix,
2100 caps->rss_table_entry_width);
2101 break;
2102 case ICE_AQC_CAPS_RXQS:
2103 caps->num_rxq = number;
2104 caps->rxq_first_id = phys_id;
2105 ice_debug(hw, ICE_DBG_INIT, "%s: num_rxq = %d\n", prefix,
2106 caps->num_rxq);
2107 ice_debug(hw, ICE_DBG_INIT, "%s: rxq_first_id = %d\n", prefix,
2108 caps->rxq_first_id);
2109 break;
2110 case ICE_AQC_CAPS_TXQS:
2111 caps->num_txq = number;
2112 caps->txq_first_id = phys_id;
2113 ice_debug(hw, ICE_DBG_INIT, "%s: num_txq = %d\n", prefix,
2114 caps->num_txq);
2115 ice_debug(hw, ICE_DBG_INIT, "%s: txq_first_id = %d\n", prefix,
2116 caps->txq_first_id);
2117 break;
2118 case ICE_AQC_CAPS_MSIX:
2119 caps->num_msix_vectors = number;
2120 caps->msix_vector_first_id = phys_id;
2121 ice_debug(hw, ICE_DBG_INIT, "%s: num_msix_vectors = %d\n", prefix,
2122 caps->num_msix_vectors);
2123 ice_debug(hw, ICE_DBG_INIT, "%s: msix_vector_first_id = %d\n", prefix,
2124 caps->msix_vector_first_id);
2125 break;
2126 case ICE_AQC_CAPS_PENDING_NVM_VER:
2127 caps->nvm_update_pending_nvm = true;
2128 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_nvm\n", prefix);
2129 break;
2130 case ICE_AQC_CAPS_PENDING_OROM_VER:
2131 caps->nvm_update_pending_orom = true;
2132 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_orom\n", prefix);
2133 break;
2134 case ICE_AQC_CAPS_PENDING_NET_VER:
2135 caps->nvm_update_pending_netlist = true;
2136 ice_debug(hw, ICE_DBG_INIT, "%s: update_pending_netlist\n", prefix);
2137 break;
2138 case ICE_AQC_CAPS_NVM_MGMT:
2139 caps->nvm_unified_update =
2140 (number & ICE_NVM_MGMT_UNIFIED_UPD_SUPPORT) ?
2141 true : false;
2142 ice_debug(hw, ICE_DBG_INIT, "%s: nvm_unified_update = %d\n", prefix,
2143 caps->nvm_unified_update);
2144 break;
2145 case ICE_AQC_CAPS_RDMA:
2146 caps->rdma = (number == 1);
2147 ice_debug(hw, ICE_DBG_INIT, "%s: rdma = %d\n", prefix, caps->rdma);
2148 break;
2149 case ICE_AQC_CAPS_MAX_MTU:
2150 caps->max_mtu = number;
2151 ice_debug(hw, ICE_DBG_INIT, "%s: max_mtu = %d\n",
2152 prefix, caps->max_mtu);
2153 break;
2154 case ICE_AQC_CAPS_PCIE_RESET_AVOIDANCE:
2155 caps->pcie_reset_avoidance = (number > 0);
2156 ice_debug(hw, ICE_DBG_INIT,
2157 "%s: pcie_reset_avoidance = %d\n", prefix,
2158 caps->pcie_reset_avoidance);
2159 break;
2160 case ICE_AQC_CAPS_POST_UPDATE_RESET_RESTRICT:
2161 caps->reset_restrict_support = (number == 1);
2162 ice_debug(hw, ICE_DBG_INIT,
2163 "%s: reset_restrict_support = %d\n", prefix,
2164 caps->reset_restrict_support);
2165 break;
2166 case ICE_AQC_CAPS_FW_LAG_SUPPORT:
2167 caps->roce_lag = !!(number & ICE_AQC_BIT_ROCEV2_LAG);
2168 ice_debug(hw, ICE_DBG_INIT, "%s: roce_lag = %u\n",
2169 prefix, caps->roce_lag);
2170 caps->sriov_lag = !!(number & ICE_AQC_BIT_SRIOV_LAG);
2171 ice_debug(hw, ICE_DBG_INIT, "%s: sriov_lag = %u\n",
2172 prefix, caps->sriov_lag);
2173 break;
2174 default:
2175 /* Not one of the recognized common capabilities */
2176 found = false;
2177 }
2178
2179 return found;
2180}
2181
2182/**
2183 * ice_recalc_port_limited_caps - Recalculate port limited capabilities
2184 * @hw: pointer to the HW structure
2185 * @caps: pointer to capabilities structure to fix
2186 *
2187 * Re-calculate the capabilities that are dependent on the number of physical
2188 * ports; i.e. some features are not supported or function differently on
2189 * devices with more than 4 ports.
2190 */
2191static void
2192ice_recalc_port_limited_caps(struct ice_hw *hw, struct ice_hw_common_caps *caps)
2193{
2194 /* This assumes device capabilities are always scanned before function
2195 * capabilities during the initialization flow.
2196 */
2197 if (hw->dev_caps.num_funcs > 4) {
2198 /* Max 4 TCs per port */
2199 caps->maxtc = 4;
2200 ice_debug(hw, ICE_DBG_INIT, "reducing maxtc to %d (based on #ports)\n",
2201 caps->maxtc);
2202 if (caps->rdma) {
2203 ice_debug(hw, ICE_DBG_INIT, "forcing RDMA off\n");
2204 caps->rdma = 0;
2205 }
2206
2207 /* print message only when processing device capabilities
2208 * during initialization.
2209 */
2210 if (caps == &hw->dev_caps.common_cap)
2211 dev_info(ice_hw_to_dev(hw), "RDMA functionality is not available with the current device configuration.\n");
2212 }
2213}
2214
2215/**
2216 * ice_parse_vf_func_caps - Parse ICE_AQC_CAPS_VF function caps
2217 * @hw: pointer to the HW struct
2218 * @func_p: pointer to function capabilities structure
2219 * @cap: pointer to the capability element to parse
2220 *
2221 * Extract function capabilities for ICE_AQC_CAPS_VF.
2222 */
2223static void
2224ice_parse_vf_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2225 struct ice_aqc_list_caps_elem *cap)
2226{
2227 u32 logical_id = le32_to_cpu(cap->logical_id);
2228 u32 number = le32_to_cpu(cap->number);
2229
2230 func_p->num_allocd_vfs = number;
2231 func_p->vf_base_id = logical_id;
2232 ice_debug(hw, ICE_DBG_INIT, "func caps: num_allocd_vfs = %d\n",
2233 func_p->num_allocd_vfs);
2234 ice_debug(hw, ICE_DBG_INIT, "func caps: vf_base_id = %d\n",
2235 func_p->vf_base_id);
2236}
2237
2238/**
2239 * ice_parse_vsi_func_caps - Parse ICE_AQC_CAPS_VSI function caps
2240 * @hw: pointer to the HW struct
2241 * @func_p: pointer to function capabilities structure
2242 * @cap: pointer to the capability element to parse
2243 *
2244 * Extract function capabilities for ICE_AQC_CAPS_VSI.
2245 */
2246static void
2247ice_parse_vsi_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2248 struct ice_aqc_list_caps_elem *cap)
2249{
2250 func_p->guar_num_vsi = ice_get_num_per_func(hw, ICE_MAX_VSI);
2251 ice_debug(hw, ICE_DBG_INIT, "func caps: guar_num_vsi (fw) = %d\n",
2252 le32_to_cpu(cap->number));
2253 ice_debug(hw, ICE_DBG_INIT, "func caps: guar_num_vsi = %d\n",
2254 func_p->guar_num_vsi);
2255}
2256
2257/**
2258 * ice_parse_1588_func_caps - Parse ICE_AQC_CAPS_1588 function caps
2259 * @hw: pointer to the HW struct
2260 * @func_p: pointer to function capabilities structure
2261 * @cap: pointer to the capability element to parse
2262 *
2263 * Extract function capabilities for ICE_AQC_CAPS_1588.
2264 */
2265static void
2266ice_parse_1588_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2267 struct ice_aqc_list_caps_elem *cap)
2268{
2269 struct ice_ts_func_info *info = &func_p->ts_func_info;
2270 u32 number = le32_to_cpu(cap->number);
2271
2272 info->ena = ((number & ICE_TS_FUNC_ENA_M) != 0);
2273 func_p->common_cap.ieee_1588 = info->ena;
2274
2275 info->src_tmr_owned = ((number & ICE_TS_SRC_TMR_OWND_M) != 0);
2276 info->tmr_ena = ((number & ICE_TS_TMR_ENA_M) != 0);
2277 info->tmr_index_owned = ((number & ICE_TS_TMR_IDX_OWND_M) != 0);
2278 info->tmr_index_assoc = ((number & ICE_TS_TMR_IDX_ASSOC_M) != 0);
2279
2280 info->clk_freq = FIELD_GET(ICE_TS_CLK_FREQ_M, number);
2281 info->clk_src = ((number & ICE_TS_CLK_SRC_M) != 0);
2282
2283 if (info->clk_freq < NUM_ICE_TIME_REF_FREQ) {
2284 info->time_ref = (enum ice_time_ref_freq)info->clk_freq;
2285 } else {
2286 /* Unknown clock frequency, so assume a (probably incorrect)
2287 * default to avoid out-of-bounds look ups of frequency
2288 * related information.
2289 */
2290 ice_debug(hw, ICE_DBG_INIT, "1588 func caps: unknown clock frequency %u\n",
2291 info->clk_freq);
2292 info->time_ref = ICE_TIME_REF_FREQ_25_000;
2293 }
2294
2295 ice_debug(hw, ICE_DBG_INIT, "func caps: ieee_1588 = %u\n",
2296 func_p->common_cap.ieee_1588);
2297 ice_debug(hw, ICE_DBG_INIT, "func caps: src_tmr_owned = %u\n",
2298 info->src_tmr_owned);
2299 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_ena = %u\n",
2300 info->tmr_ena);
2301 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_index_owned = %u\n",
2302 info->tmr_index_owned);
2303 ice_debug(hw, ICE_DBG_INIT, "func caps: tmr_index_assoc = %u\n",
2304 info->tmr_index_assoc);
2305 ice_debug(hw, ICE_DBG_INIT, "func caps: clk_freq = %u\n",
2306 info->clk_freq);
2307 ice_debug(hw, ICE_DBG_INIT, "func caps: clk_src = %u\n",
2308 info->clk_src);
2309}
2310
2311/**
2312 * ice_parse_fdir_func_caps - Parse ICE_AQC_CAPS_FD function caps
2313 * @hw: pointer to the HW struct
2314 * @func_p: pointer to function capabilities structure
2315 *
2316 * Extract function capabilities for ICE_AQC_CAPS_FD.
2317 */
2318static void
2319ice_parse_fdir_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p)
2320{
2321 u32 reg_val, gsize, bsize;
2322
2323 reg_val = rd32(hw, GLQF_FD_SIZE);
2324 switch (hw->mac_type) {
2325 case ICE_MAC_E830:
2326 gsize = FIELD_GET(E830_GLQF_FD_SIZE_FD_GSIZE_M, reg_val);
2327 bsize = FIELD_GET(E830_GLQF_FD_SIZE_FD_BSIZE_M, reg_val);
2328 break;
2329 case ICE_MAC_E810:
2330 default:
2331 gsize = FIELD_GET(E800_GLQF_FD_SIZE_FD_GSIZE_M, reg_val);
2332 bsize = FIELD_GET(E800_GLQF_FD_SIZE_FD_BSIZE_M, reg_val);
2333 }
2334 func_p->fd_fltr_guar = ice_get_num_per_func(hw, gsize);
2335 func_p->fd_fltr_best_effort = bsize;
2336
2337 ice_debug(hw, ICE_DBG_INIT, "func caps: fd_fltr_guar = %d\n",
2338 func_p->fd_fltr_guar);
2339 ice_debug(hw, ICE_DBG_INIT, "func caps: fd_fltr_best_effort = %d\n",
2340 func_p->fd_fltr_best_effort);
2341}
2342
2343/**
2344 * ice_parse_func_caps - Parse function capabilities
2345 * @hw: pointer to the HW struct
2346 * @func_p: pointer to function capabilities structure
2347 * @buf: buffer containing the function capability records
2348 * @cap_count: the number of capabilities
2349 *
2350 * Helper function to parse function (0x000A) capabilities list. For
2351 * capabilities shared between device and function, this relies on
2352 * ice_parse_common_caps.
2353 *
2354 * Loop through the list of provided capabilities and extract the relevant
2355 * data into the function capabilities structured.
2356 */
2357static void
2358ice_parse_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_p,
2359 void *buf, u32 cap_count)
2360{
2361 struct ice_aqc_list_caps_elem *cap_resp;
2362 u32 i;
2363
2364 cap_resp = buf;
2365
2366 memset(func_p, 0, sizeof(*func_p));
2367
2368 for (i = 0; i < cap_count; i++) {
2369 u16 cap = le16_to_cpu(cap_resp[i].cap);
2370 bool found;
2371
2372 found = ice_parse_common_caps(hw, &func_p->common_cap,
2373 &cap_resp[i], "func caps");
2374
2375 switch (cap) {
2376 case ICE_AQC_CAPS_VF:
2377 ice_parse_vf_func_caps(hw, func_p, &cap_resp[i]);
2378 break;
2379 case ICE_AQC_CAPS_VSI:
2380 ice_parse_vsi_func_caps(hw, func_p, &cap_resp[i]);
2381 break;
2382 case ICE_AQC_CAPS_1588:
2383 ice_parse_1588_func_caps(hw, func_p, &cap_resp[i]);
2384 break;
2385 case ICE_AQC_CAPS_FD:
2386 ice_parse_fdir_func_caps(hw, func_p);
2387 break;
2388 default:
2389 /* Don't list common capabilities as unknown */
2390 if (!found)
2391 ice_debug(hw, ICE_DBG_INIT, "func caps: unknown capability[%d]: 0x%x\n",
2392 i, cap);
2393 break;
2394 }
2395 }
2396
2397 ice_recalc_port_limited_caps(hw, &func_p->common_cap);
2398}
2399
2400/**
2401 * ice_parse_valid_functions_cap - Parse ICE_AQC_CAPS_VALID_FUNCTIONS caps
2402 * @hw: pointer to the HW struct
2403 * @dev_p: pointer to device capabilities structure
2404 * @cap: capability element to parse
2405 *
2406 * Parse ICE_AQC_CAPS_VALID_FUNCTIONS for device capabilities.
2407 */
2408static void
2409ice_parse_valid_functions_cap(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2410 struct ice_aqc_list_caps_elem *cap)
2411{
2412 u32 number = le32_to_cpu(cap->number);
2413
2414 dev_p->num_funcs = hweight32(number);
2415 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_funcs = %d\n",
2416 dev_p->num_funcs);
2417}
2418
2419/**
2420 * ice_parse_vf_dev_caps - Parse ICE_AQC_CAPS_VF device caps
2421 * @hw: pointer to the HW struct
2422 * @dev_p: pointer to device capabilities structure
2423 * @cap: capability element to parse
2424 *
2425 * Parse ICE_AQC_CAPS_VF for device capabilities.
2426 */
2427static void
2428ice_parse_vf_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2429 struct ice_aqc_list_caps_elem *cap)
2430{
2431 u32 number = le32_to_cpu(cap->number);
2432
2433 dev_p->num_vfs_exposed = number;
2434 ice_debug(hw, ICE_DBG_INIT, "dev_caps: num_vfs_exposed = %d\n",
2435 dev_p->num_vfs_exposed);
2436}
2437
2438/**
2439 * ice_parse_vsi_dev_caps - Parse ICE_AQC_CAPS_VSI device caps
2440 * @hw: pointer to the HW struct
2441 * @dev_p: pointer to device capabilities structure
2442 * @cap: capability element to parse
2443 *
2444 * Parse ICE_AQC_CAPS_VSI for device capabilities.
2445 */
2446static void
2447ice_parse_vsi_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2448 struct ice_aqc_list_caps_elem *cap)
2449{
2450 u32 number = le32_to_cpu(cap->number);
2451
2452 dev_p->num_vsi_allocd_to_host = number;
2453 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_vsi_allocd_to_host = %d\n",
2454 dev_p->num_vsi_allocd_to_host);
2455}
2456
2457/**
2458 * ice_parse_1588_dev_caps - Parse ICE_AQC_CAPS_1588 device caps
2459 * @hw: pointer to the HW struct
2460 * @dev_p: pointer to device capabilities structure
2461 * @cap: capability element to parse
2462 *
2463 * Parse ICE_AQC_CAPS_1588 for device capabilities.
2464 */
2465static void
2466ice_parse_1588_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2467 struct ice_aqc_list_caps_elem *cap)
2468{
2469 struct ice_ts_dev_info *info = &dev_p->ts_dev_info;
2470 u32 logical_id = le32_to_cpu(cap->logical_id);
2471 u32 phys_id = le32_to_cpu(cap->phys_id);
2472 u32 number = le32_to_cpu(cap->number);
2473
2474 info->ena = ((number & ICE_TS_DEV_ENA_M) != 0);
2475 dev_p->common_cap.ieee_1588 = info->ena;
2476
2477 info->tmr0_owner = number & ICE_TS_TMR0_OWNR_M;
2478 info->tmr0_owned = ((number & ICE_TS_TMR0_OWND_M) != 0);
2479 info->tmr0_ena = ((number & ICE_TS_TMR0_ENA_M) != 0);
2480
2481 info->tmr1_owner = FIELD_GET(ICE_TS_TMR1_OWNR_M, number);
2482 info->tmr1_owned = ((number & ICE_TS_TMR1_OWND_M) != 0);
2483 info->tmr1_ena = ((number & ICE_TS_TMR1_ENA_M) != 0);
2484
2485 info->ts_ll_read = ((number & ICE_TS_LL_TX_TS_READ_M) != 0);
2486 info->ts_ll_int_read = ((number & ICE_TS_LL_TX_TS_INT_READ_M) != 0);
2487
2488 info->ena_ports = logical_id;
2489 info->tmr_own_map = phys_id;
2490
2491 ice_debug(hw, ICE_DBG_INIT, "dev caps: ieee_1588 = %u\n",
2492 dev_p->common_cap.ieee_1588);
2493 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_owner = %u\n",
2494 info->tmr0_owner);
2495 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_owned = %u\n",
2496 info->tmr0_owned);
2497 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr0_ena = %u\n",
2498 info->tmr0_ena);
2499 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_owner = %u\n",
2500 info->tmr1_owner);
2501 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_owned = %u\n",
2502 info->tmr1_owned);
2503 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr1_ena = %u\n",
2504 info->tmr1_ena);
2505 ice_debug(hw, ICE_DBG_INIT, "dev caps: ts_ll_read = %u\n",
2506 info->ts_ll_read);
2507 ice_debug(hw, ICE_DBG_INIT, "dev caps: ts_ll_int_read = %u\n",
2508 info->ts_ll_int_read);
2509 ice_debug(hw, ICE_DBG_INIT, "dev caps: ieee_1588 ena_ports = %u\n",
2510 info->ena_ports);
2511 ice_debug(hw, ICE_DBG_INIT, "dev caps: tmr_own_map = %u\n",
2512 info->tmr_own_map);
2513}
2514
2515/**
2516 * ice_parse_fdir_dev_caps - Parse ICE_AQC_CAPS_FD device caps
2517 * @hw: pointer to the HW struct
2518 * @dev_p: pointer to device capabilities structure
2519 * @cap: capability element to parse
2520 *
2521 * Parse ICE_AQC_CAPS_FD for device capabilities.
2522 */
2523static void
2524ice_parse_fdir_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2525 struct ice_aqc_list_caps_elem *cap)
2526{
2527 u32 number = le32_to_cpu(cap->number);
2528
2529 dev_p->num_flow_director_fltr = number;
2530 ice_debug(hw, ICE_DBG_INIT, "dev caps: num_flow_director_fltr = %d\n",
2531 dev_p->num_flow_director_fltr);
2532}
2533
2534/**
2535 * ice_parse_sensor_reading_cap - Parse ICE_AQC_CAPS_SENSOR_READING cap
2536 * @hw: pointer to the HW struct
2537 * @dev_p: pointer to device capabilities structure
2538 * @cap: capability element to parse
2539 *
2540 * Parse ICE_AQC_CAPS_SENSOR_READING for device capability for reading
2541 * enabled sensors.
2542 */
2543static void
2544ice_parse_sensor_reading_cap(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2545 struct ice_aqc_list_caps_elem *cap)
2546{
2547 dev_p->supported_sensors = le32_to_cpu(cap->number);
2548
2549 ice_debug(hw, ICE_DBG_INIT,
2550 "dev caps: supported sensors (bitmap) = 0x%x\n",
2551 dev_p->supported_sensors);
2552}
2553
2554/**
2555 * ice_parse_dev_caps - Parse device capabilities
2556 * @hw: pointer to the HW struct
2557 * @dev_p: pointer to device capabilities structure
2558 * @buf: buffer containing the device capability records
2559 * @cap_count: the number of capabilities
2560 *
2561 * Helper device to parse device (0x000B) capabilities list. For
2562 * capabilities shared between device and function, this relies on
2563 * ice_parse_common_caps.
2564 *
2565 * Loop through the list of provided capabilities and extract the relevant
2566 * data into the device capabilities structured.
2567 */
2568static void
2569ice_parse_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_p,
2570 void *buf, u32 cap_count)
2571{
2572 struct ice_aqc_list_caps_elem *cap_resp;
2573 u32 i;
2574
2575 cap_resp = buf;
2576
2577 memset(dev_p, 0, sizeof(*dev_p));
2578
2579 for (i = 0; i < cap_count; i++) {
2580 u16 cap = le16_to_cpu(cap_resp[i].cap);
2581 bool found;
2582
2583 found = ice_parse_common_caps(hw, &dev_p->common_cap,
2584 &cap_resp[i], "dev caps");
2585
2586 switch (cap) {
2587 case ICE_AQC_CAPS_VALID_FUNCTIONS:
2588 ice_parse_valid_functions_cap(hw, dev_p, &cap_resp[i]);
2589 break;
2590 case ICE_AQC_CAPS_VF:
2591 ice_parse_vf_dev_caps(hw, dev_p, &cap_resp[i]);
2592 break;
2593 case ICE_AQC_CAPS_VSI:
2594 ice_parse_vsi_dev_caps(hw, dev_p, &cap_resp[i]);
2595 break;
2596 case ICE_AQC_CAPS_1588:
2597 ice_parse_1588_dev_caps(hw, dev_p, &cap_resp[i]);
2598 break;
2599 case ICE_AQC_CAPS_FD:
2600 ice_parse_fdir_dev_caps(hw, dev_p, &cap_resp[i]);
2601 break;
2602 case ICE_AQC_CAPS_SENSOR_READING:
2603 ice_parse_sensor_reading_cap(hw, dev_p, &cap_resp[i]);
2604 break;
2605 default:
2606 /* Don't list common capabilities as unknown */
2607 if (!found)
2608 ice_debug(hw, ICE_DBG_INIT, "dev caps: unknown capability[%d]: 0x%x\n",
2609 i, cap);
2610 break;
2611 }
2612 }
2613
2614 ice_recalc_port_limited_caps(hw, &dev_p->common_cap);
2615}
2616
2617/**
2618 * ice_is_pf_c827 - check if pf contains c827 phy
2619 * @hw: pointer to the hw struct
2620 */
2621bool ice_is_pf_c827(struct ice_hw *hw)
2622{
2623 struct ice_aqc_get_link_topo cmd = {};
2624 u8 node_part_number;
2625 u16 node_handle;
2626 int status;
2627
2628 if (hw->mac_type != ICE_MAC_E810)
2629 return false;
2630
2631 if (hw->device_id != ICE_DEV_ID_E810C_QSFP)
2632 return true;
2633
2634 cmd.addr.topo_params.node_type_ctx =
2635 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_TYPE_M, ICE_AQC_LINK_TOPO_NODE_TYPE_PHY) |
2636 FIELD_PREP(ICE_AQC_LINK_TOPO_NODE_CTX_M, ICE_AQC_LINK_TOPO_NODE_CTX_PORT);
2637 cmd.addr.topo_params.index = 0;
2638
2639 status = ice_aq_get_netlist_node(hw, &cmd, &node_part_number,
2640 &node_handle);
2641
2642 if (status || node_part_number != ICE_AQC_GET_LINK_TOPO_NODE_NR_C827)
2643 return false;
2644
2645 if (node_handle == E810C_QSFP_C827_0_HANDLE || node_handle == E810C_QSFP_C827_1_HANDLE)
2646 return true;
2647
2648 return false;
2649}
2650
2651/**
2652 * ice_is_phy_rclk_in_netlist
2653 * @hw: pointer to the hw struct
2654 *
2655 * Check if the PHY Recovered Clock device is present in the netlist
2656 */
2657bool ice_is_phy_rclk_in_netlist(struct ice_hw *hw)
2658{
2659 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2660 ICE_AQC_GET_LINK_TOPO_NODE_NR_C827, NULL) &&
2661 ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2662 ICE_AQC_GET_LINK_TOPO_NODE_NR_E822_PHY, NULL))
2663 return false;
2664
2665 return true;
2666}
2667
2668/**
2669 * ice_is_clock_mux_in_netlist
2670 * @hw: pointer to the hw struct
2671 *
2672 * Check if the Clock Multiplexer device is present in the netlist
2673 */
2674bool ice_is_clock_mux_in_netlist(struct ice_hw *hw)
2675{
2676 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_MUX,
2677 ICE_AQC_GET_LINK_TOPO_NODE_NR_GEN_CLK_MUX,
2678 NULL))
2679 return false;
2680
2681 return true;
2682}
2683
2684/**
2685 * ice_is_cgu_in_netlist - check for CGU presence
2686 * @hw: pointer to the hw struct
2687 *
2688 * Check if the Clock Generation Unit (CGU) device is present in the netlist.
2689 * Save the CGU part number in the hw structure for later use.
2690 * Return:
2691 * * true - cgu is present
2692 * * false - cgu is not present
2693 */
2694bool ice_is_cgu_in_netlist(struct ice_hw *hw)
2695{
2696 if (!ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2697 ICE_AQC_GET_LINK_TOPO_NODE_NR_ZL30632_80032,
2698 NULL)) {
2699 hw->cgu_part_number = ICE_AQC_GET_LINK_TOPO_NODE_NR_ZL30632_80032;
2700 return true;
2701 } else if (!ice_find_netlist_node(hw,
2702 ICE_AQC_LINK_TOPO_NODE_TYPE_CLK_CTRL,
2703 ICE_AQC_GET_LINK_TOPO_NODE_NR_SI5383_5384,
2704 NULL)) {
2705 hw->cgu_part_number = ICE_AQC_GET_LINK_TOPO_NODE_NR_SI5383_5384;
2706 return true;
2707 }
2708
2709 return false;
2710}
2711
2712/**
2713 * ice_is_gps_in_netlist
2714 * @hw: pointer to the hw struct
2715 *
2716 * Check if the GPS generic device is present in the netlist
2717 */
2718bool ice_is_gps_in_netlist(struct ice_hw *hw)
2719{
2720 if (ice_find_netlist_node(hw, ICE_AQC_LINK_TOPO_NODE_TYPE_GPS,
2721 ICE_AQC_GET_LINK_TOPO_NODE_NR_GEN_GPS, NULL))
2722 return false;
2723
2724 return true;
2725}
2726
2727/**
2728 * ice_aq_list_caps - query function/device capabilities
2729 * @hw: pointer to the HW struct
2730 * @buf: a buffer to hold the capabilities
2731 * @buf_size: size of the buffer
2732 * @cap_count: if not NULL, set to the number of capabilities reported
2733 * @opc: capabilities type to discover, device or function
2734 * @cd: pointer to command details structure or NULL
2735 *
2736 * Get the function (0x000A) or device (0x000B) capabilities description from
2737 * firmware and store it in the buffer.
2738 *
2739 * If the cap_count pointer is not NULL, then it is set to the number of
2740 * capabilities firmware will report. Note that if the buffer size is too
2741 * small, it is possible the command will return ICE_AQ_ERR_ENOMEM. The
2742 * cap_count will still be updated in this case. It is recommended that the
2743 * buffer size be set to ICE_AQ_MAX_BUF_LEN (the largest possible buffer that
2744 * firmware could return) to avoid this.
2745 */
2746int
2747ice_aq_list_caps(struct ice_hw *hw, void *buf, u16 buf_size, u32 *cap_count,
2748 enum ice_adminq_opc opc, struct ice_sq_cd *cd)
2749{
2750 struct ice_aqc_list_caps *cmd;
2751 struct ice_aq_desc desc;
2752 int status;
2753
2754 cmd = &desc.params.get_cap;
2755
2756 if (opc != ice_aqc_opc_list_func_caps &&
2757 opc != ice_aqc_opc_list_dev_caps)
2758 return -EINVAL;
2759
2760 ice_fill_dflt_direct_cmd_desc(&desc, opc);
2761 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
2762
2763 if (cap_count)
2764 *cap_count = le32_to_cpu(cmd->count);
2765
2766 return status;
2767}
2768
2769/**
2770 * ice_discover_dev_caps - Read and extract device capabilities
2771 * @hw: pointer to the hardware structure
2772 * @dev_caps: pointer to device capabilities structure
2773 *
2774 * Read the device capabilities and extract them into the dev_caps structure
2775 * for later use.
2776 */
2777int
2778ice_discover_dev_caps(struct ice_hw *hw, struct ice_hw_dev_caps *dev_caps)
2779{
2780 u32 cap_count = 0;
2781 void *cbuf;
2782 int status;
2783
2784 cbuf = kzalloc(ICE_AQ_MAX_BUF_LEN, GFP_KERNEL);
2785 if (!cbuf)
2786 return -ENOMEM;
2787
2788 /* Although the driver doesn't know the number of capabilities the
2789 * device will return, we can simply send a 4KB buffer, the maximum
2790 * possible size that firmware can return.
2791 */
2792 cap_count = ICE_AQ_MAX_BUF_LEN / sizeof(struct ice_aqc_list_caps_elem);
2793
2794 status = ice_aq_list_caps(hw, cbuf, ICE_AQ_MAX_BUF_LEN, &cap_count,
2795 ice_aqc_opc_list_dev_caps, NULL);
2796 if (!status)
2797 ice_parse_dev_caps(hw, dev_caps, cbuf, cap_count);
2798 kfree(cbuf);
2799
2800 return status;
2801}
2802
2803/**
2804 * ice_discover_func_caps - Read and extract function capabilities
2805 * @hw: pointer to the hardware structure
2806 * @func_caps: pointer to function capabilities structure
2807 *
2808 * Read the function capabilities and extract them into the func_caps structure
2809 * for later use.
2810 */
2811static int
2812ice_discover_func_caps(struct ice_hw *hw, struct ice_hw_func_caps *func_caps)
2813{
2814 u32 cap_count = 0;
2815 void *cbuf;
2816 int status;
2817
2818 cbuf = kzalloc(ICE_AQ_MAX_BUF_LEN, GFP_KERNEL);
2819 if (!cbuf)
2820 return -ENOMEM;
2821
2822 /* Although the driver doesn't know the number of capabilities the
2823 * device will return, we can simply send a 4KB buffer, the maximum
2824 * possible size that firmware can return.
2825 */
2826 cap_count = ICE_AQ_MAX_BUF_LEN / sizeof(struct ice_aqc_list_caps_elem);
2827
2828 status = ice_aq_list_caps(hw, cbuf, ICE_AQ_MAX_BUF_LEN, &cap_count,
2829 ice_aqc_opc_list_func_caps, NULL);
2830 if (!status)
2831 ice_parse_func_caps(hw, func_caps, cbuf, cap_count);
2832 kfree(cbuf);
2833
2834 return status;
2835}
2836
2837/**
2838 * ice_set_safe_mode_caps - Override dev/func capabilities when in safe mode
2839 * @hw: pointer to the hardware structure
2840 */
2841void ice_set_safe_mode_caps(struct ice_hw *hw)
2842{
2843 struct ice_hw_func_caps *func_caps = &hw->func_caps;
2844 struct ice_hw_dev_caps *dev_caps = &hw->dev_caps;
2845 struct ice_hw_common_caps cached_caps;
2846 u32 num_funcs;
2847
2848 /* cache some func_caps values that should be restored after memset */
2849 cached_caps = func_caps->common_cap;
2850
2851 /* unset func capabilities */
2852 memset(func_caps, 0, sizeof(*func_caps));
2853
2854#define ICE_RESTORE_FUNC_CAP(name) \
2855 func_caps->common_cap.name = cached_caps.name
2856
2857 /* restore cached values */
2858 ICE_RESTORE_FUNC_CAP(valid_functions);
2859 ICE_RESTORE_FUNC_CAP(txq_first_id);
2860 ICE_RESTORE_FUNC_CAP(rxq_first_id);
2861 ICE_RESTORE_FUNC_CAP(msix_vector_first_id);
2862 ICE_RESTORE_FUNC_CAP(max_mtu);
2863 ICE_RESTORE_FUNC_CAP(nvm_unified_update);
2864 ICE_RESTORE_FUNC_CAP(nvm_update_pending_nvm);
2865 ICE_RESTORE_FUNC_CAP(nvm_update_pending_orom);
2866 ICE_RESTORE_FUNC_CAP(nvm_update_pending_netlist);
2867
2868 /* one Tx and one Rx queue in safe mode */
2869 func_caps->common_cap.num_rxq = 1;
2870 func_caps->common_cap.num_txq = 1;
2871
2872 /* two MSIX vectors, one for traffic and one for misc causes */
2873 func_caps->common_cap.num_msix_vectors = 2;
2874 func_caps->guar_num_vsi = 1;
2875
2876 /* cache some dev_caps values that should be restored after memset */
2877 cached_caps = dev_caps->common_cap;
2878 num_funcs = dev_caps->num_funcs;
2879
2880 /* unset dev capabilities */
2881 memset(dev_caps, 0, sizeof(*dev_caps));
2882
2883#define ICE_RESTORE_DEV_CAP(name) \
2884 dev_caps->common_cap.name = cached_caps.name
2885
2886 /* restore cached values */
2887 ICE_RESTORE_DEV_CAP(valid_functions);
2888 ICE_RESTORE_DEV_CAP(txq_first_id);
2889 ICE_RESTORE_DEV_CAP(rxq_first_id);
2890 ICE_RESTORE_DEV_CAP(msix_vector_first_id);
2891 ICE_RESTORE_DEV_CAP(max_mtu);
2892 ICE_RESTORE_DEV_CAP(nvm_unified_update);
2893 ICE_RESTORE_DEV_CAP(nvm_update_pending_nvm);
2894 ICE_RESTORE_DEV_CAP(nvm_update_pending_orom);
2895 ICE_RESTORE_DEV_CAP(nvm_update_pending_netlist);
2896 dev_caps->num_funcs = num_funcs;
2897
2898 /* one Tx and one Rx queue per function in safe mode */
2899 dev_caps->common_cap.num_rxq = num_funcs;
2900 dev_caps->common_cap.num_txq = num_funcs;
2901
2902 /* two MSIX vectors per function */
2903 dev_caps->common_cap.num_msix_vectors = 2 * num_funcs;
2904}
2905
2906/**
2907 * ice_get_caps - get info about the HW
2908 * @hw: pointer to the hardware structure
2909 */
2910int ice_get_caps(struct ice_hw *hw)
2911{
2912 int status;
2913
2914 status = ice_discover_dev_caps(hw, &hw->dev_caps);
2915 if (status)
2916 return status;
2917
2918 return ice_discover_func_caps(hw, &hw->func_caps);
2919}
2920
2921/**
2922 * ice_aq_manage_mac_write - manage MAC address write command
2923 * @hw: pointer to the HW struct
2924 * @mac_addr: MAC address to be written as LAA/LAA+WoL/Port address
2925 * @flags: flags to control write behavior
2926 * @cd: pointer to command details structure or NULL
2927 *
2928 * This function is used to write MAC address to the NVM (0x0108).
2929 */
2930int
2931ice_aq_manage_mac_write(struct ice_hw *hw, const u8 *mac_addr, u8 flags,
2932 struct ice_sq_cd *cd)
2933{
2934 struct ice_aqc_manage_mac_write *cmd;
2935 struct ice_aq_desc desc;
2936
2937 cmd = &desc.params.mac_write;
2938 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_manage_mac_write);
2939
2940 cmd->flags = flags;
2941 ether_addr_copy(cmd->mac_addr, mac_addr);
2942
2943 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
2944}
2945
2946/**
2947 * ice_aq_clear_pxe_mode
2948 * @hw: pointer to the HW struct
2949 *
2950 * Tell the firmware that the driver is taking over from PXE (0x0110).
2951 */
2952static int ice_aq_clear_pxe_mode(struct ice_hw *hw)
2953{
2954 struct ice_aq_desc desc;
2955
2956 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_clear_pxe_mode);
2957 desc.params.clear_pxe.rx_cnt = ICE_AQC_CLEAR_PXE_RX_CNT;
2958
2959 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
2960}
2961
2962/**
2963 * ice_clear_pxe_mode - clear pxe operations mode
2964 * @hw: pointer to the HW struct
2965 *
2966 * Make sure all PXE mode settings are cleared, including things
2967 * like descriptor fetch/write-back mode.
2968 */
2969void ice_clear_pxe_mode(struct ice_hw *hw)
2970{
2971 if (ice_check_sq_alive(hw, &hw->adminq))
2972 ice_aq_clear_pxe_mode(hw);
2973}
2974
2975/**
2976 * ice_aq_set_port_params - set physical port parameters.
2977 * @pi: pointer to the port info struct
2978 * @double_vlan: if set double VLAN is enabled
2979 * @cd: pointer to command details structure or NULL
2980 *
2981 * Set Physical port parameters (0x0203)
2982 */
2983int
2984ice_aq_set_port_params(struct ice_port_info *pi, bool double_vlan,
2985 struct ice_sq_cd *cd)
2986
2987{
2988 struct ice_aqc_set_port_params *cmd;
2989 struct ice_hw *hw = pi->hw;
2990 struct ice_aq_desc desc;
2991 u16 cmd_flags = 0;
2992
2993 cmd = &desc.params.set_port_params;
2994
2995 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_params);
2996 if (double_vlan)
2997 cmd_flags |= ICE_AQC_SET_P_PARAMS_DOUBLE_VLAN_ENA;
2998 cmd->cmd_flags = cpu_to_le16(cmd_flags);
2999
3000 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3001}
3002
3003/**
3004 * ice_is_100m_speed_supported
3005 * @hw: pointer to the HW struct
3006 *
3007 * returns true if 100M speeds are supported by the device,
3008 * false otherwise.
3009 */
3010bool ice_is_100m_speed_supported(struct ice_hw *hw)
3011{
3012 switch (hw->device_id) {
3013 case ICE_DEV_ID_E822C_SGMII:
3014 case ICE_DEV_ID_E822L_SGMII:
3015 case ICE_DEV_ID_E823L_1GBE:
3016 case ICE_DEV_ID_E823C_SGMII:
3017 return true;
3018 default:
3019 return false;
3020 }
3021}
3022
3023/**
3024 * ice_get_link_speed_based_on_phy_type - returns link speed
3025 * @phy_type_low: lower part of phy_type
3026 * @phy_type_high: higher part of phy_type
3027 *
3028 * This helper function will convert an entry in PHY type structure
3029 * [phy_type_low, phy_type_high] to its corresponding link speed.
3030 * Note: In the structure of [phy_type_low, phy_type_high], there should
3031 * be one bit set, as this function will convert one PHY type to its
3032 * speed.
3033 * If no bit gets set, ICE_AQ_LINK_SPEED_UNKNOWN will be returned
3034 * If more than one bit gets set, ICE_AQ_LINK_SPEED_UNKNOWN will be returned
3035 */
3036static u16
3037ice_get_link_speed_based_on_phy_type(u64 phy_type_low, u64 phy_type_high)
3038{
3039 u16 speed_phy_type_high = ICE_AQ_LINK_SPEED_UNKNOWN;
3040 u16 speed_phy_type_low = ICE_AQ_LINK_SPEED_UNKNOWN;
3041
3042 switch (phy_type_low) {
3043 case ICE_PHY_TYPE_LOW_100BASE_TX:
3044 case ICE_PHY_TYPE_LOW_100M_SGMII:
3045 speed_phy_type_low = ICE_AQ_LINK_SPEED_100MB;
3046 break;
3047 case ICE_PHY_TYPE_LOW_1000BASE_T:
3048 case ICE_PHY_TYPE_LOW_1000BASE_SX:
3049 case ICE_PHY_TYPE_LOW_1000BASE_LX:
3050 case ICE_PHY_TYPE_LOW_1000BASE_KX:
3051 case ICE_PHY_TYPE_LOW_1G_SGMII:
3052 speed_phy_type_low = ICE_AQ_LINK_SPEED_1000MB;
3053 break;
3054 case ICE_PHY_TYPE_LOW_2500BASE_T:
3055 case ICE_PHY_TYPE_LOW_2500BASE_X:
3056 case ICE_PHY_TYPE_LOW_2500BASE_KX:
3057 speed_phy_type_low = ICE_AQ_LINK_SPEED_2500MB;
3058 break;
3059 case ICE_PHY_TYPE_LOW_5GBASE_T:
3060 case ICE_PHY_TYPE_LOW_5GBASE_KR:
3061 speed_phy_type_low = ICE_AQ_LINK_SPEED_5GB;
3062 break;
3063 case ICE_PHY_TYPE_LOW_10GBASE_T:
3064 case ICE_PHY_TYPE_LOW_10G_SFI_DA:
3065 case ICE_PHY_TYPE_LOW_10GBASE_SR:
3066 case ICE_PHY_TYPE_LOW_10GBASE_LR:
3067 case ICE_PHY_TYPE_LOW_10GBASE_KR_CR1:
3068 case ICE_PHY_TYPE_LOW_10G_SFI_AOC_ACC:
3069 case ICE_PHY_TYPE_LOW_10G_SFI_C2C:
3070 speed_phy_type_low = ICE_AQ_LINK_SPEED_10GB;
3071 break;
3072 case ICE_PHY_TYPE_LOW_25GBASE_T:
3073 case ICE_PHY_TYPE_LOW_25GBASE_CR:
3074 case ICE_PHY_TYPE_LOW_25GBASE_CR_S:
3075 case ICE_PHY_TYPE_LOW_25GBASE_CR1:
3076 case ICE_PHY_TYPE_LOW_25GBASE_SR:
3077 case ICE_PHY_TYPE_LOW_25GBASE_LR:
3078 case ICE_PHY_TYPE_LOW_25GBASE_KR:
3079 case ICE_PHY_TYPE_LOW_25GBASE_KR_S:
3080 case ICE_PHY_TYPE_LOW_25GBASE_KR1:
3081 case ICE_PHY_TYPE_LOW_25G_AUI_AOC_ACC:
3082 case ICE_PHY_TYPE_LOW_25G_AUI_C2C:
3083 speed_phy_type_low = ICE_AQ_LINK_SPEED_25GB;
3084 break;
3085 case ICE_PHY_TYPE_LOW_40GBASE_CR4:
3086 case ICE_PHY_TYPE_LOW_40GBASE_SR4:
3087 case ICE_PHY_TYPE_LOW_40GBASE_LR4:
3088 case ICE_PHY_TYPE_LOW_40GBASE_KR4:
3089 case ICE_PHY_TYPE_LOW_40G_XLAUI_AOC_ACC:
3090 case ICE_PHY_TYPE_LOW_40G_XLAUI:
3091 speed_phy_type_low = ICE_AQ_LINK_SPEED_40GB;
3092 break;
3093 case ICE_PHY_TYPE_LOW_50GBASE_CR2:
3094 case ICE_PHY_TYPE_LOW_50GBASE_SR2:
3095 case ICE_PHY_TYPE_LOW_50GBASE_LR2:
3096 case ICE_PHY_TYPE_LOW_50GBASE_KR2:
3097 case ICE_PHY_TYPE_LOW_50G_LAUI2_AOC_ACC:
3098 case ICE_PHY_TYPE_LOW_50G_LAUI2:
3099 case ICE_PHY_TYPE_LOW_50G_AUI2_AOC_ACC:
3100 case ICE_PHY_TYPE_LOW_50G_AUI2:
3101 case ICE_PHY_TYPE_LOW_50GBASE_CP:
3102 case ICE_PHY_TYPE_LOW_50GBASE_SR:
3103 case ICE_PHY_TYPE_LOW_50GBASE_FR:
3104 case ICE_PHY_TYPE_LOW_50GBASE_LR:
3105 case ICE_PHY_TYPE_LOW_50GBASE_KR_PAM4:
3106 case ICE_PHY_TYPE_LOW_50G_AUI1_AOC_ACC:
3107 case ICE_PHY_TYPE_LOW_50G_AUI1:
3108 speed_phy_type_low = ICE_AQ_LINK_SPEED_50GB;
3109 break;
3110 case ICE_PHY_TYPE_LOW_100GBASE_CR4:
3111 case ICE_PHY_TYPE_LOW_100GBASE_SR4:
3112 case ICE_PHY_TYPE_LOW_100GBASE_LR4:
3113 case ICE_PHY_TYPE_LOW_100GBASE_KR4:
3114 case ICE_PHY_TYPE_LOW_100G_CAUI4_AOC_ACC:
3115 case ICE_PHY_TYPE_LOW_100G_CAUI4:
3116 case ICE_PHY_TYPE_LOW_100G_AUI4_AOC_ACC:
3117 case ICE_PHY_TYPE_LOW_100G_AUI4:
3118 case ICE_PHY_TYPE_LOW_100GBASE_CR_PAM4:
3119 case ICE_PHY_TYPE_LOW_100GBASE_KR_PAM4:
3120 case ICE_PHY_TYPE_LOW_100GBASE_CP2:
3121 case ICE_PHY_TYPE_LOW_100GBASE_SR2:
3122 case ICE_PHY_TYPE_LOW_100GBASE_DR:
3123 speed_phy_type_low = ICE_AQ_LINK_SPEED_100GB;
3124 break;
3125 default:
3126 speed_phy_type_low = ICE_AQ_LINK_SPEED_UNKNOWN;
3127 break;
3128 }
3129
3130 switch (phy_type_high) {
3131 case ICE_PHY_TYPE_HIGH_100GBASE_KR2_PAM4:
3132 case ICE_PHY_TYPE_HIGH_100G_CAUI2_AOC_ACC:
3133 case ICE_PHY_TYPE_HIGH_100G_CAUI2:
3134 case ICE_PHY_TYPE_HIGH_100G_AUI2_AOC_ACC:
3135 case ICE_PHY_TYPE_HIGH_100G_AUI2:
3136 speed_phy_type_high = ICE_AQ_LINK_SPEED_100GB;
3137 break;
3138 case ICE_PHY_TYPE_HIGH_200G_CR4_PAM4:
3139 case ICE_PHY_TYPE_HIGH_200G_SR4:
3140 case ICE_PHY_TYPE_HIGH_200G_FR4:
3141 case ICE_PHY_TYPE_HIGH_200G_LR4:
3142 case ICE_PHY_TYPE_HIGH_200G_DR4:
3143 case ICE_PHY_TYPE_HIGH_200G_KR4_PAM4:
3144 case ICE_PHY_TYPE_HIGH_200G_AUI4_AOC_ACC:
3145 case ICE_PHY_TYPE_HIGH_200G_AUI4:
3146 speed_phy_type_high = ICE_AQ_LINK_SPEED_200GB;
3147 break;
3148 default:
3149 speed_phy_type_high = ICE_AQ_LINK_SPEED_UNKNOWN;
3150 break;
3151 }
3152
3153 if (speed_phy_type_low == ICE_AQ_LINK_SPEED_UNKNOWN &&
3154 speed_phy_type_high == ICE_AQ_LINK_SPEED_UNKNOWN)
3155 return ICE_AQ_LINK_SPEED_UNKNOWN;
3156 else if (speed_phy_type_low != ICE_AQ_LINK_SPEED_UNKNOWN &&
3157 speed_phy_type_high != ICE_AQ_LINK_SPEED_UNKNOWN)
3158 return ICE_AQ_LINK_SPEED_UNKNOWN;
3159 else if (speed_phy_type_low != ICE_AQ_LINK_SPEED_UNKNOWN &&
3160 speed_phy_type_high == ICE_AQ_LINK_SPEED_UNKNOWN)
3161 return speed_phy_type_low;
3162 else
3163 return speed_phy_type_high;
3164}
3165
3166/**
3167 * ice_update_phy_type
3168 * @phy_type_low: pointer to the lower part of phy_type
3169 * @phy_type_high: pointer to the higher part of phy_type
3170 * @link_speeds_bitmap: targeted link speeds bitmap
3171 *
3172 * Note: For the link_speeds_bitmap structure, you can check it at
3173 * [ice_aqc_get_link_status->link_speed]. Caller can pass in
3174 * link_speeds_bitmap include multiple speeds.
3175 *
3176 * Each entry in this [phy_type_low, phy_type_high] structure will
3177 * present a certain link speed. This helper function will turn on bits
3178 * in [phy_type_low, phy_type_high] structure based on the value of
3179 * link_speeds_bitmap input parameter.
3180 */
3181void
3182ice_update_phy_type(u64 *phy_type_low, u64 *phy_type_high,
3183 u16 link_speeds_bitmap)
3184{
3185 u64 pt_high;
3186 u64 pt_low;
3187 int index;
3188 u16 speed;
3189
3190 /* We first check with low part of phy_type */
3191 for (index = 0; index <= ICE_PHY_TYPE_LOW_MAX_INDEX; index++) {
3192 pt_low = BIT_ULL(index);
3193 speed = ice_get_link_speed_based_on_phy_type(pt_low, 0);
3194
3195 if (link_speeds_bitmap & speed)
3196 *phy_type_low |= BIT_ULL(index);
3197 }
3198
3199 /* We then check with high part of phy_type */
3200 for (index = 0; index <= ICE_PHY_TYPE_HIGH_MAX_INDEX; index++) {
3201 pt_high = BIT_ULL(index);
3202 speed = ice_get_link_speed_based_on_phy_type(0, pt_high);
3203
3204 if (link_speeds_bitmap & speed)
3205 *phy_type_high |= BIT_ULL(index);
3206 }
3207}
3208
3209/**
3210 * ice_aq_set_phy_cfg
3211 * @hw: pointer to the HW struct
3212 * @pi: port info structure of the interested logical port
3213 * @cfg: structure with PHY configuration data to be set
3214 * @cd: pointer to command details structure or NULL
3215 *
3216 * Set the various PHY configuration parameters supported on the Port.
3217 * One or more of the Set PHY config parameters may be ignored in an MFP
3218 * mode as the PF may not have the privilege to set some of the PHY Config
3219 * parameters. This status will be indicated by the command response (0x0601).
3220 */
3221int
3222ice_aq_set_phy_cfg(struct ice_hw *hw, struct ice_port_info *pi,
3223 struct ice_aqc_set_phy_cfg_data *cfg, struct ice_sq_cd *cd)
3224{
3225 struct ice_aq_desc desc;
3226 int status;
3227
3228 if (!cfg)
3229 return -EINVAL;
3230
3231 /* Ensure that only valid bits of cfg->caps can be turned on. */
3232 if (cfg->caps & ~ICE_AQ_PHY_ENA_VALID_MASK) {
3233 ice_debug(hw, ICE_DBG_PHY, "Invalid bit is set in ice_aqc_set_phy_cfg_data->caps : 0x%x\n",
3234 cfg->caps);
3235
3236 cfg->caps &= ICE_AQ_PHY_ENA_VALID_MASK;
3237 }
3238
3239 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_phy_cfg);
3240 desc.params.set_phy.lport_num = pi->lport;
3241 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
3242
3243 ice_debug(hw, ICE_DBG_LINK, "set phy cfg\n");
3244 ice_debug(hw, ICE_DBG_LINK, " phy_type_low = 0x%llx\n",
3245 (unsigned long long)le64_to_cpu(cfg->phy_type_low));
3246 ice_debug(hw, ICE_DBG_LINK, " phy_type_high = 0x%llx\n",
3247 (unsigned long long)le64_to_cpu(cfg->phy_type_high));
3248 ice_debug(hw, ICE_DBG_LINK, " caps = 0x%x\n", cfg->caps);
3249 ice_debug(hw, ICE_DBG_LINK, " low_power_ctrl_an = 0x%x\n",
3250 cfg->low_power_ctrl_an);
3251 ice_debug(hw, ICE_DBG_LINK, " eee_cap = 0x%x\n", cfg->eee_cap);
3252 ice_debug(hw, ICE_DBG_LINK, " eeer_value = 0x%x\n", cfg->eeer_value);
3253 ice_debug(hw, ICE_DBG_LINK, " link_fec_opt = 0x%x\n",
3254 cfg->link_fec_opt);
3255
3256 status = ice_aq_send_cmd(hw, &desc, cfg, sizeof(*cfg), cd);
3257 if (hw->adminq.sq_last_status == ICE_AQ_RC_EMODE)
3258 status = 0;
3259
3260 if (!status)
3261 pi->phy.curr_user_phy_cfg = *cfg;
3262
3263 return status;
3264}
3265
3266/**
3267 * ice_update_link_info - update status of the HW network link
3268 * @pi: port info structure of the interested logical port
3269 */
3270int ice_update_link_info(struct ice_port_info *pi)
3271{
3272 struct ice_link_status *li;
3273 int status;
3274
3275 if (!pi)
3276 return -EINVAL;
3277
3278 li = &pi->phy.link_info;
3279
3280 status = ice_aq_get_link_info(pi, true, NULL, NULL);
3281 if (status)
3282 return status;
3283
3284 if (li->link_info & ICE_AQ_MEDIA_AVAILABLE) {
3285 struct ice_aqc_get_phy_caps_data *pcaps __free(kfree) = NULL;
3286
3287 pcaps = kzalloc(sizeof(*pcaps), GFP_KERNEL);
3288 if (!pcaps)
3289 return -ENOMEM;
3290
3291 status = ice_aq_get_phy_caps(pi, false, ICE_AQC_REPORT_TOPO_CAP_MEDIA,
3292 pcaps, NULL);
3293 }
3294
3295 return status;
3296}
3297
3298/**
3299 * ice_cache_phy_user_req
3300 * @pi: port information structure
3301 * @cache_data: PHY logging data
3302 * @cache_mode: PHY logging mode
3303 *
3304 * Log the user request on (FC, FEC, SPEED) for later use.
3305 */
3306static void
3307ice_cache_phy_user_req(struct ice_port_info *pi,
3308 struct ice_phy_cache_mode_data cache_data,
3309 enum ice_phy_cache_mode cache_mode)
3310{
3311 if (!pi)
3312 return;
3313
3314 switch (cache_mode) {
3315 case ICE_FC_MODE:
3316 pi->phy.curr_user_fc_req = cache_data.data.curr_user_fc_req;
3317 break;
3318 case ICE_SPEED_MODE:
3319 pi->phy.curr_user_speed_req =
3320 cache_data.data.curr_user_speed_req;
3321 break;
3322 case ICE_FEC_MODE:
3323 pi->phy.curr_user_fec_req = cache_data.data.curr_user_fec_req;
3324 break;
3325 default:
3326 break;
3327 }
3328}
3329
3330/**
3331 * ice_caps_to_fc_mode
3332 * @caps: PHY capabilities
3333 *
3334 * Convert PHY FC capabilities to ice FC mode
3335 */
3336enum ice_fc_mode ice_caps_to_fc_mode(u8 caps)
3337{
3338 if (caps & ICE_AQC_PHY_EN_TX_LINK_PAUSE &&
3339 caps & ICE_AQC_PHY_EN_RX_LINK_PAUSE)
3340 return ICE_FC_FULL;
3341
3342 if (caps & ICE_AQC_PHY_EN_TX_LINK_PAUSE)
3343 return ICE_FC_TX_PAUSE;
3344
3345 if (caps & ICE_AQC_PHY_EN_RX_LINK_PAUSE)
3346 return ICE_FC_RX_PAUSE;
3347
3348 return ICE_FC_NONE;
3349}
3350
3351/**
3352 * ice_caps_to_fec_mode
3353 * @caps: PHY capabilities
3354 * @fec_options: Link FEC options
3355 *
3356 * Convert PHY FEC capabilities to ice FEC mode
3357 */
3358enum ice_fec_mode ice_caps_to_fec_mode(u8 caps, u8 fec_options)
3359{
3360 if (caps & ICE_AQC_PHY_EN_AUTO_FEC)
3361 return ICE_FEC_AUTO;
3362
3363 if (fec_options & (ICE_AQC_PHY_FEC_10G_KR_40G_KR4_EN |
3364 ICE_AQC_PHY_FEC_10G_KR_40G_KR4_REQ |
3365 ICE_AQC_PHY_FEC_25G_KR_CLAUSE74_EN |
3366 ICE_AQC_PHY_FEC_25G_KR_REQ))
3367 return ICE_FEC_BASER;
3368
3369 if (fec_options & (ICE_AQC_PHY_FEC_25G_RS_528_REQ |
3370 ICE_AQC_PHY_FEC_25G_RS_544_REQ |
3371 ICE_AQC_PHY_FEC_25G_RS_CLAUSE91_EN))
3372 return ICE_FEC_RS;
3373
3374 return ICE_FEC_NONE;
3375}
3376
3377/**
3378 * ice_cfg_phy_fc - Configure PHY FC data based on FC mode
3379 * @pi: port information structure
3380 * @cfg: PHY configuration data to set FC mode
3381 * @req_mode: FC mode to configure
3382 */
3383int
3384ice_cfg_phy_fc(struct ice_port_info *pi, struct ice_aqc_set_phy_cfg_data *cfg,
3385 enum ice_fc_mode req_mode)
3386{
3387 struct ice_phy_cache_mode_data cache_data;
3388 u8 pause_mask = 0x0;
3389
3390 if (!pi || !cfg)
3391 return -EINVAL;
3392
3393 switch (req_mode) {
3394 case ICE_FC_FULL:
3395 pause_mask |= ICE_AQC_PHY_EN_TX_LINK_PAUSE;
3396 pause_mask |= ICE_AQC_PHY_EN_RX_LINK_PAUSE;
3397 break;
3398 case ICE_FC_RX_PAUSE:
3399 pause_mask |= ICE_AQC_PHY_EN_RX_LINK_PAUSE;
3400 break;
3401 case ICE_FC_TX_PAUSE:
3402 pause_mask |= ICE_AQC_PHY_EN_TX_LINK_PAUSE;
3403 break;
3404 default:
3405 break;
3406 }
3407
3408 /* clear the old pause settings */
3409 cfg->caps &= ~(ICE_AQC_PHY_EN_TX_LINK_PAUSE |
3410 ICE_AQC_PHY_EN_RX_LINK_PAUSE);
3411
3412 /* set the new capabilities */
3413 cfg->caps |= pause_mask;
3414
3415 /* Cache user FC request */
3416 cache_data.data.curr_user_fc_req = req_mode;
3417 ice_cache_phy_user_req(pi, cache_data, ICE_FC_MODE);
3418
3419 return 0;
3420}
3421
3422/**
3423 * ice_set_fc
3424 * @pi: port information structure
3425 * @aq_failures: pointer to status code, specific to ice_set_fc routine
3426 * @ena_auto_link_update: enable automatic link update
3427 *
3428 * Set the requested flow control mode.
3429 */
3430int
3431ice_set_fc(struct ice_port_info *pi, u8 *aq_failures, bool ena_auto_link_update)
3432{
3433 struct ice_aqc_get_phy_caps_data *pcaps __free(kfree) = NULL;
3434 struct ice_aqc_set_phy_cfg_data cfg = { 0 };
3435 struct ice_hw *hw;
3436 int status;
3437
3438 if (!pi || !aq_failures)
3439 return -EINVAL;
3440
3441 *aq_failures = 0;
3442 hw = pi->hw;
3443
3444 pcaps = kzalloc(sizeof(*pcaps), GFP_KERNEL);
3445 if (!pcaps)
3446 return -ENOMEM;
3447
3448 /* Get the current PHY config */
3449 status = ice_aq_get_phy_caps(pi, false, ICE_AQC_REPORT_ACTIVE_CFG,
3450 pcaps, NULL);
3451 if (status) {
3452 *aq_failures = ICE_SET_FC_AQ_FAIL_GET;
3453 goto out;
3454 }
3455
3456 ice_copy_phy_caps_to_cfg(pi, pcaps, &cfg);
3457
3458 /* Configure the set PHY data */
3459 status = ice_cfg_phy_fc(pi, &cfg, pi->fc.req_mode);
3460 if (status)
3461 goto out;
3462
3463 /* If the capabilities have changed, then set the new config */
3464 if (cfg.caps != pcaps->caps) {
3465 int retry_count, retry_max = 10;
3466
3467 /* Auto restart link so settings take effect */
3468 if (ena_auto_link_update)
3469 cfg.caps |= ICE_AQ_PHY_ENA_AUTO_LINK_UPDT;
3470
3471 status = ice_aq_set_phy_cfg(hw, pi, &cfg, NULL);
3472 if (status) {
3473 *aq_failures = ICE_SET_FC_AQ_FAIL_SET;
3474 goto out;
3475 }
3476
3477 /* Update the link info
3478 * It sometimes takes a really long time for link to
3479 * come back from the atomic reset. Thus, we wait a
3480 * little bit.
3481 */
3482 for (retry_count = 0; retry_count < retry_max; retry_count++) {
3483 status = ice_update_link_info(pi);
3484
3485 if (!status)
3486 break;
3487
3488 mdelay(100);
3489 }
3490
3491 if (status)
3492 *aq_failures = ICE_SET_FC_AQ_FAIL_UPDATE;
3493 }
3494
3495out:
3496 return status;
3497}
3498
3499/**
3500 * ice_phy_caps_equals_cfg
3501 * @phy_caps: PHY capabilities
3502 * @phy_cfg: PHY configuration
3503 *
3504 * Helper function to determine if PHY capabilities matches PHY
3505 * configuration
3506 */
3507bool
3508ice_phy_caps_equals_cfg(struct ice_aqc_get_phy_caps_data *phy_caps,
3509 struct ice_aqc_set_phy_cfg_data *phy_cfg)
3510{
3511 u8 caps_mask, cfg_mask;
3512
3513 if (!phy_caps || !phy_cfg)
3514 return false;
3515
3516 /* These bits are not common between capabilities and configuration.
3517 * Do not use them to determine equality.
3518 */
3519 caps_mask = ICE_AQC_PHY_CAPS_MASK & ~(ICE_AQC_PHY_AN_MODE |
3520 ICE_AQC_GET_PHY_EN_MOD_QUAL);
3521 cfg_mask = ICE_AQ_PHY_ENA_VALID_MASK & ~ICE_AQ_PHY_ENA_AUTO_LINK_UPDT;
3522
3523 if (phy_caps->phy_type_low != phy_cfg->phy_type_low ||
3524 phy_caps->phy_type_high != phy_cfg->phy_type_high ||
3525 ((phy_caps->caps & caps_mask) != (phy_cfg->caps & cfg_mask)) ||
3526 phy_caps->low_power_ctrl_an != phy_cfg->low_power_ctrl_an ||
3527 phy_caps->eee_cap != phy_cfg->eee_cap ||
3528 phy_caps->eeer_value != phy_cfg->eeer_value ||
3529 phy_caps->link_fec_options != phy_cfg->link_fec_opt)
3530 return false;
3531
3532 return true;
3533}
3534
3535/**
3536 * ice_copy_phy_caps_to_cfg - Copy PHY ability data to configuration data
3537 * @pi: port information structure
3538 * @caps: PHY ability structure to copy date from
3539 * @cfg: PHY configuration structure to copy data to
3540 *
3541 * Helper function to copy AQC PHY get ability data to PHY set configuration
3542 * data structure
3543 */
3544void
3545ice_copy_phy_caps_to_cfg(struct ice_port_info *pi,
3546 struct ice_aqc_get_phy_caps_data *caps,
3547 struct ice_aqc_set_phy_cfg_data *cfg)
3548{
3549 if (!pi || !caps || !cfg)
3550 return;
3551
3552 memset(cfg, 0, sizeof(*cfg));
3553 cfg->phy_type_low = caps->phy_type_low;
3554 cfg->phy_type_high = caps->phy_type_high;
3555 cfg->caps = caps->caps;
3556 cfg->low_power_ctrl_an = caps->low_power_ctrl_an;
3557 cfg->eee_cap = caps->eee_cap;
3558 cfg->eeer_value = caps->eeer_value;
3559 cfg->link_fec_opt = caps->link_fec_options;
3560 cfg->module_compliance_enforcement =
3561 caps->module_compliance_enforcement;
3562}
3563
3564/**
3565 * ice_cfg_phy_fec - Configure PHY FEC data based on FEC mode
3566 * @pi: port information structure
3567 * @cfg: PHY configuration data to set FEC mode
3568 * @fec: FEC mode to configure
3569 */
3570int
3571ice_cfg_phy_fec(struct ice_port_info *pi, struct ice_aqc_set_phy_cfg_data *cfg,
3572 enum ice_fec_mode fec)
3573{
3574 struct ice_aqc_get_phy_caps_data *pcaps __free(kfree) = NULL;
3575 struct ice_hw *hw;
3576 int status;
3577
3578 if (!pi || !cfg)
3579 return -EINVAL;
3580
3581 hw = pi->hw;
3582
3583 pcaps = kzalloc(sizeof(*pcaps), GFP_KERNEL);
3584 if (!pcaps)
3585 return -ENOMEM;
3586
3587 status = ice_aq_get_phy_caps(pi, false,
3588 (ice_fw_supports_report_dflt_cfg(hw) ?
3589 ICE_AQC_REPORT_DFLT_CFG :
3590 ICE_AQC_REPORT_TOPO_CAP_MEDIA), pcaps, NULL);
3591 if (status)
3592 goto out;
3593
3594 cfg->caps |= pcaps->caps & ICE_AQC_PHY_EN_AUTO_FEC;
3595 cfg->link_fec_opt = pcaps->link_fec_options;
3596
3597 switch (fec) {
3598 case ICE_FEC_BASER:
3599 /* Clear RS bits, and AND BASE-R ability
3600 * bits and OR request bits.
3601 */
3602 cfg->link_fec_opt &= ICE_AQC_PHY_FEC_10G_KR_40G_KR4_EN |
3603 ICE_AQC_PHY_FEC_25G_KR_CLAUSE74_EN;
3604 cfg->link_fec_opt |= ICE_AQC_PHY_FEC_10G_KR_40G_KR4_REQ |
3605 ICE_AQC_PHY_FEC_25G_KR_REQ;
3606 break;
3607 case ICE_FEC_RS:
3608 /* Clear BASE-R bits, and AND RS ability
3609 * bits and OR request bits.
3610 */
3611 cfg->link_fec_opt &= ICE_AQC_PHY_FEC_25G_RS_CLAUSE91_EN;
3612 cfg->link_fec_opt |= ICE_AQC_PHY_FEC_25G_RS_528_REQ |
3613 ICE_AQC_PHY_FEC_25G_RS_544_REQ;
3614 break;
3615 case ICE_FEC_NONE:
3616 /* Clear all FEC option bits. */
3617 cfg->link_fec_opt &= ~ICE_AQC_PHY_FEC_MASK;
3618 break;
3619 case ICE_FEC_AUTO:
3620 /* AND auto FEC bit, and all caps bits. */
3621 cfg->caps &= ICE_AQC_PHY_CAPS_MASK;
3622 cfg->link_fec_opt |= pcaps->link_fec_options;
3623 break;
3624 default:
3625 status = -EINVAL;
3626 break;
3627 }
3628
3629 if (fec == ICE_FEC_AUTO && ice_fw_supports_link_override(hw) &&
3630 !ice_fw_supports_report_dflt_cfg(hw)) {
3631 struct ice_link_default_override_tlv tlv = { 0 };
3632
3633 status = ice_get_link_default_override(&tlv, pi);
3634 if (status)
3635 goto out;
3636
3637 if (!(tlv.options & ICE_LINK_OVERRIDE_STRICT_MODE) &&
3638 (tlv.options & ICE_LINK_OVERRIDE_EN))
3639 cfg->link_fec_opt = tlv.fec_options;
3640 }
3641
3642out:
3643 return status;
3644}
3645
3646/**
3647 * ice_get_link_status - get status of the HW network link
3648 * @pi: port information structure
3649 * @link_up: pointer to bool (true/false = linkup/linkdown)
3650 *
3651 * Variable link_up is true if link is up, false if link is down.
3652 * The variable link_up is invalid if status is non zero. As a
3653 * result of this call, link status reporting becomes enabled
3654 */
3655int ice_get_link_status(struct ice_port_info *pi, bool *link_up)
3656{
3657 struct ice_phy_info *phy_info;
3658 int status = 0;
3659
3660 if (!pi || !link_up)
3661 return -EINVAL;
3662
3663 phy_info = &pi->phy;
3664
3665 if (phy_info->get_link_info) {
3666 status = ice_update_link_info(pi);
3667
3668 if (status)
3669 ice_debug(pi->hw, ICE_DBG_LINK, "get link status error, status = %d\n",
3670 status);
3671 }
3672
3673 *link_up = phy_info->link_info.link_info & ICE_AQ_LINK_UP;
3674
3675 return status;
3676}
3677
3678/**
3679 * ice_aq_set_link_restart_an
3680 * @pi: pointer to the port information structure
3681 * @ena_link: if true: enable link, if false: disable link
3682 * @cd: pointer to command details structure or NULL
3683 *
3684 * Sets up the link and restarts the Auto-Negotiation over the link.
3685 */
3686int
3687ice_aq_set_link_restart_an(struct ice_port_info *pi, bool ena_link,
3688 struct ice_sq_cd *cd)
3689{
3690 struct ice_aqc_restart_an *cmd;
3691 struct ice_aq_desc desc;
3692
3693 cmd = &desc.params.restart_an;
3694
3695 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_restart_an);
3696
3697 cmd->cmd_flags = ICE_AQC_RESTART_AN_LINK_RESTART;
3698 cmd->lport_num = pi->lport;
3699 if (ena_link)
3700 cmd->cmd_flags |= ICE_AQC_RESTART_AN_LINK_ENABLE;
3701 else
3702 cmd->cmd_flags &= ~ICE_AQC_RESTART_AN_LINK_ENABLE;
3703
3704 return ice_aq_send_cmd(pi->hw, &desc, NULL, 0, cd);
3705}
3706
3707/**
3708 * ice_aq_set_event_mask
3709 * @hw: pointer to the HW struct
3710 * @port_num: port number of the physical function
3711 * @mask: event mask to be set
3712 * @cd: pointer to command details structure or NULL
3713 *
3714 * Set event mask (0x0613)
3715 */
3716int
3717ice_aq_set_event_mask(struct ice_hw *hw, u8 port_num, u16 mask,
3718 struct ice_sq_cd *cd)
3719{
3720 struct ice_aqc_set_event_mask *cmd;
3721 struct ice_aq_desc desc;
3722
3723 cmd = &desc.params.set_event_mask;
3724
3725 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_event_mask);
3726
3727 cmd->lport_num = port_num;
3728
3729 cmd->event_mask = cpu_to_le16(mask);
3730 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3731}
3732
3733/**
3734 * ice_aq_set_mac_loopback
3735 * @hw: pointer to the HW struct
3736 * @ena_lpbk: Enable or Disable loopback
3737 * @cd: pointer to command details structure or NULL
3738 *
3739 * Enable/disable loopback on a given port
3740 */
3741int
3742ice_aq_set_mac_loopback(struct ice_hw *hw, bool ena_lpbk, struct ice_sq_cd *cd)
3743{
3744 struct ice_aqc_set_mac_lb *cmd;
3745 struct ice_aq_desc desc;
3746
3747 cmd = &desc.params.set_mac_lb;
3748
3749 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_mac_lb);
3750 if (ena_lpbk)
3751 cmd->lb_mode = ICE_AQ_MAC_LB_EN;
3752
3753 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3754}
3755
3756/**
3757 * ice_aq_set_port_id_led
3758 * @pi: pointer to the port information
3759 * @is_orig_mode: is this LED set to original mode (by the net-list)
3760 * @cd: pointer to command details structure or NULL
3761 *
3762 * Set LED value for the given port (0x06e9)
3763 */
3764int
3765ice_aq_set_port_id_led(struct ice_port_info *pi, bool is_orig_mode,
3766 struct ice_sq_cd *cd)
3767{
3768 struct ice_aqc_set_port_id_led *cmd;
3769 struct ice_hw *hw = pi->hw;
3770 struct ice_aq_desc desc;
3771
3772 cmd = &desc.params.set_port_id_led;
3773
3774 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_id_led);
3775
3776 if (is_orig_mode)
3777 cmd->ident_mode = ICE_AQC_PORT_IDENT_LED_ORIG;
3778 else
3779 cmd->ident_mode = ICE_AQC_PORT_IDENT_LED_BLINK;
3780
3781 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
3782}
3783
3784/**
3785 * ice_aq_get_port_options
3786 * @hw: pointer to the HW struct
3787 * @options: buffer for the resultant port options
3788 * @option_count: input - size of the buffer in port options structures,
3789 * output - number of returned port options
3790 * @lport: logical port to call the command with (optional)
3791 * @lport_valid: when false, FW uses port owned by the PF instead of lport,
3792 * when PF owns more than 1 port it must be true
3793 * @active_option_idx: index of active port option in returned buffer
3794 * @active_option_valid: active option in returned buffer is valid
3795 * @pending_option_idx: index of pending port option in returned buffer
3796 * @pending_option_valid: pending option in returned buffer is valid
3797 *
3798 * Calls Get Port Options AQC (0x06ea) and verifies result.
3799 */
3800int
3801ice_aq_get_port_options(struct ice_hw *hw,
3802 struct ice_aqc_get_port_options_elem *options,
3803 u8 *option_count, u8 lport, bool lport_valid,
3804 u8 *active_option_idx, bool *active_option_valid,
3805 u8 *pending_option_idx, bool *pending_option_valid)
3806{
3807 struct ice_aqc_get_port_options *cmd;
3808 struct ice_aq_desc desc;
3809 int status;
3810 u8 i;
3811
3812 /* options buffer shall be able to hold max returned options */
3813 if (*option_count < ICE_AQC_PORT_OPT_COUNT_M)
3814 return -EINVAL;
3815
3816 cmd = &desc.params.get_port_options;
3817 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_port_options);
3818
3819 if (lport_valid)
3820 cmd->lport_num = lport;
3821 cmd->lport_num_valid = lport_valid;
3822
3823 status = ice_aq_send_cmd(hw, &desc, options,
3824 *option_count * sizeof(*options), NULL);
3825 if (status)
3826 return status;
3827
3828 /* verify direct FW response & set output parameters */
3829 *option_count = FIELD_GET(ICE_AQC_PORT_OPT_COUNT_M,
3830 cmd->port_options_count);
3831 ice_debug(hw, ICE_DBG_PHY, "options: %x\n", *option_count);
3832 *active_option_valid = FIELD_GET(ICE_AQC_PORT_OPT_VALID,
3833 cmd->port_options);
3834 if (*active_option_valid) {
3835 *active_option_idx = FIELD_GET(ICE_AQC_PORT_OPT_ACTIVE_M,
3836 cmd->port_options);
3837 if (*active_option_idx > (*option_count - 1))
3838 return -EIO;
3839 ice_debug(hw, ICE_DBG_PHY, "active idx: %x\n",
3840 *active_option_idx);
3841 }
3842
3843 *pending_option_valid = FIELD_GET(ICE_AQC_PENDING_PORT_OPT_VALID,
3844 cmd->pending_port_option_status);
3845 if (*pending_option_valid) {
3846 *pending_option_idx = FIELD_GET(ICE_AQC_PENDING_PORT_OPT_IDX_M,
3847 cmd->pending_port_option_status);
3848 if (*pending_option_idx > (*option_count - 1))
3849 return -EIO;
3850 ice_debug(hw, ICE_DBG_PHY, "pending idx: %x\n",
3851 *pending_option_idx);
3852 }
3853
3854 /* mask output options fields */
3855 for (i = 0; i < *option_count; i++) {
3856 options[i].pmd = FIELD_GET(ICE_AQC_PORT_OPT_PMD_COUNT_M,
3857 options[i].pmd);
3858 options[i].max_lane_speed = FIELD_GET(ICE_AQC_PORT_OPT_MAX_LANE_M,
3859 options[i].max_lane_speed);
3860 ice_debug(hw, ICE_DBG_PHY, "pmds: %x max speed: %x\n",
3861 options[i].pmd, options[i].max_lane_speed);
3862 }
3863
3864 return 0;
3865}
3866
3867/**
3868 * ice_aq_set_port_option
3869 * @hw: pointer to the HW struct
3870 * @lport: logical port to call the command with
3871 * @lport_valid: when false, FW uses port owned by the PF instead of lport,
3872 * when PF owns more than 1 port it must be true
3873 * @new_option: new port option to be written
3874 *
3875 * Calls Set Port Options AQC (0x06eb).
3876 */
3877int
3878ice_aq_set_port_option(struct ice_hw *hw, u8 lport, u8 lport_valid,
3879 u8 new_option)
3880{
3881 struct ice_aqc_set_port_option *cmd;
3882 struct ice_aq_desc desc;
3883
3884 if (new_option > ICE_AQC_PORT_OPT_COUNT_M)
3885 return -EINVAL;
3886
3887 cmd = &desc.params.set_port_option;
3888 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_port_option);
3889
3890 if (lport_valid)
3891 cmd->lport_num = lport;
3892
3893 cmd->lport_num_valid = lport_valid;
3894 cmd->selected_port_option = new_option;
3895
3896 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
3897}
3898
3899/**
3900 * ice_aq_sff_eeprom
3901 * @hw: pointer to the HW struct
3902 * @lport: bits [7:0] = logical port, bit [8] = logical port valid
3903 * @bus_addr: I2C bus address of the eeprom (typically 0xA0, 0=topo default)
3904 * @mem_addr: I2C offset. lower 8 bits for address, 8 upper bits zero padding.
3905 * @page: QSFP page
3906 * @set_page: set or ignore the page
3907 * @data: pointer to data buffer to be read/written to the I2C device.
3908 * @length: 1-16 for read, 1 for write.
3909 * @write: 0 read, 1 for write.
3910 * @cd: pointer to command details structure or NULL
3911 *
3912 * Read/Write SFF EEPROM (0x06EE)
3913 */
3914int
3915ice_aq_sff_eeprom(struct ice_hw *hw, u16 lport, u8 bus_addr,
3916 u16 mem_addr, u8 page, u8 set_page, u8 *data, u8 length,
3917 bool write, struct ice_sq_cd *cd)
3918{
3919 struct ice_aqc_sff_eeprom *cmd;
3920 struct ice_aq_desc desc;
3921 u16 i2c_bus_addr;
3922 int status;
3923
3924 if (!data || (mem_addr & 0xff00))
3925 return -EINVAL;
3926
3927 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_sff_eeprom);
3928 cmd = &desc.params.read_write_sff_param;
3929 desc.flags = cpu_to_le16(ICE_AQ_FLAG_RD);
3930 cmd->lport_num = (u8)(lport & 0xff);
3931 cmd->lport_num_valid = (u8)((lport >> 8) & 0x01);
3932 i2c_bus_addr = FIELD_PREP(ICE_AQC_SFF_I2CBUS_7BIT_M, bus_addr >> 1) |
3933 FIELD_PREP(ICE_AQC_SFF_SET_EEPROM_PAGE_M, set_page);
3934 if (write)
3935 i2c_bus_addr |= ICE_AQC_SFF_IS_WRITE;
3936 cmd->i2c_bus_addr = cpu_to_le16(i2c_bus_addr);
3937 cmd->i2c_mem_addr = cpu_to_le16(mem_addr & 0xff);
3938 cmd->eeprom_page = le16_encode_bits(page, ICE_AQC_SFF_EEPROM_PAGE_M);
3939
3940 status = ice_aq_send_cmd(hw, &desc, data, length, cd);
3941 return status;
3942}
3943
3944static enum ice_lut_size ice_lut_type_to_size(enum ice_lut_type type)
3945{
3946 switch (type) {
3947 case ICE_LUT_VSI:
3948 return ICE_LUT_VSI_SIZE;
3949 case ICE_LUT_GLOBAL:
3950 return ICE_LUT_GLOBAL_SIZE;
3951 case ICE_LUT_PF:
3952 return ICE_LUT_PF_SIZE;
3953 }
3954 WARN_ONCE(1, "incorrect type passed");
3955 return ICE_LUT_VSI_SIZE;
3956}
3957
3958static enum ice_aqc_lut_flags ice_lut_size_to_flag(enum ice_lut_size size)
3959{
3960 switch (size) {
3961 case ICE_LUT_VSI_SIZE:
3962 return ICE_AQC_LUT_SIZE_SMALL;
3963 case ICE_LUT_GLOBAL_SIZE:
3964 return ICE_AQC_LUT_SIZE_512;
3965 case ICE_LUT_PF_SIZE:
3966 return ICE_AQC_LUT_SIZE_2K;
3967 }
3968 WARN_ONCE(1, "incorrect size passed");
3969 return 0;
3970}
3971
3972/**
3973 * __ice_aq_get_set_rss_lut
3974 * @hw: pointer to the hardware structure
3975 * @params: RSS LUT parameters
3976 * @set: set true to set the table, false to get the table
3977 *
3978 * Internal function to get (0x0B05) or set (0x0B03) RSS look up table
3979 */
3980static int
3981__ice_aq_get_set_rss_lut(struct ice_hw *hw,
3982 struct ice_aq_get_set_rss_lut_params *params, bool set)
3983{
3984 u16 opcode, vsi_id, vsi_handle = params->vsi_handle, glob_lut_idx = 0;
3985 enum ice_lut_type lut_type = params->lut_type;
3986 struct ice_aqc_get_set_rss_lut *desc_params;
3987 enum ice_aqc_lut_flags flags;
3988 enum ice_lut_size lut_size;
3989 struct ice_aq_desc desc;
3990 u8 *lut = params->lut;
3991
3992
3993 if (!lut || !ice_is_vsi_valid(hw, vsi_handle))
3994 return -EINVAL;
3995
3996 lut_size = ice_lut_type_to_size(lut_type);
3997 if (lut_size > params->lut_size)
3998 return -EINVAL;
3999 else if (set && lut_size != params->lut_size)
4000 return -EINVAL;
4001
4002 opcode = set ? ice_aqc_opc_set_rss_lut : ice_aqc_opc_get_rss_lut;
4003 ice_fill_dflt_direct_cmd_desc(&desc, opcode);
4004 if (set)
4005 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4006
4007 desc_params = &desc.params.get_set_rss_lut;
4008 vsi_id = ice_get_hw_vsi_num(hw, vsi_handle);
4009 desc_params->vsi_id = cpu_to_le16(vsi_id | ICE_AQC_RSS_VSI_VALID);
4010
4011 if (lut_type == ICE_LUT_GLOBAL)
4012 glob_lut_idx = FIELD_PREP(ICE_AQC_LUT_GLOBAL_IDX,
4013 params->global_lut_id);
4014
4015 flags = lut_type | glob_lut_idx | ice_lut_size_to_flag(lut_size);
4016 desc_params->flags = cpu_to_le16(flags);
4017
4018 return ice_aq_send_cmd(hw, &desc, lut, lut_size, NULL);
4019}
4020
4021/**
4022 * ice_aq_get_rss_lut
4023 * @hw: pointer to the hardware structure
4024 * @get_params: RSS LUT parameters used to specify which RSS LUT to get
4025 *
4026 * get the RSS lookup table, PF or VSI type
4027 */
4028int
4029ice_aq_get_rss_lut(struct ice_hw *hw, struct ice_aq_get_set_rss_lut_params *get_params)
4030{
4031 return __ice_aq_get_set_rss_lut(hw, get_params, false);
4032}
4033
4034/**
4035 * ice_aq_set_rss_lut
4036 * @hw: pointer to the hardware structure
4037 * @set_params: RSS LUT parameters used to specify how to set the RSS LUT
4038 *
4039 * set the RSS lookup table, PF or VSI type
4040 */
4041int
4042ice_aq_set_rss_lut(struct ice_hw *hw, struct ice_aq_get_set_rss_lut_params *set_params)
4043{
4044 return __ice_aq_get_set_rss_lut(hw, set_params, true);
4045}
4046
4047/**
4048 * __ice_aq_get_set_rss_key
4049 * @hw: pointer to the HW struct
4050 * @vsi_id: VSI FW index
4051 * @key: pointer to key info struct
4052 * @set: set true to set the key, false to get the key
4053 *
4054 * get (0x0B04) or set (0x0B02) the RSS key per VSI
4055 */
4056static int
4057__ice_aq_get_set_rss_key(struct ice_hw *hw, u16 vsi_id,
4058 struct ice_aqc_get_set_rss_keys *key, bool set)
4059{
4060 struct ice_aqc_get_set_rss_key *desc_params;
4061 u16 key_size = sizeof(*key);
4062 struct ice_aq_desc desc;
4063
4064 if (set) {
4065 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_rss_key);
4066 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4067 } else {
4068 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_rss_key);
4069 }
4070
4071 desc_params = &desc.params.get_set_rss_key;
4072 desc_params->vsi_id = cpu_to_le16(vsi_id | ICE_AQC_RSS_VSI_VALID);
4073
4074 return ice_aq_send_cmd(hw, &desc, key, key_size, NULL);
4075}
4076
4077/**
4078 * ice_aq_get_rss_key
4079 * @hw: pointer to the HW struct
4080 * @vsi_handle: software VSI handle
4081 * @key: pointer to key info struct
4082 *
4083 * get the RSS key per VSI
4084 */
4085int
4086ice_aq_get_rss_key(struct ice_hw *hw, u16 vsi_handle,
4087 struct ice_aqc_get_set_rss_keys *key)
4088{
4089 if (!ice_is_vsi_valid(hw, vsi_handle) || !key)
4090 return -EINVAL;
4091
4092 return __ice_aq_get_set_rss_key(hw, ice_get_hw_vsi_num(hw, vsi_handle),
4093 key, false);
4094}
4095
4096/**
4097 * ice_aq_set_rss_key
4098 * @hw: pointer to the HW struct
4099 * @vsi_handle: software VSI handle
4100 * @keys: pointer to key info struct
4101 *
4102 * set the RSS key per VSI
4103 */
4104int
4105ice_aq_set_rss_key(struct ice_hw *hw, u16 vsi_handle,
4106 struct ice_aqc_get_set_rss_keys *keys)
4107{
4108 if (!ice_is_vsi_valid(hw, vsi_handle) || !keys)
4109 return -EINVAL;
4110
4111 return __ice_aq_get_set_rss_key(hw, ice_get_hw_vsi_num(hw, vsi_handle),
4112 keys, true);
4113}
4114
4115/**
4116 * ice_aq_add_lan_txq
4117 * @hw: pointer to the hardware structure
4118 * @num_qgrps: Number of added queue groups
4119 * @qg_list: list of queue groups to be added
4120 * @buf_size: size of buffer for indirect command
4121 * @cd: pointer to command details structure or NULL
4122 *
4123 * Add Tx LAN queue (0x0C30)
4124 *
4125 * NOTE:
4126 * Prior to calling add Tx LAN queue:
4127 * Initialize the following as part of the Tx queue context:
4128 * Completion queue ID if the queue uses Completion queue, Quanta profile,
4129 * Cache profile and Packet shaper profile.
4130 *
4131 * After add Tx LAN queue AQ command is completed:
4132 * Interrupts should be associated with specific queues,
4133 * Association of Tx queue to Doorbell queue is not part of Add LAN Tx queue
4134 * flow.
4135 */
4136static int
4137ice_aq_add_lan_txq(struct ice_hw *hw, u8 num_qgrps,
4138 struct ice_aqc_add_tx_qgrp *qg_list, u16 buf_size,
4139 struct ice_sq_cd *cd)
4140{
4141 struct ice_aqc_add_tx_qgrp *list;
4142 struct ice_aqc_add_txqs *cmd;
4143 struct ice_aq_desc desc;
4144 u16 i, sum_size = 0;
4145
4146 cmd = &desc.params.add_txqs;
4147
4148 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_add_txqs);
4149
4150 if (!qg_list)
4151 return -EINVAL;
4152
4153 if (num_qgrps > ICE_LAN_TXQ_MAX_QGRPS)
4154 return -EINVAL;
4155
4156 for (i = 0, list = qg_list; i < num_qgrps; i++) {
4157 sum_size += struct_size(list, txqs, list->num_txqs);
4158 list = (struct ice_aqc_add_tx_qgrp *)(list->txqs +
4159 list->num_txqs);
4160 }
4161
4162 if (buf_size != sum_size)
4163 return -EINVAL;
4164
4165 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4166
4167 cmd->num_qgrps = num_qgrps;
4168
4169 return ice_aq_send_cmd(hw, &desc, qg_list, buf_size, cd);
4170}
4171
4172/**
4173 * ice_aq_dis_lan_txq
4174 * @hw: pointer to the hardware structure
4175 * @num_qgrps: number of groups in the list
4176 * @qg_list: the list of groups to disable
4177 * @buf_size: the total size of the qg_list buffer in bytes
4178 * @rst_src: if called due to reset, specifies the reset source
4179 * @vmvf_num: the relative VM or VF number that is undergoing the reset
4180 * @cd: pointer to command details structure or NULL
4181 *
4182 * Disable LAN Tx queue (0x0C31)
4183 */
4184static int
4185ice_aq_dis_lan_txq(struct ice_hw *hw, u8 num_qgrps,
4186 struct ice_aqc_dis_txq_item *qg_list, u16 buf_size,
4187 enum ice_disq_rst_src rst_src, u16 vmvf_num,
4188 struct ice_sq_cd *cd)
4189{
4190 struct ice_aqc_dis_txq_item *item;
4191 struct ice_aqc_dis_txqs *cmd;
4192 struct ice_aq_desc desc;
4193 u16 vmvf_and_timeout;
4194 u16 i, sz = 0;
4195 int status;
4196
4197 cmd = &desc.params.dis_txqs;
4198 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_dis_txqs);
4199
4200 /* qg_list can be NULL only in VM/VF reset flow */
4201 if (!qg_list && !rst_src)
4202 return -EINVAL;
4203
4204 if (num_qgrps > ICE_LAN_TXQ_MAX_QGRPS)
4205 return -EINVAL;
4206
4207 cmd->num_entries = num_qgrps;
4208
4209 vmvf_and_timeout = FIELD_PREP(ICE_AQC_Q_DIS_TIMEOUT_M, 5);
4210
4211 switch (rst_src) {
4212 case ICE_VM_RESET:
4213 cmd->cmd_type = ICE_AQC_Q_DIS_CMD_VM_RESET;
4214 vmvf_and_timeout |= vmvf_num & ICE_AQC_Q_DIS_VMVF_NUM_M;
4215 break;
4216 case ICE_VF_RESET:
4217 cmd->cmd_type = ICE_AQC_Q_DIS_CMD_VF_RESET;
4218 /* In this case, FW expects vmvf_num to be absolute VF ID */
4219 vmvf_and_timeout |= (vmvf_num + hw->func_caps.vf_base_id) &
4220 ICE_AQC_Q_DIS_VMVF_NUM_M;
4221 break;
4222 case ICE_NO_RESET:
4223 default:
4224 break;
4225 }
4226
4227 cmd->vmvf_and_timeout = cpu_to_le16(vmvf_and_timeout);
4228
4229 /* flush pipe on time out */
4230 cmd->cmd_type |= ICE_AQC_Q_DIS_CMD_FLUSH_PIPE;
4231 /* If no queue group info, we are in a reset flow. Issue the AQ */
4232 if (!qg_list)
4233 goto do_aq;
4234
4235 /* set RD bit to indicate that command buffer is provided by the driver
4236 * and it needs to be read by the firmware
4237 */
4238 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4239
4240 for (i = 0, item = qg_list; i < num_qgrps; i++) {
4241 u16 item_size = struct_size(item, q_id, item->num_qs);
4242
4243 /* If the num of queues is even, add 2 bytes of padding */
4244 if ((item->num_qs % 2) == 0)
4245 item_size += 2;
4246
4247 sz += item_size;
4248
4249 item = (struct ice_aqc_dis_txq_item *)((u8 *)item + item_size);
4250 }
4251
4252 if (buf_size != sz)
4253 return -EINVAL;
4254
4255do_aq:
4256 status = ice_aq_send_cmd(hw, &desc, qg_list, buf_size, cd);
4257 if (status) {
4258 if (!qg_list)
4259 ice_debug(hw, ICE_DBG_SCHED, "VM%d disable failed %d\n",
4260 vmvf_num, hw->adminq.sq_last_status);
4261 else
4262 ice_debug(hw, ICE_DBG_SCHED, "disable queue %d failed %d\n",
4263 le16_to_cpu(qg_list[0].q_id[0]),
4264 hw->adminq.sq_last_status);
4265 }
4266 return status;
4267}
4268
4269/**
4270 * ice_aq_cfg_lan_txq
4271 * @hw: pointer to the hardware structure
4272 * @buf: buffer for command
4273 * @buf_size: size of buffer in bytes
4274 * @num_qs: number of queues being configured
4275 * @oldport: origination lport
4276 * @newport: destination lport
4277 * @cd: pointer to command details structure or NULL
4278 *
4279 * Move/Configure LAN Tx queue (0x0C32)
4280 *
4281 * There is a better AQ command to use for moving nodes, so only coding
4282 * this one for configuring the node.
4283 */
4284int
4285ice_aq_cfg_lan_txq(struct ice_hw *hw, struct ice_aqc_cfg_txqs_buf *buf,
4286 u16 buf_size, u16 num_qs, u8 oldport, u8 newport,
4287 struct ice_sq_cd *cd)
4288{
4289 struct ice_aqc_cfg_txqs *cmd;
4290 struct ice_aq_desc desc;
4291 int status;
4292
4293 cmd = &desc.params.cfg_txqs;
4294 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_cfg_txqs);
4295 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4296
4297 if (!buf)
4298 return -EINVAL;
4299
4300 cmd->cmd_type = ICE_AQC_Q_CFG_TC_CHNG;
4301 cmd->num_qs = num_qs;
4302 cmd->port_num_chng = (oldport & ICE_AQC_Q_CFG_SRC_PRT_M);
4303 cmd->port_num_chng |= FIELD_PREP(ICE_AQC_Q_CFG_DST_PRT_M, newport);
4304 cmd->time_out = FIELD_PREP(ICE_AQC_Q_CFG_TIMEOUT_M, 5);
4305 cmd->blocked_cgds = 0;
4306
4307 status = ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
4308 if (status)
4309 ice_debug(hw, ICE_DBG_SCHED, "Failed to reconfigure nodes %d\n",
4310 hw->adminq.sq_last_status);
4311 return status;
4312}
4313
4314/**
4315 * ice_aq_add_rdma_qsets
4316 * @hw: pointer to the hardware structure
4317 * @num_qset_grps: Number of RDMA Qset groups
4318 * @qset_list: list of Qset groups to be added
4319 * @buf_size: size of buffer for indirect command
4320 * @cd: pointer to command details structure or NULL
4321 *
4322 * Add Tx RDMA Qsets (0x0C33)
4323 */
4324static int
4325ice_aq_add_rdma_qsets(struct ice_hw *hw, u8 num_qset_grps,
4326 struct ice_aqc_add_rdma_qset_data *qset_list,
4327 u16 buf_size, struct ice_sq_cd *cd)
4328{
4329 struct ice_aqc_add_rdma_qset_data *list;
4330 struct ice_aqc_add_rdma_qset *cmd;
4331 struct ice_aq_desc desc;
4332 u16 i, sum_size = 0;
4333
4334 cmd = &desc.params.add_rdma_qset;
4335
4336 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_add_rdma_qset);
4337
4338 if (num_qset_grps > ICE_LAN_TXQ_MAX_QGRPS)
4339 return -EINVAL;
4340
4341 for (i = 0, list = qset_list; i < num_qset_grps; i++) {
4342 u16 num_qsets = le16_to_cpu(list->num_qsets);
4343
4344 sum_size += struct_size(list, rdma_qsets, num_qsets);
4345 list = (struct ice_aqc_add_rdma_qset_data *)(list->rdma_qsets +
4346 num_qsets);
4347 }
4348
4349 if (buf_size != sum_size)
4350 return -EINVAL;
4351
4352 desc.flags |= cpu_to_le16(ICE_AQ_FLAG_RD);
4353
4354 cmd->num_qset_grps = num_qset_grps;
4355
4356 return ice_aq_send_cmd(hw, &desc, qset_list, buf_size, cd);
4357}
4358
4359/* End of FW Admin Queue command wrappers */
4360
4361/**
4362 * ice_pack_ctx_byte - write a byte to a packed context structure
4363 * @src_ctx: unpacked source context structure
4364 * @dest_ctx: packed destination context data
4365 * @ce_info: context element description
4366 */
4367static void ice_pack_ctx_byte(u8 *src_ctx, u8 *dest_ctx,
4368 const struct ice_ctx_ele *ce_info)
4369{
4370 u8 src_byte, dest_byte, mask;
4371 u8 *from, *dest;
4372 u16 shift_width;
4373
4374 /* copy from the next struct field */
4375 from = src_ctx + ce_info->offset;
4376
4377 /* prepare the bits and mask */
4378 shift_width = ce_info->lsb % 8;
4379 mask = GENMASK(ce_info->width - 1 + shift_width, shift_width);
4380
4381 src_byte = *from;
4382 src_byte <<= shift_width;
4383 src_byte &= mask;
4384
4385 /* get the current bits from the target bit string */
4386 dest = dest_ctx + (ce_info->lsb / 8);
4387
4388 memcpy(&dest_byte, dest, sizeof(dest_byte));
4389
4390 dest_byte &= ~mask; /* get the bits not changing */
4391 dest_byte |= src_byte; /* add in the new bits */
4392
4393 /* put it all back */
4394 memcpy(dest, &dest_byte, sizeof(dest_byte));
4395}
4396
4397/**
4398 * ice_pack_ctx_word - write a word to a packed context structure
4399 * @src_ctx: unpacked source context structure
4400 * @dest_ctx: packed destination context data
4401 * @ce_info: context element description
4402 */
4403static void ice_pack_ctx_word(u8 *src_ctx, u8 *dest_ctx,
4404 const struct ice_ctx_ele *ce_info)
4405{
4406 u16 src_word, mask;
4407 __le16 dest_word;
4408 u8 *from, *dest;
4409 u16 shift_width;
4410
4411 /* copy from the next struct field */
4412 from = src_ctx + ce_info->offset;
4413
4414 /* prepare the bits and mask */
4415 shift_width = ce_info->lsb % 8;
4416 mask = GENMASK(ce_info->width - 1 + shift_width, shift_width);
4417
4418 /* don't swizzle the bits until after the mask because the mask bits
4419 * will be in a different bit position on big endian machines
4420 */
4421 src_word = *(u16 *)from;
4422 src_word <<= shift_width;
4423 src_word &= mask;
4424
4425 /* get the current bits from the target bit string */
4426 dest = dest_ctx + (ce_info->lsb / 8);
4427
4428 memcpy(&dest_word, dest, sizeof(dest_word));
4429
4430 dest_word &= ~(cpu_to_le16(mask)); /* get the bits not changing */
4431 dest_word |= cpu_to_le16(src_word); /* add in the new bits */
4432
4433 /* put it all back */
4434 memcpy(dest, &dest_word, sizeof(dest_word));
4435}
4436
4437/**
4438 * ice_pack_ctx_dword - write a dword to a packed context structure
4439 * @src_ctx: unpacked source context structure
4440 * @dest_ctx: packed destination context data
4441 * @ce_info: context element description
4442 */
4443static void ice_pack_ctx_dword(u8 *src_ctx, u8 *dest_ctx,
4444 const struct ice_ctx_ele *ce_info)
4445{
4446 u32 src_dword, mask;
4447 __le32 dest_dword;
4448 u8 *from, *dest;
4449 u16 shift_width;
4450
4451 /* copy from the next struct field */
4452 from = src_ctx + ce_info->offset;
4453
4454 /* prepare the bits and mask */
4455 shift_width = ce_info->lsb % 8;
4456 mask = GENMASK(ce_info->width - 1 + shift_width, shift_width);
4457
4458 /* don't swizzle the bits until after the mask because the mask bits
4459 * will be in a different bit position on big endian machines
4460 */
4461 src_dword = *(u32 *)from;
4462 src_dword <<= shift_width;
4463 src_dword &= mask;
4464
4465 /* get the current bits from the target bit string */
4466 dest = dest_ctx + (ce_info->lsb / 8);
4467
4468 memcpy(&dest_dword, dest, sizeof(dest_dword));
4469
4470 dest_dword &= ~(cpu_to_le32(mask)); /* get the bits not changing */
4471 dest_dword |= cpu_to_le32(src_dword); /* add in the new bits */
4472
4473 /* put it all back */
4474 memcpy(dest, &dest_dword, sizeof(dest_dword));
4475}
4476
4477/**
4478 * ice_pack_ctx_qword - write a qword to a packed context structure
4479 * @src_ctx: unpacked source context structure
4480 * @dest_ctx: packed destination context data
4481 * @ce_info: context element description
4482 */
4483static void ice_pack_ctx_qword(u8 *src_ctx, u8 *dest_ctx,
4484 const struct ice_ctx_ele *ce_info)
4485{
4486 u64 src_qword, mask;
4487 __le64 dest_qword;
4488 u8 *from, *dest;
4489 u16 shift_width;
4490
4491 /* copy from the next struct field */
4492 from = src_ctx + ce_info->offset;
4493
4494 /* prepare the bits and mask */
4495 shift_width = ce_info->lsb % 8;
4496 mask = GENMASK_ULL(ce_info->width - 1 + shift_width, shift_width);
4497
4498 /* don't swizzle the bits until after the mask because the mask bits
4499 * will be in a different bit position on big endian machines
4500 */
4501 src_qword = *(u64 *)from;
4502 src_qword <<= shift_width;
4503 src_qword &= mask;
4504
4505 /* get the current bits from the target bit string */
4506 dest = dest_ctx + (ce_info->lsb / 8);
4507
4508 memcpy(&dest_qword, dest, sizeof(dest_qword));
4509
4510 dest_qword &= ~(cpu_to_le64(mask)); /* get the bits not changing */
4511 dest_qword |= cpu_to_le64(src_qword); /* add in the new bits */
4512
4513 /* put it all back */
4514 memcpy(dest, &dest_qword, sizeof(dest_qword));
4515}
4516
4517/**
4518 * ice_set_ctx - set context bits in packed structure
4519 * @hw: pointer to the hardware structure
4520 * @src_ctx: pointer to a generic non-packed context structure
4521 * @dest_ctx: pointer to memory for the packed structure
4522 * @ce_info: List of Rx context elements
4523 */
4524int ice_set_ctx(struct ice_hw *hw, u8 *src_ctx, u8 *dest_ctx,
4525 const struct ice_ctx_ele *ce_info)
4526{
4527 int f;
4528
4529 for (f = 0; ce_info[f].width; f++) {
4530 /* We have to deal with each element of the FW response
4531 * using the correct size so that we are correct regardless
4532 * of the endianness of the machine.
4533 */
4534 if (ce_info[f].width > (ce_info[f].size_of * BITS_PER_BYTE)) {
4535 ice_debug(hw, ICE_DBG_QCTX, "Field %d width of %d bits larger than size of %d byte(s) ... skipping write\n",
4536 f, ce_info[f].width, ce_info[f].size_of);
4537 continue;
4538 }
4539 switch (ce_info[f].size_of) {
4540 case sizeof(u8):
4541 ice_pack_ctx_byte(src_ctx, dest_ctx, &ce_info[f]);
4542 break;
4543 case sizeof(u16):
4544 ice_pack_ctx_word(src_ctx, dest_ctx, &ce_info[f]);
4545 break;
4546 case sizeof(u32):
4547 ice_pack_ctx_dword(src_ctx, dest_ctx, &ce_info[f]);
4548 break;
4549 case sizeof(u64):
4550 ice_pack_ctx_qword(src_ctx, dest_ctx, &ce_info[f]);
4551 break;
4552 default:
4553 return -EINVAL;
4554 }
4555 }
4556
4557 return 0;
4558}
4559
4560/**
4561 * ice_get_lan_q_ctx - get the LAN queue context for the given VSI and TC
4562 * @hw: pointer to the HW struct
4563 * @vsi_handle: software VSI handle
4564 * @tc: TC number
4565 * @q_handle: software queue handle
4566 */
4567struct ice_q_ctx *
4568ice_get_lan_q_ctx(struct ice_hw *hw, u16 vsi_handle, u8 tc, u16 q_handle)
4569{
4570 struct ice_vsi_ctx *vsi;
4571 struct ice_q_ctx *q_ctx;
4572
4573 vsi = ice_get_vsi_ctx(hw, vsi_handle);
4574 if (!vsi)
4575 return NULL;
4576 if (q_handle >= vsi->num_lan_q_entries[tc])
4577 return NULL;
4578 if (!vsi->lan_q_ctx[tc])
4579 return NULL;
4580 q_ctx = vsi->lan_q_ctx[tc];
4581 return &q_ctx[q_handle];
4582}
4583
4584/**
4585 * ice_ena_vsi_txq
4586 * @pi: port information structure
4587 * @vsi_handle: software VSI handle
4588 * @tc: TC number
4589 * @q_handle: software queue handle
4590 * @num_qgrps: Number of added queue groups
4591 * @buf: list of queue groups to be added
4592 * @buf_size: size of buffer for indirect command
4593 * @cd: pointer to command details structure or NULL
4594 *
4595 * This function adds one LAN queue
4596 */
4597int
4598ice_ena_vsi_txq(struct ice_port_info *pi, u16 vsi_handle, u8 tc, u16 q_handle,
4599 u8 num_qgrps, struct ice_aqc_add_tx_qgrp *buf, u16 buf_size,
4600 struct ice_sq_cd *cd)
4601{
4602 struct ice_aqc_txsched_elem_data node = { 0 };
4603 struct ice_sched_node *parent;
4604 struct ice_q_ctx *q_ctx;
4605 struct ice_hw *hw;
4606 int status;
4607
4608 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4609 return -EIO;
4610
4611 if (num_qgrps > 1 || buf->num_txqs > 1)
4612 return -ENOSPC;
4613
4614 hw = pi->hw;
4615
4616 if (!ice_is_vsi_valid(hw, vsi_handle))
4617 return -EINVAL;
4618
4619 mutex_lock(&pi->sched_lock);
4620
4621 q_ctx = ice_get_lan_q_ctx(hw, vsi_handle, tc, q_handle);
4622 if (!q_ctx) {
4623 ice_debug(hw, ICE_DBG_SCHED, "Enaq: invalid queue handle %d\n",
4624 q_handle);
4625 status = -EINVAL;
4626 goto ena_txq_exit;
4627 }
4628
4629 /* find a parent node */
4630 parent = ice_sched_get_free_qparent(pi, vsi_handle, tc,
4631 ICE_SCHED_NODE_OWNER_LAN);
4632 if (!parent) {
4633 status = -EINVAL;
4634 goto ena_txq_exit;
4635 }
4636
4637 buf->parent_teid = parent->info.node_teid;
4638 node.parent_teid = parent->info.node_teid;
4639 /* Mark that the values in the "generic" section as valid. The default
4640 * value in the "generic" section is zero. This means that :
4641 * - Scheduling mode is Bytes Per Second (BPS), indicated by Bit 0.
4642 * - 0 priority among siblings, indicated by Bit 1-3.
4643 * - WFQ, indicated by Bit 4.
4644 * - 0 Adjustment value is used in PSM credit update flow, indicated by
4645 * Bit 5-6.
4646 * - Bit 7 is reserved.
4647 * Without setting the generic section as valid in valid_sections, the
4648 * Admin queue command will fail with error code ICE_AQ_RC_EINVAL.
4649 */
4650 buf->txqs[0].info.valid_sections =
4651 ICE_AQC_ELEM_VALID_GENERIC | ICE_AQC_ELEM_VALID_CIR |
4652 ICE_AQC_ELEM_VALID_EIR;
4653 buf->txqs[0].info.generic = 0;
4654 buf->txqs[0].info.cir_bw.bw_profile_idx =
4655 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4656 buf->txqs[0].info.cir_bw.bw_alloc =
4657 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4658 buf->txqs[0].info.eir_bw.bw_profile_idx =
4659 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4660 buf->txqs[0].info.eir_bw.bw_alloc =
4661 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4662
4663 /* add the LAN queue */
4664 status = ice_aq_add_lan_txq(hw, num_qgrps, buf, buf_size, cd);
4665 if (status) {
4666 ice_debug(hw, ICE_DBG_SCHED, "enable queue %d failed %d\n",
4667 le16_to_cpu(buf->txqs[0].txq_id),
4668 hw->adminq.sq_last_status);
4669 goto ena_txq_exit;
4670 }
4671
4672 node.node_teid = buf->txqs[0].q_teid;
4673 node.data.elem_type = ICE_AQC_ELEM_TYPE_LEAF;
4674 q_ctx->q_handle = q_handle;
4675 q_ctx->q_teid = le32_to_cpu(node.node_teid);
4676
4677 /* add a leaf node into scheduler tree queue layer */
4678 status = ice_sched_add_node(pi, hw->num_tx_sched_layers - 1, &node, NULL);
4679 if (!status)
4680 status = ice_sched_replay_q_bw(pi, q_ctx);
4681
4682ena_txq_exit:
4683 mutex_unlock(&pi->sched_lock);
4684 return status;
4685}
4686
4687/**
4688 * ice_dis_vsi_txq
4689 * @pi: port information structure
4690 * @vsi_handle: software VSI handle
4691 * @tc: TC number
4692 * @num_queues: number of queues
4693 * @q_handles: pointer to software queue handle array
4694 * @q_ids: pointer to the q_id array
4695 * @q_teids: pointer to queue node teids
4696 * @rst_src: if called due to reset, specifies the reset source
4697 * @vmvf_num: the relative VM or VF number that is undergoing the reset
4698 * @cd: pointer to command details structure or NULL
4699 *
4700 * This function removes queues and their corresponding nodes in SW DB
4701 */
4702int
4703ice_dis_vsi_txq(struct ice_port_info *pi, u16 vsi_handle, u8 tc, u8 num_queues,
4704 u16 *q_handles, u16 *q_ids, u32 *q_teids,
4705 enum ice_disq_rst_src rst_src, u16 vmvf_num,
4706 struct ice_sq_cd *cd)
4707{
4708 DEFINE_RAW_FLEX(struct ice_aqc_dis_txq_item, qg_list, q_id, 1);
4709 u16 i, buf_size = __struct_size(qg_list);
4710 struct ice_q_ctx *q_ctx;
4711 int status = -ENOENT;
4712 struct ice_hw *hw;
4713
4714 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4715 return -EIO;
4716
4717 hw = pi->hw;
4718
4719 if (!num_queues) {
4720 /* if queue is disabled already yet the disable queue command
4721 * has to be sent to complete the VF reset, then call
4722 * ice_aq_dis_lan_txq without any queue information
4723 */
4724 if (rst_src)
4725 return ice_aq_dis_lan_txq(hw, 0, NULL, 0, rst_src,
4726 vmvf_num, NULL);
4727 return -EIO;
4728 }
4729
4730 mutex_lock(&pi->sched_lock);
4731
4732 for (i = 0; i < num_queues; i++) {
4733 struct ice_sched_node *node;
4734
4735 node = ice_sched_find_node_by_teid(pi->root, q_teids[i]);
4736 if (!node)
4737 continue;
4738 q_ctx = ice_get_lan_q_ctx(hw, vsi_handle, tc, q_handles[i]);
4739 if (!q_ctx) {
4740 ice_debug(hw, ICE_DBG_SCHED, "invalid queue handle%d\n",
4741 q_handles[i]);
4742 continue;
4743 }
4744 if (q_ctx->q_handle != q_handles[i]) {
4745 ice_debug(hw, ICE_DBG_SCHED, "Err:handles %d %d\n",
4746 q_ctx->q_handle, q_handles[i]);
4747 continue;
4748 }
4749 qg_list->parent_teid = node->info.parent_teid;
4750 qg_list->num_qs = 1;
4751 qg_list->q_id[0] = cpu_to_le16(q_ids[i]);
4752 status = ice_aq_dis_lan_txq(hw, 1, qg_list, buf_size, rst_src,
4753 vmvf_num, cd);
4754
4755 if (status)
4756 break;
4757 ice_free_sched_node(pi, node);
4758 q_ctx->q_handle = ICE_INVAL_Q_HANDLE;
4759 q_ctx->q_teid = ICE_INVAL_TEID;
4760 }
4761 mutex_unlock(&pi->sched_lock);
4762 return status;
4763}
4764
4765/**
4766 * ice_cfg_vsi_qs - configure the new/existing VSI queues
4767 * @pi: port information structure
4768 * @vsi_handle: software VSI handle
4769 * @tc_bitmap: TC bitmap
4770 * @maxqs: max queues array per TC
4771 * @owner: LAN or RDMA
4772 *
4773 * This function adds/updates the VSI queues per TC.
4774 */
4775static int
4776ice_cfg_vsi_qs(struct ice_port_info *pi, u16 vsi_handle, u8 tc_bitmap,
4777 u16 *maxqs, u8 owner)
4778{
4779 int status = 0;
4780 u8 i;
4781
4782 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4783 return -EIO;
4784
4785 if (!ice_is_vsi_valid(pi->hw, vsi_handle))
4786 return -EINVAL;
4787
4788 mutex_lock(&pi->sched_lock);
4789
4790 ice_for_each_traffic_class(i) {
4791 /* configuration is possible only if TC node is present */
4792 if (!ice_sched_get_tc_node(pi, i))
4793 continue;
4794
4795 status = ice_sched_cfg_vsi(pi, vsi_handle, i, maxqs[i], owner,
4796 ice_is_tc_ena(tc_bitmap, i));
4797 if (status)
4798 break;
4799 }
4800
4801 mutex_unlock(&pi->sched_lock);
4802 return status;
4803}
4804
4805/**
4806 * ice_cfg_vsi_lan - configure VSI LAN queues
4807 * @pi: port information structure
4808 * @vsi_handle: software VSI handle
4809 * @tc_bitmap: TC bitmap
4810 * @max_lanqs: max LAN queues array per TC
4811 *
4812 * This function adds/updates the VSI LAN queues per TC.
4813 */
4814int
4815ice_cfg_vsi_lan(struct ice_port_info *pi, u16 vsi_handle, u8 tc_bitmap,
4816 u16 *max_lanqs)
4817{
4818 return ice_cfg_vsi_qs(pi, vsi_handle, tc_bitmap, max_lanqs,
4819 ICE_SCHED_NODE_OWNER_LAN);
4820}
4821
4822/**
4823 * ice_cfg_vsi_rdma - configure the VSI RDMA queues
4824 * @pi: port information structure
4825 * @vsi_handle: software VSI handle
4826 * @tc_bitmap: TC bitmap
4827 * @max_rdmaqs: max RDMA queues array per TC
4828 *
4829 * This function adds/updates the VSI RDMA queues per TC.
4830 */
4831int
4832ice_cfg_vsi_rdma(struct ice_port_info *pi, u16 vsi_handle, u16 tc_bitmap,
4833 u16 *max_rdmaqs)
4834{
4835 return ice_cfg_vsi_qs(pi, vsi_handle, tc_bitmap, max_rdmaqs,
4836 ICE_SCHED_NODE_OWNER_RDMA);
4837}
4838
4839/**
4840 * ice_ena_vsi_rdma_qset
4841 * @pi: port information structure
4842 * @vsi_handle: software VSI handle
4843 * @tc: TC number
4844 * @rdma_qset: pointer to RDMA Qset
4845 * @num_qsets: number of RDMA Qsets
4846 * @qset_teid: pointer to Qset node TEIDs
4847 *
4848 * This function adds RDMA Qset
4849 */
4850int
4851ice_ena_vsi_rdma_qset(struct ice_port_info *pi, u16 vsi_handle, u8 tc,
4852 u16 *rdma_qset, u16 num_qsets, u32 *qset_teid)
4853{
4854 struct ice_aqc_txsched_elem_data node = { 0 };
4855 struct ice_aqc_add_rdma_qset_data *buf;
4856 struct ice_sched_node *parent;
4857 struct ice_hw *hw;
4858 u16 i, buf_size;
4859 int ret;
4860
4861 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4862 return -EIO;
4863 hw = pi->hw;
4864
4865 if (!ice_is_vsi_valid(hw, vsi_handle))
4866 return -EINVAL;
4867
4868 buf_size = struct_size(buf, rdma_qsets, num_qsets);
4869 buf = kzalloc(buf_size, GFP_KERNEL);
4870 if (!buf)
4871 return -ENOMEM;
4872 mutex_lock(&pi->sched_lock);
4873
4874 parent = ice_sched_get_free_qparent(pi, vsi_handle, tc,
4875 ICE_SCHED_NODE_OWNER_RDMA);
4876 if (!parent) {
4877 ret = -EINVAL;
4878 goto rdma_error_exit;
4879 }
4880 buf->parent_teid = parent->info.node_teid;
4881 node.parent_teid = parent->info.node_teid;
4882
4883 buf->num_qsets = cpu_to_le16(num_qsets);
4884 for (i = 0; i < num_qsets; i++) {
4885 buf->rdma_qsets[i].tx_qset_id = cpu_to_le16(rdma_qset[i]);
4886 buf->rdma_qsets[i].info.valid_sections =
4887 ICE_AQC_ELEM_VALID_GENERIC | ICE_AQC_ELEM_VALID_CIR |
4888 ICE_AQC_ELEM_VALID_EIR;
4889 buf->rdma_qsets[i].info.generic = 0;
4890 buf->rdma_qsets[i].info.cir_bw.bw_profile_idx =
4891 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4892 buf->rdma_qsets[i].info.cir_bw.bw_alloc =
4893 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4894 buf->rdma_qsets[i].info.eir_bw.bw_profile_idx =
4895 cpu_to_le16(ICE_SCHED_DFLT_RL_PROF_ID);
4896 buf->rdma_qsets[i].info.eir_bw.bw_alloc =
4897 cpu_to_le16(ICE_SCHED_DFLT_BW_WT);
4898 }
4899 ret = ice_aq_add_rdma_qsets(hw, 1, buf, buf_size, NULL);
4900 if (ret) {
4901 ice_debug(hw, ICE_DBG_RDMA, "add RDMA qset failed\n");
4902 goto rdma_error_exit;
4903 }
4904 node.data.elem_type = ICE_AQC_ELEM_TYPE_LEAF;
4905 for (i = 0; i < num_qsets; i++) {
4906 node.node_teid = buf->rdma_qsets[i].qset_teid;
4907 ret = ice_sched_add_node(pi, hw->num_tx_sched_layers - 1,
4908 &node, NULL);
4909 if (ret)
4910 break;
4911 qset_teid[i] = le32_to_cpu(node.node_teid);
4912 }
4913rdma_error_exit:
4914 mutex_unlock(&pi->sched_lock);
4915 kfree(buf);
4916 return ret;
4917}
4918
4919/**
4920 * ice_dis_vsi_rdma_qset - free RDMA resources
4921 * @pi: port_info struct
4922 * @count: number of RDMA Qsets to free
4923 * @qset_teid: TEID of Qset node
4924 * @q_id: list of queue IDs being disabled
4925 */
4926int
4927ice_dis_vsi_rdma_qset(struct ice_port_info *pi, u16 count, u32 *qset_teid,
4928 u16 *q_id)
4929{
4930 DEFINE_RAW_FLEX(struct ice_aqc_dis_txq_item, qg_list, q_id, 1);
4931 u16 qg_size = __struct_size(qg_list);
4932 struct ice_hw *hw;
4933 int status = 0;
4934 int i;
4935
4936 if (!pi || pi->port_state != ICE_SCHED_PORT_STATE_READY)
4937 return -EIO;
4938
4939 hw = pi->hw;
4940
4941 mutex_lock(&pi->sched_lock);
4942
4943 for (i = 0; i < count; i++) {
4944 struct ice_sched_node *node;
4945
4946 node = ice_sched_find_node_by_teid(pi->root, qset_teid[i]);
4947 if (!node)
4948 continue;
4949
4950 qg_list->parent_teid = node->info.parent_teid;
4951 qg_list->num_qs = 1;
4952 qg_list->q_id[0] =
4953 cpu_to_le16(q_id[i] |
4954 ICE_AQC_Q_DIS_BUF_ELEM_TYPE_RDMA_QSET);
4955
4956 status = ice_aq_dis_lan_txq(hw, 1, qg_list, qg_size,
4957 ICE_NO_RESET, 0, NULL);
4958 if (status)
4959 break;
4960
4961 ice_free_sched_node(pi, node);
4962 }
4963
4964 mutex_unlock(&pi->sched_lock);
4965 return status;
4966}
4967
4968/**
4969 * ice_aq_get_cgu_abilities - get cgu abilities
4970 * @hw: pointer to the HW struct
4971 * @abilities: CGU abilities
4972 *
4973 * Get CGU abilities (0x0C61)
4974 * Return: 0 on success or negative value on failure.
4975 */
4976int
4977ice_aq_get_cgu_abilities(struct ice_hw *hw,
4978 struct ice_aqc_get_cgu_abilities *abilities)
4979{
4980 struct ice_aq_desc desc;
4981
4982 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_abilities);
4983 return ice_aq_send_cmd(hw, &desc, abilities, sizeof(*abilities), NULL);
4984}
4985
4986/**
4987 * ice_aq_set_input_pin_cfg - set input pin config
4988 * @hw: pointer to the HW struct
4989 * @input_idx: Input index
4990 * @flags1: Input flags
4991 * @flags2: Input flags
4992 * @freq: Frequency in Hz
4993 * @phase_delay: Delay in ps
4994 *
4995 * Set CGU input config (0x0C62)
4996 * Return: 0 on success or negative value on failure.
4997 */
4998int
4999ice_aq_set_input_pin_cfg(struct ice_hw *hw, u8 input_idx, u8 flags1, u8 flags2,
5000 u32 freq, s32 phase_delay)
5001{
5002 struct ice_aqc_set_cgu_input_config *cmd;
5003 struct ice_aq_desc desc;
5004
5005 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_input_config);
5006 cmd = &desc.params.set_cgu_input_config;
5007 cmd->input_idx = input_idx;
5008 cmd->flags1 = flags1;
5009 cmd->flags2 = flags2;
5010 cmd->freq = cpu_to_le32(freq);
5011 cmd->phase_delay = cpu_to_le32(phase_delay);
5012
5013 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5014}
5015
5016/**
5017 * ice_aq_get_input_pin_cfg - get input pin config
5018 * @hw: pointer to the HW struct
5019 * @input_idx: Input index
5020 * @status: Pin status
5021 * @type: Pin type
5022 * @flags1: Input flags
5023 * @flags2: Input flags
5024 * @freq: Frequency in Hz
5025 * @phase_delay: Delay in ps
5026 *
5027 * Get CGU input config (0x0C63)
5028 * Return: 0 on success or negative value on failure.
5029 */
5030int
5031ice_aq_get_input_pin_cfg(struct ice_hw *hw, u8 input_idx, u8 *status, u8 *type,
5032 u8 *flags1, u8 *flags2, u32 *freq, s32 *phase_delay)
5033{
5034 struct ice_aqc_get_cgu_input_config *cmd;
5035 struct ice_aq_desc desc;
5036 int ret;
5037
5038 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_input_config);
5039 cmd = &desc.params.get_cgu_input_config;
5040 cmd->input_idx = input_idx;
5041
5042 ret = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5043 if (!ret) {
5044 if (status)
5045 *status = cmd->status;
5046 if (type)
5047 *type = cmd->type;
5048 if (flags1)
5049 *flags1 = cmd->flags1;
5050 if (flags2)
5051 *flags2 = cmd->flags2;
5052 if (freq)
5053 *freq = le32_to_cpu(cmd->freq);
5054 if (phase_delay)
5055 *phase_delay = le32_to_cpu(cmd->phase_delay);
5056 }
5057
5058 return ret;
5059}
5060
5061/**
5062 * ice_aq_set_output_pin_cfg - set output pin config
5063 * @hw: pointer to the HW struct
5064 * @output_idx: Output index
5065 * @flags: Output flags
5066 * @src_sel: Index of DPLL block
5067 * @freq: Output frequency
5068 * @phase_delay: Output phase compensation
5069 *
5070 * Set CGU output config (0x0C64)
5071 * Return: 0 on success or negative value on failure.
5072 */
5073int
5074ice_aq_set_output_pin_cfg(struct ice_hw *hw, u8 output_idx, u8 flags,
5075 u8 src_sel, u32 freq, s32 phase_delay)
5076{
5077 struct ice_aqc_set_cgu_output_config *cmd;
5078 struct ice_aq_desc desc;
5079
5080 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_output_config);
5081 cmd = &desc.params.set_cgu_output_config;
5082 cmd->output_idx = output_idx;
5083 cmd->flags = flags;
5084 cmd->src_sel = src_sel;
5085 cmd->freq = cpu_to_le32(freq);
5086 cmd->phase_delay = cpu_to_le32(phase_delay);
5087
5088 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5089}
5090
5091/**
5092 * ice_aq_get_output_pin_cfg - get output pin config
5093 * @hw: pointer to the HW struct
5094 * @output_idx: Output index
5095 * @flags: Output flags
5096 * @src_sel: Internal DPLL source
5097 * @freq: Output frequency
5098 * @src_freq: Source frequency
5099 *
5100 * Get CGU output config (0x0C65)
5101 * Return: 0 on success or negative value on failure.
5102 */
5103int
5104ice_aq_get_output_pin_cfg(struct ice_hw *hw, u8 output_idx, u8 *flags,
5105 u8 *src_sel, u32 *freq, u32 *src_freq)
5106{
5107 struct ice_aqc_get_cgu_output_config *cmd;
5108 struct ice_aq_desc desc;
5109 int ret;
5110
5111 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_output_config);
5112 cmd = &desc.params.get_cgu_output_config;
5113 cmd->output_idx = output_idx;
5114
5115 ret = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5116 if (!ret) {
5117 if (flags)
5118 *flags = cmd->flags;
5119 if (src_sel)
5120 *src_sel = cmd->src_sel;
5121 if (freq)
5122 *freq = le32_to_cpu(cmd->freq);
5123 if (src_freq)
5124 *src_freq = le32_to_cpu(cmd->src_freq);
5125 }
5126
5127 return ret;
5128}
5129
5130/**
5131 * ice_aq_get_cgu_dpll_status - get dpll status
5132 * @hw: pointer to the HW struct
5133 * @dpll_num: DPLL index
5134 * @ref_state: Reference clock state
5135 * @config: current DPLL config
5136 * @dpll_state: current DPLL state
5137 * @phase_offset: Phase offset in ns
5138 * @eec_mode: EEC_mode
5139 *
5140 * Get CGU DPLL status (0x0C66)
5141 * Return: 0 on success or negative value on failure.
5142 */
5143int
5144ice_aq_get_cgu_dpll_status(struct ice_hw *hw, u8 dpll_num, u8 *ref_state,
5145 u8 *dpll_state, u8 *config, s64 *phase_offset,
5146 u8 *eec_mode)
5147{
5148 struct ice_aqc_get_cgu_dpll_status *cmd;
5149 struct ice_aq_desc desc;
5150 int status;
5151
5152 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_dpll_status);
5153 cmd = &desc.params.get_cgu_dpll_status;
5154 cmd->dpll_num = dpll_num;
5155
5156 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5157 if (!status) {
5158 *ref_state = cmd->ref_state;
5159 *dpll_state = cmd->dpll_state;
5160 *config = cmd->config;
5161 *phase_offset = le32_to_cpu(cmd->phase_offset_h);
5162 *phase_offset <<= 32;
5163 *phase_offset += le32_to_cpu(cmd->phase_offset_l);
5164 *phase_offset = sign_extend64(*phase_offset, 47);
5165 *eec_mode = cmd->eec_mode;
5166 }
5167
5168 return status;
5169}
5170
5171/**
5172 * ice_aq_set_cgu_dpll_config - set dpll config
5173 * @hw: pointer to the HW struct
5174 * @dpll_num: DPLL index
5175 * @ref_state: Reference clock state
5176 * @config: DPLL config
5177 * @eec_mode: EEC mode
5178 *
5179 * Set CGU DPLL config (0x0C67)
5180 * Return: 0 on success or negative value on failure.
5181 */
5182int
5183ice_aq_set_cgu_dpll_config(struct ice_hw *hw, u8 dpll_num, u8 ref_state,
5184 u8 config, u8 eec_mode)
5185{
5186 struct ice_aqc_set_cgu_dpll_config *cmd;
5187 struct ice_aq_desc desc;
5188
5189 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_dpll_config);
5190 cmd = &desc.params.set_cgu_dpll_config;
5191 cmd->dpll_num = dpll_num;
5192 cmd->ref_state = ref_state;
5193 cmd->config = config;
5194 cmd->eec_mode = eec_mode;
5195
5196 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5197}
5198
5199/**
5200 * ice_aq_set_cgu_ref_prio - set input reference priority
5201 * @hw: pointer to the HW struct
5202 * @dpll_num: DPLL index
5203 * @ref_idx: Reference pin index
5204 * @ref_priority: Reference input priority
5205 *
5206 * Set CGU reference priority (0x0C68)
5207 * Return: 0 on success or negative value on failure.
5208 */
5209int
5210ice_aq_set_cgu_ref_prio(struct ice_hw *hw, u8 dpll_num, u8 ref_idx,
5211 u8 ref_priority)
5212{
5213 struct ice_aqc_set_cgu_ref_prio *cmd;
5214 struct ice_aq_desc desc;
5215
5216 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_cgu_ref_prio);
5217 cmd = &desc.params.set_cgu_ref_prio;
5218 cmd->dpll_num = dpll_num;
5219 cmd->ref_idx = ref_idx;
5220 cmd->ref_priority = ref_priority;
5221
5222 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5223}
5224
5225/**
5226 * ice_aq_get_cgu_ref_prio - get input reference priority
5227 * @hw: pointer to the HW struct
5228 * @dpll_num: DPLL index
5229 * @ref_idx: Reference pin index
5230 * @ref_prio: Reference input priority
5231 *
5232 * Get CGU reference priority (0x0C69)
5233 * Return: 0 on success or negative value on failure.
5234 */
5235int
5236ice_aq_get_cgu_ref_prio(struct ice_hw *hw, u8 dpll_num, u8 ref_idx,
5237 u8 *ref_prio)
5238{
5239 struct ice_aqc_get_cgu_ref_prio *cmd;
5240 struct ice_aq_desc desc;
5241 int status;
5242
5243 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_ref_prio);
5244 cmd = &desc.params.get_cgu_ref_prio;
5245 cmd->dpll_num = dpll_num;
5246 cmd->ref_idx = ref_idx;
5247
5248 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5249 if (!status)
5250 *ref_prio = cmd->ref_priority;
5251
5252 return status;
5253}
5254
5255/**
5256 * ice_aq_get_cgu_info - get cgu info
5257 * @hw: pointer to the HW struct
5258 * @cgu_id: CGU ID
5259 * @cgu_cfg_ver: CGU config version
5260 * @cgu_fw_ver: CGU firmware version
5261 *
5262 * Get CGU info (0x0C6A)
5263 * Return: 0 on success or negative value on failure.
5264 */
5265int
5266ice_aq_get_cgu_info(struct ice_hw *hw, u32 *cgu_id, u32 *cgu_cfg_ver,
5267 u32 *cgu_fw_ver)
5268{
5269 struct ice_aqc_get_cgu_info *cmd;
5270 struct ice_aq_desc desc;
5271 int status;
5272
5273 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_cgu_info);
5274 cmd = &desc.params.get_cgu_info;
5275
5276 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5277 if (!status) {
5278 *cgu_id = le32_to_cpu(cmd->cgu_id);
5279 *cgu_cfg_ver = le32_to_cpu(cmd->cgu_cfg_ver);
5280 *cgu_fw_ver = le32_to_cpu(cmd->cgu_fw_ver);
5281 }
5282
5283 return status;
5284}
5285
5286/**
5287 * ice_aq_set_phy_rec_clk_out - set RCLK phy out
5288 * @hw: pointer to the HW struct
5289 * @phy_output: PHY reference clock output pin
5290 * @enable: GPIO state to be applied
5291 * @freq: PHY output frequency
5292 *
5293 * Set phy recovered clock as reference (0x0630)
5294 * Return: 0 on success or negative value on failure.
5295 */
5296int
5297ice_aq_set_phy_rec_clk_out(struct ice_hw *hw, u8 phy_output, bool enable,
5298 u32 *freq)
5299{
5300 struct ice_aqc_set_phy_rec_clk_out *cmd;
5301 struct ice_aq_desc desc;
5302 int status;
5303
5304 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_phy_rec_clk_out);
5305 cmd = &desc.params.set_phy_rec_clk_out;
5306 cmd->phy_output = phy_output;
5307 cmd->port_num = ICE_AQC_SET_PHY_REC_CLK_OUT_CURR_PORT;
5308 cmd->flags = enable & ICE_AQC_SET_PHY_REC_CLK_OUT_OUT_EN;
5309 cmd->freq = cpu_to_le32(*freq);
5310
5311 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5312 if (!status)
5313 *freq = le32_to_cpu(cmd->freq);
5314
5315 return status;
5316}
5317
5318/**
5319 * ice_aq_get_phy_rec_clk_out - get phy recovered signal info
5320 * @hw: pointer to the HW struct
5321 * @phy_output: PHY reference clock output pin
5322 * @port_num: Port number
5323 * @flags: PHY flags
5324 * @node_handle: PHY output frequency
5325 *
5326 * Get PHY recovered clock output info (0x0631)
5327 * Return: 0 on success or negative value on failure.
5328 */
5329int
5330ice_aq_get_phy_rec_clk_out(struct ice_hw *hw, u8 *phy_output, u8 *port_num,
5331 u8 *flags, u16 *node_handle)
5332{
5333 struct ice_aqc_get_phy_rec_clk_out *cmd;
5334 struct ice_aq_desc desc;
5335 int status;
5336
5337 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_phy_rec_clk_out);
5338 cmd = &desc.params.get_phy_rec_clk_out;
5339 cmd->phy_output = *phy_output;
5340
5341 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5342 if (!status) {
5343 *phy_output = cmd->phy_output;
5344 if (port_num)
5345 *port_num = cmd->port_num;
5346 if (flags)
5347 *flags = cmd->flags;
5348 if (node_handle)
5349 *node_handle = le16_to_cpu(cmd->node_handle);
5350 }
5351
5352 return status;
5353}
5354
5355/**
5356 * ice_aq_get_sensor_reading
5357 * @hw: pointer to the HW struct
5358 * @data: pointer to data to be read from the sensor
5359 *
5360 * Get sensor reading (0x0632)
5361 */
5362int ice_aq_get_sensor_reading(struct ice_hw *hw,
5363 struct ice_aqc_get_sensor_reading_resp *data)
5364{
5365 struct ice_aqc_get_sensor_reading *cmd;
5366 struct ice_aq_desc desc;
5367 int status;
5368
5369 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_sensor_reading);
5370 cmd = &desc.params.get_sensor_reading;
5371#define ICE_INTERNAL_TEMP_SENSOR_FORMAT 0
5372#define ICE_INTERNAL_TEMP_SENSOR 0
5373 cmd->sensor = ICE_INTERNAL_TEMP_SENSOR;
5374 cmd->format = ICE_INTERNAL_TEMP_SENSOR_FORMAT;
5375
5376 status = ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5377 if (!status)
5378 memcpy(data, &desc.params.get_sensor_reading_resp,
5379 sizeof(*data));
5380
5381 return status;
5382}
5383
5384/**
5385 * ice_replay_pre_init - replay pre initialization
5386 * @hw: pointer to the HW struct
5387 *
5388 * Initializes required config data for VSI, FD, ACL, and RSS before replay.
5389 */
5390static int ice_replay_pre_init(struct ice_hw *hw)
5391{
5392 struct ice_switch_info *sw = hw->switch_info;
5393 u8 i;
5394
5395 /* Delete old entries from replay filter list head if there is any */
5396 ice_rm_all_sw_replay_rule_info(hw);
5397 /* In start of replay, move entries into replay_rules list, it
5398 * will allow adding rules entries back to filt_rules list,
5399 * which is operational list.
5400 */
5401 for (i = 0; i < ICE_MAX_NUM_RECIPES; i++)
5402 list_replace_init(&sw->recp_list[i].filt_rules,
5403 &sw->recp_list[i].filt_replay_rules);
5404 ice_sched_replay_agg_vsi_preinit(hw);
5405
5406 return 0;
5407}
5408
5409/**
5410 * ice_replay_vsi - replay VSI configuration
5411 * @hw: pointer to the HW struct
5412 * @vsi_handle: driver VSI handle
5413 *
5414 * Restore all VSI configuration after reset. It is required to call this
5415 * function with main VSI first.
5416 */
5417int ice_replay_vsi(struct ice_hw *hw, u16 vsi_handle)
5418{
5419 int status;
5420
5421 if (!ice_is_vsi_valid(hw, vsi_handle))
5422 return -EINVAL;
5423
5424 /* Replay pre-initialization if there is any */
5425 if (vsi_handle == ICE_MAIN_VSI_HANDLE) {
5426 status = ice_replay_pre_init(hw);
5427 if (status)
5428 return status;
5429 }
5430 /* Replay per VSI all RSS configurations */
5431 status = ice_replay_rss_cfg(hw, vsi_handle);
5432 if (status)
5433 return status;
5434 /* Replay per VSI all filters */
5435 status = ice_replay_vsi_all_fltr(hw, vsi_handle);
5436 if (!status)
5437 status = ice_replay_vsi_agg(hw, vsi_handle);
5438 return status;
5439}
5440
5441/**
5442 * ice_replay_post - post replay configuration cleanup
5443 * @hw: pointer to the HW struct
5444 *
5445 * Post replay cleanup.
5446 */
5447void ice_replay_post(struct ice_hw *hw)
5448{
5449 /* Delete old entries from replay filter list head */
5450 ice_rm_all_sw_replay_rule_info(hw);
5451 ice_sched_replay_agg(hw);
5452}
5453
5454/**
5455 * ice_stat_update40 - read 40 bit stat from the chip and update stat values
5456 * @hw: ptr to the hardware info
5457 * @reg: offset of 64 bit HW register to read from
5458 * @prev_stat_loaded: bool to specify if previous stats are loaded
5459 * @prev_stat: ptr to previous loaded stat value
5460 * @cur_stat: ptr to current stat value
5461 */
5462void
5463ice_stat_update40(struct ice_hw *hw, u32 reg, bool prev_stat_loaded,
5464 u64 *prev_stat, u64 *cur_stat)
5465{
5466 u64 new_data = rd64(hw, reg) & (BIT_ULL(40) - 1);
5467
5468 /* device stats are not reset at PFR, they likely will not be zeroed
5469 * when the driver starts. Thus, save the value from the first read
5470 * without adding to the statistic value so that we report stats which
5471 * count up from zero.
5472 */
5473 if (!prev_stat_loaded) {
5474 *prev_stat = new_data;
5475 return;
5476 }
5477
5478 /* Calculate the difference between the new and old values, and then
5479 * add it to the software stat value.
5480 */
5481 if (new_data >= *prev_stat)
5482 *cur_stat += new_data - *prev_stat;
5483 else
5484 /* to manage the potential roll-over */
5485 *cur_stat += (new_data + BIT_ULL(40)) - *prev_stat;
5486
5487 /* Update the previously stored value to prepare for next read */
5488 *prev_stat = new_data;
5489}
5490
5491/**
5492 * ice_stat_update32 - read 32 bit stat from the chip and update stat values
5493 * @hw: ptr to the hardware info
5494 * @reg: offset of HW register to read from
5495 * @prev_stat_loaded: bool to specify if previous stats are loaded
5496 * @prev_stat: ptr to previous loaded stat value
5497 * @cur_stat: ptr to current stat value
5498 */
5499void
5500ice_stat_update32(struct ice_hw *hw, u32 reg, bool prev_stat_loaded,
5501 u64 *prev_stat, u64 *cur_stat)
5502{
5503 u32 new_data;
5504
5505 new_data = rd32(hw, reg);
5506
5507 /* device stats are not reset at PFR, they likely will not be zeroed
5508 * when the driver starts. Thus, save the value from the first read
5509 * without adding to the statistic value so that we report stats which
5510 * count up from zero.
5511 */
5512 if (!prev_stat_loaded) {
5513 *prev_stat = new_data;
5514 return;
5515 }
5516
5517 /* Calculate the difference between the new and old values, and then
5518 * add it to the software stat value.
5519 */
5520 if (new_data >= *prev_stat)
5521 *cur_stat += new_data - *prev_stat;
5522 else
5523 /* to manage the potential roll-over */
5524 *cur_stat += (new_data + BIT_ULL(32)) - *prev_stat;
5525
5526 /* Update the previously stored value to prepare for next read */
5527 *prev_stat = new_data;
5528}
5529
5530/**
5531 * ice_sched_query_elem - query element information from HW
5532 * @hw: pointer to the HW struct
5533 * @node_teid: node TEID to be queried
5534 * @buf: buffer to element information
5535 *
5536 * This function queries HW element information
5537 */
5538int
5539ice_sched_query_elem(struct ice_hw *hw, u32 node_teid,
5540 struct ice_aqc_txsched_elem_data *buf)
5541{
5542 u16 buf_size, num_elem_ret = 0;
5543 int status;
5544
5545 buf_size = sizeof(*buf);
5546 memset(buf, 0, buf_size);
5547 buf->node_teid = cpu_to_le32(node_teid);
5548 status = ice_aq_query_sched_elems(hw, 1, buf, buf_size, &num_elem_ret,
5549 NULL);
5550 if (status || num_elem_ret != 1)
5551 ice_debug(hw, ICE_DBG_SCHED, "query element failed\n");
5552 return status;
5553}
5554
5555/**
5556 * ice_aq_read_i2c
5557 * @hw: pointer to the hw struct
5558 * @topo_addr: topology address for a device to communicate with
5559 * @bus_addr: 7-bit I2C bus address
5560 * @addr: I2C memory address (I2C offset) with up to 16 bits
5561 * @params: I2C parameters: bit [7] - Repeated start,
5562 * bits [6:5] data offset size,
5563 * bit [4] - I2C address type,
5564 * bits [3:0] - data size to read (0-16 bytes)
5565 * @data: pointer to data (0 to 16 bytes) to be read from the I2C device
5566 * @cd: pointer to command details structure or NULL
5567 *
5568 * Read I2C (0x06E2)
5569 */
5570int
5571ice_aq_read_i2c(struct ice_hw *hw, struct ice_aqc_link_topo_addr topo_addr,
5572 u16 bus_addr, __le16 addr, u8 params, u8 *data,
5573 struct ice_sq_cd *cd)
5574{
5575 struct ice_aq_desc desc = { 0 };
5576 struct ice_aqc_i2c *cmd;
5577 u8 data_size;
5578 int status;
5579
5580 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_read_i2c);
5581 cmd = &desc.params.read_write_i2c;
5582
5583 if (!data)
5584 return -EINVAL;
5585
5586 data_size = FIELD_GET(ICE_AQC_I2C_DATA_SIZE_M, params);
5587
5588 cmd->i2c_bus_addr = cpu_to_le16(bus_addr);
5589 cmd->topo_addr = topo_addr;
5590 cmd->i2c_params = params;
5591 cmd->i2c_addr = addr;
5592
5593 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5594 if (!status) {
5595 struct ice_aqc_read_i2c_resp *resp;
5596 u8 i;
5597
5598 resp = &desc.params.read_i2c_resp;
5599 for (i = 0; i < data_size; i++) {
5600 *data = resp->i2c_data[i];
5601 data++;
5602 }
5603 }
5604
5605 return status;
5606}
5607
5608/**
5609 * ice_aq_write_i2c
5610 * @hw: pointer to the hw struct
5611 * @topo_addr: topology address for a device to communicate with
5612 * @bus_addr: 7-bit I2C bus address
5613 * @addr: I2C memory address (I2C offset) with up to 16 bits
5614 * @params: I2C parameters: bit [4] - I2C address type, bits [3:0] - data size to write (0-7 bytes)
5615 * @data: pointer to data (0 to 4 bytes) to be written to the I2C device
5616 * @cd: pointer to command details structure or NULL
5617 *
5618 * Write I2C (0x06E3)
5619 *
5620 * * Return:
5621 * * 0 - Successful write to the i2c device
5622 * * -EINVAL - Data size greater than 4 bytes
5623 * * -EIO - FW error
5624 */
5625int
5626ice_aq_write_i2c(struct ice_hw *hw, struct ice_aqc_link_topo_addr topo_addr,
5627 u16 bus_addr, __le16 addr, u8 params, const u8 *data,
5628 struct ice_sq_cd *cd)
5629{
5630 struct ice_aq_desc desc = { 0 };
5631 struct ice_aqc_i2c *cmd;
5632 u8 data_size;
5633
5634 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_write_i2c);
5635 cmd = &desc.params.read_write_i2c;
5636
5637 data_size = FIELD_GET(ICE_AQC_I2C_DATA_SIZE_M, params);
5638
5639 /* data_size limited to 4 */
5640 if (data_size > 4)
5641 return -EINVAL;
5642
5643 cmd->i2c_bus_addr = cpu_to_le16(bus_addr);
5644 cmd->topo_addr = topo_addr;
5645 cmd->i2c_params = params;
5646 cmd->i2c_addr = addr;
5647
5648 memcpy(cmd->i2c_data, data, data_size);
5649
5650 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5651}
5652
5653/**
5654 * ice_aq_set_gpio
5655 * @hw: pointer to the hw struct
5656 * @gpio_ctrl_handle: GPIO controller node handle
5657 * @pin_idx: IO Number of the GPIO that needs to be set
5658 * @value: SW provide IO value to set in the LSB
5659 * @cd: pointer to command details structure or NULL
5660 *
5661 * Sends 0x06EC AQ command to set the GPIO pin state that's part of the topology
5662 */
5663int
5664ice_aq_set_gpio(struct ice_hw *hw, u16 gpio_ctrl_handle, u8 pin_idx, bool value,
5665 struct ice_sq_cd *cd)
5666{
5667 struct ice_aqc_gpio *cmd;
5668 struct ice_aq_desc desc;
5669
5670 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_gpio);
5671 cmd = &desc.params.read_write_gpio;
5672 cmd->gpio_ctrl_handle = cpu_to_le16(gpio_ctrl_handle);
5673 cmd->gpio_num = pin_idx;
5674 cmd->gpio_val = value ? 1 : 0;
5675
5676 return ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5677}
5678
5679/**
5680 * ice_aq_get_gpio
5681 * @hw: pointer to the hw struct
5682 * @gpio_ctrl_handle: GPIO controller node handle
5683 * @pin_idx: IO Number of the GPIO that needs to be set
5684 * @value: IO value read
5685 * @cd: pointer to command details structure or NULL
5686 *
5687 * Sends 0x06ED AQ command to get the value of a GPIO signal which is part of
5688 * the topology
5689 */
5690int
5691ice_aq_get_gpio(struct ice_hw *hw, u16 gpio_ctrl_handle, u8 pin_idx,
5692 bool *value, struct ice_sq_cd *cd)
5693{
5694 struct ice_aqc_gpio *cmd;
5695 struct ice_aq_desc desc;
5696 int status;
5697
5698 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_get_gpio);
5699 cmd = &desc.params.read_write_gpio;
5700 cmd->gpio_ctrl_handle = cpu_to_le16(gpio_ctrl_handle);
5701 cmd->gpio_num = pin_idx;
5702
5703 status = ice_aq_send_cmd(hw, &desc, NULL, 0, cd);
5704 if (status)
5705 return status;
5706
5707 *value = !!cmd->gpio_val;
5708 return 0;
5709}
5710
5711/**
5712 * ice_is_fw_api_min_ver
5713 * @hw: pointer to the hardware structure
5714 * @maj: major version
5715 * @min: minor version
5716 * @patch: patch version
5717 *
5718 * Checks if the firmware API is minimum version
5719 */
5720static bool ice_is_fw_api_min_ver(struct ice_hw *hw, u8 maj, u8 min, u8 patch)
5721{
5722 if (hw->api_maj_ver == maj) {
5723 if (hw->api_min_ver > min)
5724 return true;
5725 if (hw->api_min_ver == min && hw->api_patch >= patch)
5726 return true;
5727 } else if (hw->api_maj_ver > maj) {
5728 return true;
5729 }
5730
5731 return false;
5732}
5733
5734/**
5735 * ice_fw_supports_link_override
5736 * @hw: pointer to the hardware structure
5737 *
5738 * Checks if the firmware supports link override
5739 */
5740bool ice_fw_supports_link_override(struct ice_hw *hw)
5741{
5742 return ice_is_fw_api_min_ver(hw, ICE_FW_API_LINK_OVERRIDE_MAJ,
5743 ICE_FW_API_LINK_OVERRIDE_MIN,
5744 ICE_FW_API_LINK_OVERRIDE_PATCH);
5745}
5746
5747/**
5748 * ice_get_link_default_override
5749 * @ldo: pointer to the link default override struct
5750 * @pi: pointer to the port info struct
5751 *
5752 * Gets the link default override for a port
5753 */
5754int
5755ice_get_link_default_override(struct ice_link_default_override_tlv *ldo,
5756 struct ice_port_info *pi)
5757{
5758 u16 i, tlv, tlv_len, tlv_start, buf, offset;
5759 struct ice_hw *hw = pi->hw;
5760 int status;
5761
5762 status = ice_get_pfa_module_tlv(hw, &tlv, &tlv_len,
5763 ICE_SR_LINK_DEFAULT_OVERRIDE_PTR);
5764 if (status) {
5765 ice_debug(hw, ICE_DBG_INIT, "Failed to read link override TLV.\n");
5766 return status;
5767 }
5768
5769 /* Each port has its own config; calculate for our port */
5770 tlv_start = tlv + pi->lport * ICE_SR_PFA_LINK_OVERRIDE_WORDS +
5771 ICE_SR_PFA_LINK_OVERRIDE_OFFSET;
5772
5773 /* link options first */
5774 status = ice_read_sr_word(hw, tlv_start, &buf);
5775 if (status) {
5776 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5777 return status;
5778 }
5779 ldo->options = FIELD_GET(ICE_LINK_OVERRIDE_OPT_M, buf);
5780 ldo->phy_config = (buf & ICE_LINK_OVERRIDE_PHY_CFG_M) >>
5781 ICE_LINK_OVERRIDE_PHY_CFG_S;
5782
5783 /* link PHY config */
5784 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_FEC_OFFSET;
5785 status = ice_read_sr_word(hw, offset, &buf);
5786 if (status) {
5787 ice_debug(hw, ICE_DBG_INIT, "Failed to read override phy config.\n");
5788 return status;
5789 }
5790 ldo->fec_options = buf & ICE_LINK_OVERRIDE_FEC_OPT_M;
5791
5792 /* PHY types low */
5793 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_PHY_OFFSET;
5794 for (i = 0; i < ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS; i++) {
5795 status = ice_read_sr_word(hw, (offset + i), &buf);
5796 if (status) {
5797 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5798 return status;
5799 }
5800 /* shift 16 bits at a time to fill 64 bits */
5801 ldo->phy_type_low |= ((u64)buf << (i * 16));
5802 }
5803
5804 /* PHY types high */
5805 offset = tlv_start + ICE_SR_PFA_LINK_OVERRIDE_PHY_OFFSET +
5806 ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS;
5807 for (i = 0; i < ICE_SR_PFA_LINK_OVERRIDE_PHY_WORDS; i++) {
5808 status = ice_read_sr_word(hw, (offset + i), &buf);
5809 if (status) {
5810 ice_debug(hw, ICE_DBG_INIT, "Failed to read override link options.\n");
5811 return status;
5812 }
5813 /* shift 16 bits at a time to fill 64 bits */
5814 ldo->phy_type_high |= ((u64)buf << (i * 16));
5815 }
5816
5817 return status;
5818}
5819
5820/**
5821 * ice_is_phy_caps_an_enabled - check if PHY capabilities autoneg is enabled
5822 * @caps: get PHY capability data
5823 */
5824bool ice_is_phy_caps_an_enabled(struct ice_aqc_get_phy_caps_data *caps)
5825{
5826 if (caps->caps & ICE_AQC_PHY_AN_MODE ||
5827 caps->low_power_ctrl_an & (ICE_AQC_PHY_AN_EN_CLAUSE28 |
5828 ICE_AQC_PHY_AN_EN_CLAUSE73 |
5829 ICE_AQC_PHY_AN_EN_CLAUSE37))
5830 return true;
5831
5832 return false;
5833}
5834
5835/**
5836 * ice_aq_set_lldp_mib - Set the LLDP MIB
5837 * @hw: pointer to the HW struct
5838 * @mib_type: Local, Remote or both Local and Remote MIBs
5839 * @buf: pointer to the caller-supplied buffer to store the MIB block
5840 * @buf_size: size of the buffer (in bytes)
5841 * @cd: pointer to command details structure or NULL
5842 *
5843 * Set the LLDP MIB. (0x0A08)
5844 */
5845int
5846ice_aq_set_lldp_mib(struct ice_hw *hw, u8 mib_type, void *buf, u16 buf_size,
5847 struct ice_sq_cd *cd)
5848{
5849 struct ice_aqc_lldp_set_local_mib *cmd;
5850 struct ice_aq_desc desc;
5851
5852 cmd = &desc.params.lldp_set_mib;
5853
5854 if (buf_size == 0 || !buf)
5855 return -EINVAL;
5856
5857 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_set_local_mib);
5858
5859 desc.flags |= cpu_to_le16((u16)ICE_AQ_FLAG_RD);
5860 desc.datalen = cpu_to_le16(buf_size);
5861
5862 cmd->type = mib_type;
5863 cmd->length = cpu_to_le16(buf_size);
5864
5865 return ice_aq_send_cmd(hw, &desc, buf, buf_size, cd);
5866}
5867
5868/**
5869 * ice_fw_supports_lldp_fltr_ctrl - check NVM version supports lldp_fltr_ctrl
5870 * @hw: pointer to HW struct
5871 */
5872bool ice_fw_supports_lldp_fltr_ctrl(struct ice_hw *hw)
5873{
5874 if (hw->mac_type != ICE_MAC_E810)
5875 return false;
5876
5877 return ice_is_fw_api_min_ver(hw, ICE_FW_API_LLDP_FLTR_MAJ,
5878 ICE_FW_API_LLDP_FLTR_MIN,
5879 ICE_FW_API_LLDP_FLTR_PATCH);
5880}
5881
5882/**
5883 * ice_lldp_fltr_add_remove - add or remove a LLDP Rx switch filter
5884 * @hw: pointer to HW struct
5885 * @vsi_num: absolute HW index for VSI
5886 * @add: boolean for if adding or removing a filter
5887 */
5888int
5889ice_lldp_fltr_add_remove(struct ice_hw *hw, u16 vsi_num, bool add)
5890{
5891 struct ice_aqc_lldp_filter_ctrl *cmd;
5892 struct ice_aq_desc desc;
5893
5894 cmd = &desc.params.lldp_filter_ctrl;
5895
5896 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_filter_ctrl);
5897
5898 if (add)
5899 cmd->cmd_flags = ICE_AQC_LLDP_FILTER_ACTION_ADD;
5900 else
5901 cmd->cmd_flags = ICE_AQC_LLDP_FILTER_ACTION_DELETE;
5902
5903 cmd->vsi_num = cpu_to_le16(vsi_num);
5904
5905 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5906}
5907
5908/**
5909 * ice_lldp_execute_pending_mib - execute LLDP pending MIB request
5910 * @hw: pointer to HW struct
5911 */
5912int ice_lldp_execute_pending_mib(struct ice_hw *hw)
5913{
5914 struct ice_aq_desc desc;
5915
5916 ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_lldp_execute_pending_mib);
5917
5918 return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);
5919}
5920
5921/**
5922 * ice_fw_supports_report_dflt_cfg
5923 * @hw: pointer to the hardware structure
5924 *
5925 * Checks if the firmware supports report default configuration
5926 */
5927bool ice_fw_supports_report_dflt_cfg(struct ice_hw *hw)
5928{
5929 return ice_is_fw_api_min_ver(hw, ICE_FW_API_REPORT_DFLT_CFG_MAJ,
5930 ICE_FW_API_REPORT_DFLT_CFG_MIN,
5931 ICE_FW_API_REPORT_DFLT_CFG_PATCH);
5932}
5933
5934/* each of the indexes into the following array match the speed of a return
5935 * value from the list of AQ returned speeds like the range:
5936 * ICE_AQ_LINK_SPEED_10MB .. ICE_AQ_LINK_SPEED_100GB excluding
5937 * ICE_AQ_LINK_SPEED_UNKNOWN which is BIT(15) and maps to BIT(14) in this
5938 * array. The array is defined as 15 elements long because the link_speed
5939 * returned by the firmware is a 16 bit * value, but is indexed
5940 * by [fls(speed) - 1]
5941 */
5942static const u32 ice_aq_to_link_speed[] = {
5943 SPEED_10, /* BIT(0) */
5944 SPEED_100,
5945 SPEED_1000,
5946 SPEED_2500,
5947 SPEED_5000,
5948 SPEED_10000,
5949 SPEED_20000,
5950 SPEED_25000,
5951 SPEED_40000,
5952 SPEED_50000,
5953 SPEED_100000, /* BIT(10) */
5954 SPEED_200000,
5955};
5956
5957/**
5958 * ice_get_link_speed - get integer speed from table
5959 * @index: array index from fls(aq speed) - 1
5960 *
5961 * Returns: u32 value containing integer speed
5962 */
5963u32 ice_get_link_speed(u16 index)
5964{
5965 if (index >= ARRAY_SIZE(ice_aq_to_link_speed))
5966 return 0;
5967
5968 return ice_aq_to_link_speed[index];
5969}