ice: add fw and port health reporters

// SPDX-License-Identifier: GPL-2.0

/* Copyright (c) 2024, Intel Corporation. */

#include "health.h"

#include "ice.h"

#include "ice_adminq_cmd.h" /* for enum ice_aqc_health_status_elem */

#include "health.h"

#define ICE_DEVLINK_FMSG_PUT_FIELD(fmsg, obj, name) \

	devlink_fmsg_put(fmsg, #name, (obj)->name)

#define ICE_HEALTH_STATUS_DATA_SIZE 2

struct ice_health_status {

	enum ice_aqc_health_status code;

	const char *description;

	const char *solution;

	const char *data_label[ICE_HEALTH_STATUS_DATA_SIZE];

};

/*

 * In addition to the health status codes provided below, the firmware might

 * generate Health Status Codes that are not pertinent to the end-user.

 * For instance, Health Code 0x1002 is triggered when the command fails.

 * Such codes should be disregarded by the end-user.

 * The below lookup requires to be sorted by code.

 */

static const char *const ice_common_port_solutions =

	"Check your cable connection. Change or replace the module or cable. Manually set speed and duplex.";

static const char *const ice_port_number_label = "Port Number";

static const char *const ice_update_nvm_solution = "Update to the latest NVM image.";

static const struct ice_health_status ice_health_status_lookup[] = {

	{ICE_AQC_HEALTH_STATUS_ERR_UNKNOWN_MOD_STRICT, "An unsupported module was detected.",

		ice_common_port_solutions, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_MOD_TYPE, "Module type is not supported.",

		"Change or replace the module or cable.", {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_MOD_QUAL, "Module is not qualified.",

		ice_common_port_solutions, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_MOD_COMM,

		"Device cannot communicate with the module.",

		"Check your cable connection. Change or replace the module or cable. Manually set speed and duplex.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_MOD_CONFLICT, "Unresolved module conflict.",

		"Manually set speed/duplex or change the port option. If the problem persists, use a cable/module that is found in the supported modules and cables list for this device.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_MOD_NOT_PRESENT, "Module is not present.",

		"Check that the module is inserted correctly. If the problem persists, use a cable/module that is found in the supported modules and cables list for this device.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_INFO_MOD_UNDERUTILIZED, "Underutilized module.",

		"Change or replace the module or cable. Change the port option.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_UNKNOWN_MOD_LENIENT, "An unsupported module was detected.",

		ice_common_port_solutions, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_INVALID_LINK_CFG, "Invalid link configuration.",

		NULL, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_PORT_ACCESS, "Port hardware access error.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_PORT_UNREACHABLE, "A port is unreachable.",

		"Change the port option. Update to the latest NVM image."},

	{ICE_AQC_HEALTH_STATUS_INFO_PORT_SPEED_MOD_LIMITED, "Port speed is limited due to module.",

		"Change the module or configure the port option to match the current module speed. Change the port option.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_PARALLEL_FAULT,

		"All configured link modes were attempted but failed to establish link. The device will restart the process to establish link.",

		"Check link partner connection and configuration.",

		{ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_INFO_PORT_SPEED_PHY_LIMITED,

		"Port speed is limited by PHY capabilities.",

		"Change the module to align to port option.", {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_NETLIST_TOPO, "LOM topology netlist is corrupted.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_NETLIST, "Unrecoverable netlist error.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_TOPO_CONFLICT, "Port topology conflict.",

		"Change the port option. Update to the latest NVM image."},

	{ICE_AQC_HEALTH_STATUS_ERR_LINK_HW_ACCESS, "Unrecoverable hardware access error.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_LINK_RUNTIME, "Unrecoverable runtime error.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_DNL_INIT, "Link management engine failed to initialize.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_ERR_PHY_FW_LOAD,

		"Failed to load the firmware image in the external PHY.",

		ice_update_nvm_solution, {ice_port_number_label}},

	{ICE_AQC_HEALTH_STATUS_INFO_RECOVERY, "The device is in firmware recovery mode.",

		ice_update_nvm_solution, {"Extended Error"}},

	{ICE_AQC_HEALTH_STATUS_ERR_FLASH_ACCESS, "The flash chip cannot be accessed.",

		"If issue persists, call customer support.", {"Access Type"}},

	{ICE_AQC_HEALTH_STATUS_ERR_NVM_AUTH, "NVM authentication failed.",

		ice_update_nvm_solution},

	{ICE_AQC_HEALTH_STATUS_ERR_OROM_AUTH, "Option ROM authentication failed.",

		ice_update_nvm_solution},

	{ICE_AQC_HEALTH_STATUS_ERR_DDP_AUTH, "DDP package authentication failed.",

		"Update to latest base driver and DDP package."},

	{ICE_AQC_HEALTH_STATUS_ERR_NVM_COMPAT, "NVM image is incompatible.",

		ice_update_nvm_solution},

	{ICE_AQC_HEALTH_STATUS_ERR_OROM_COMPAT, "Option ROM is incompatible.",

		ice_update_nvm_solution, {"Expected PCI Device ID", "Expected Module ID"}},

	{ICE_AQC_HEALTH_STATUS_ERR_DCB_MIB,

		"Supplied MIB file is invalid. DCB reverted to default configuration.",

		"Disable FW-LLDP and check DCBx system configuration.",

		{ice_port_number_label, "MIB ID"}},

};

static int ice_health_status_lookup_compare(const void *a, const void *b)

{

	return ((struct ice_health_status *)a)->code - ((struct ice_health_status *)b)->code;

}

static const struct ice_health_status *ice_get_health_status(u16 code)

{

	struct ice_health_status key = { .code = code };

	return bsearch(&key, ice_health_status_lookup, ARRAY_SIZE(ice_health_status_lookup),

		       sizeof(struct ice_health_status), ice_health_status_lookup_compare);

}

static void ice_describe_status_code(struct devlink_fmsg *fmsg,

				     struct ice_aqc_health_status_elem *hse)

{

	static const char *const aux_label[] = { "Aux Data 1", "Aux Data 2" };

	const struct ice_health_status *health_code;

	u32 internal_data[2];

	u16 status_code;

	status_code = le16_to_cpu(hse->health_status_code);

	devlink_fmsg_put(fmsg, "Syndrome", status_code);

	if (status_code) {

		internal_data[0] = le32_to_cpu(hse->internal_data1);

		internal_data[1] = le32_to_cpu(hse->internal_data2);

		health_code = ice_get_health_status(status_code);

		if (!health_code)

			return;

		devlink_fmsg_string_pair_put(fmsg, "Description", health_code->description);

		if (health_code->solution)

			devlink_fmsg_string_pair_put(fmsg, "Possible Solution",

						     health_code->solution);

		for (size_t i = 0; i < ICE_HEALTH_STATUS_DATA_SIZE; i++) {

			if (internal_data[i] != ICE_AQC_HEALTH_STATUS_UNDEFINED_DATA)

				devlink_fmsg_u32_pair_put(fmsg,

							  health_code->data_label[i] ?

							  health_code->data_label[i] :

							  aux_label[i],

							  internal_data[i]);

		}

	}

}

static int

ice_port_reporter_diagnose(struct devlink_health_reporter *reporter, struct devlink_fmsg *fmsg,

			   struct netlink_ext_ack *extack)

{

	struct ice_pf *pf = devlink_health_reporter_priv(reporter);

	ice_describe_status_code(fmsg, &pf->health_reporters.port_status);

	return 0;

}

static int

ice_port_reporter_dump(struct devlink_health_reporter *reporter, struct devlink_fmsg *fmsg,

		       void *priv_ctx, struct netlink_ext_ack __always_unused *extack)

{

	struct ice_pf *pf = devlink_health_reporter_priv(reporter);

	ice_describe_status_code(fmsg, &pf->health_reporters.port_status);

	return 0;

}

static int

ice_fw_reporter_diagnose(struct devlink_health_reporter *reporter, struct devlink_fmsg *fmsg,

			 struct netlink_ext_ack *extack)

{

	struct ice_pf *pf = devlink_health_reporter_priv(reporter);

	ice_describe_status_code(fmsg, &pf->health_reporters.fw_status);

	return 0;

}

static int

ice_fw_reporter_dump(struct devlink_health_reporter *reporter, struct devlink_fmsg *fmsg,

		     void *priv_ctx, struct netlink_ext_ack *extack)

{

	struct ice_pf *pf = devlink_health_reporter_priv(reporter);

	ice_describe_status_code(fmsg, &pf->health_reporters.fw_status);

	return 0;

}

static void ice_config_health_events(struct ice_pf *pf, bool enable)

{

	u8 enable_bits = 0;

	int ret;

	if (enable)

		enable_bits = ICE_AQC_HEALTH_STATUS_SET_PF_SPECIFIC_MASK |

			      ICE_AQC_HEALTH_STATUS_SET_GLOBAL_MASK;

	ret = ice_aq_set_health_status_cfg(&pf->hw, enable_bits);

	if (ret)

		dev_err(ice_pf_to_dev(pf), "Failed to %s firmware health events, err %d aq_err %s\n",

			str_enable_disable(enable), ret,

			ice_aq_str(pf->hw.adminq.sq_last_status));

}

/**

 * ice_process_health_status_event - Process the health status event from FW

 * @pf: pointer to the PF structure

 * @event: event structure containing the Health Status Event opcode

 *

 * Decode the Health Status Events and print the associated messages

 */

void ice_process_health_status_event(struct ice_pf *pf, struct ice_rq_event_info *event)

{

	const struct ice_aqc_health_status_elem *health_info;

	u16 count;

	health_info = (struct ice_aqc_health_status_elem *)event->msg_buf;

	count = le16_to_cpu(event->desc.params.get_health_status.health_status_count);

	if (count > (event->buf_len / sizeof(*health_info))) {

		dev_err(ice_pf_to_dev(pf), "Received a health status event with invalid element count\n");

		return;

	}

	for (size_t i = 0; i < count; i++) {

		const struct ice_health_status *health_code;

		u16 status_code;

		status_code = le16_to_cpu(health_info->health_status_code);

		health_code = ice_get_health_status(status_code);

		if (health_code) {

			switch (le16_to_cpu(health_info->event_source)) {

			case ICE_AQC_HEALTH_STATUS_GLOBAL:

				pf->health_reporters.fw_status = *health_info;

				devlink_health_report(pf->health_reporters.fw,

						      "FW syndrome reported", NULL);

				break;

			case ICE_AQC_HEALTH_STATUS_PF:

			case ICE_AQC_HEALTH_STATUS_PORT:

				pf->health_reporters.port_status = *health_info;

				devlink_health_report(pf->health_reporters.port,

						      "Port syndrome reported", NULL);

				break;

			default:

				dev_err(ice_pf_to_dev(pf), "Health code with unknown source\n");

			}

		} else {

			u32 data1, data2;

			u16 source;

			source = le16_to_cpu(health_info->event_source);

			data1 = le32_to_cpu(health_info->internal_data1);

			data2 = le32_to_cpu(health_info->internal_data2);

			dev_dbg(ice_pf_to_dev(pf),

				"Received internal health status code 0x%08x, source: 0x%08x, data1: 0x%08x, data2: 0x%08x",

				status_code, source, data1, data2);

		}

		health_info++;

	}

}

/**

 * ice_devlink_health_report - boilerplate to call given @reporter

 *

	return rep;

}

#define ICE_DEFINE_HEALTH_REPORTER_OPS(_name) \

#define ICE_HEALTH_REPORTER_OPS_FIELD(_name, _field) \

	._field = ice_##_name##_reporter_##_field,

#define ICE_DEFINE_HEALTH_REPORTER_OPS_1(_name, _field1) \

	static const struct devlink_health_reporter_ops ice_##_name##_reporter_ops = { \

	.name = #_name, \

	.dump = ice_ ## _name ## _reporter_dump, \

	ICE_HEALTH_REPORTER_OPS_FIELD(_name, _field1) \

	}

ICE_DEFINE_HEALTH_REPORTER_OPS(mdd);

ICE_DEFINE_HEALTH_REPORTER_OPS(tx_hang);

#define ICE_DEFINE_HEALTH_REPORTER_OPS_2(_name, _field1, _field2) \

	static const struct devlink_health_reporter_ops ice_##_name##_reporter_ops = { \

	.name = #_name, \

	ICE_HEALTH_REPORTER_OPS_FIELD(_name, _field1) \

	ICE_HEALTH_REPORTER_OPS_FIELD(_name, _field2) \

	}

ICE_DEFINE_HEALTH_REPORTER_OPS_1(mdd, dump);

ICE_DEFINE_HEALTH_REPORTER_OPS_1(tx_hang, dump);

ICE_DEFINE_HEALTH_REPORTER_OPS_2(fw, dump, diagnose);

ICE_DEFINE_HEALTH_REPORTER_OPS_2(port, dump, diagnose);

/**

 * ice_health_init - allocate and init all ice devlink health reporters and

	reps->mdd = ice_init_devlink_rep(pf, &ice_mdd_reporter_ops);

	reps->tx_hang = ice_init_devlink_rep(pf, &ice_tx_hang_reporter_ops);

	if (ice_is_fw_health_report_supported(&pf->hw)) {

		reps->fw = ice_init_devlink_rep(pf, &ice_fw_reporter_ops);

		reps->port = ice_init_devlink_rep(pf, &ice_port_reporter_ops);

		ice_config_health_events(pf, true);

	}

}

/**

{

	ice_deinit_devl_reporter(pf->health_reporters.mdd);

	ice_deinit_devl_reporter(pf->health_reporters.tx_hang);

	if (ice_is_fw_health_report_supported(&pf->hw)) {

		ice_deinit_devl_reporter(pf->health_reporters.fw);

		ice_deinit_devl_reporter(pf->health_reporters.port);

		ice_config_health_events(pf, false);

	}

}

static

 * devlink health mechanism for ice driver.

 */

struct ice_aqc_health_status_elem;

struct ice_pf;

struct ice_tx_ring;

struct ice_rq_event_info;

enum ice_mdd_src {

	ICE_MDD_SRC_TX_PQM,

/**

 * struct ice_health - stores ice devlink health reporters and accompanied data

 * @tx_hang: devlink health reporter for tx_hang event

 * @fw: devlink health reporter for FW Health Status events

 * @mdd: devlink health reporter for MDD detection event

 * @port: devlink health reporter for Port Health Status events

 * @tx_hang: devlink health reporter for tx_hang event

 * @tx_hang_buf: pre-allocated place to put info for Tx hang reporter from

 *               non-sleeping context

 * @tx_ring: ring that the hang occurred on

 * @head: descriptor head

 * @intr: interrupt register value

 * @vsi_num: VSI owning the queue that the hang occurred on

 * @fw_status: buffer for last received FW Status event

 * @port_status: buffer for last received Port Status event

 */

struct ice_health {

	struct devlink_health_reporter *fw;

	struct devlink_health_reporter *mdd;

	struct devlink_health_reporter *port;

	struct devlink_health_reporter *tx_hang;

	struct_group_tagged(ice_health_tx_hang_buf, tx_hang_buf,

		struct ice_tx_ring *tx_ring;

		u32 intr;

		u16 vsi_num;

	);

	struct ice_aqc_health_status_elem fw_status;

	struct ice_aqc_health_status_elem port_status;

};

void ice_process_health_status_event(struct ice_pf *pf,

				     struct ice_rq_event_info *event);

void ice_health_init(struct ice_pf *pf);

void ice_health_deinit(struct ice_pf *pf);

void ice_health_clear(struct ice_pf *pf);

	ICE_AQC_FW_LOG_ID_MAX,

};

enum ice_aqc_health_status_mask {

	ICE_AQC_HEALTH_STATUS_SET_PF_SPECIFIC_MASK = BIT(0),

	ICE_AQC_HEALTH_STATUS_SET_ALL_PF_MASK      = BIT(1),

	ICE_AQC_HEALTH_STATUS_SET_GLOBAL_MASK      = BIT(2),

};

/* Set Health Status (direct 0xFF20) */

struct ice_aqc_set_health_status_cfg {

	u8 event_source;

	u8 reserved[15];

};

enum ice_aqc_health_status {

	ICE_AQC_HEALTH_STATUS_ERR_UNKNOWN_MOD_STRICT		= 0x101,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_TYPE			= 0x102,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_QUAL			= 0x103,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_COMM			= 0x104,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_CONFLICT			= 0x105,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_NOT_PRESENT		= 0x106,

	ICE_AQC_HEALTH_STATUS_INFO_MOD_UNDERUTILIZED		= 0x107,

	ICE_AQC_HEALTH_STATUS_ERR_UNKNOWN_MOD_LENIENT		= 0x108,

	ICE_AQC_HEALTH_STATUS_ERR_MOD_DIAGNOSTIC_FEATURE	= 0x109,

	ICE_AQC_HEALTH_STATUS_ERR_INVALID_LINK_CFG		= 0x10B,

	ICE_AQC_HEALTH_STATUS_ERR_PORT_ACCESS			= 0x10C,

	ICE_AQC_HEALTH_STATUS_ERR_PORT_UNREACHABLE		= 0x10D,

	ICE_AQC_HEALTH_STATUS_INFO_PORT_SPEED_MOD_LIMITED	= 0x10F,

	ICE_AQC_HEALTH_STATUS_ERR_PARALLEL_FAULT		= 0x110,

	ICE_AQC_HEALTH_STATUS_INFO_PORT_SPEED_PHY_LIMITED	= 0x111,

	ICE_AQC_HEALTH_STATUS_ERR_NETLIST_TOPO			= 0x112,

	ICE_AQC_HEALTH_STATUS_ERR_NETLIST			= 0x113,

	ICE_AQC_HEALTH_STATUS_ERR_TOPO_CONFLICT			= 0x114,

	ICE_AQC_HEALTH_STATUS_ERR_LINK_HW_ACCESS		= 0x115,

	ICE_AQC_HEALTH_STATUS_ERR_LINK_RUNTIME			= 0x116,

	ICE_AQC_HEALTH_STATUS_ERR_DNL_INIT			= 0x117,

	ICE_AQC_HEALTH_STATUS_ERR_PHY_NVM_PROG			= 0x120,

	ICE_AQC_HEALTH_STATUS_ERR_PHY_FW_LOAD			= 0x121,

	ICE_AQC_HEALTH_STATUS_INFO_RECOVERY			= 0x500,

	ICE_AQC_HEALTH_STATUS_ERR_FLASH_ACCESS			= 0x501,

	ICE_AQC_HEALTH_STATUS_ERR_NVM_AUTH			= 0x502,

	ICE_AQC_HEALTH_STATUS_ERR_OROM_AUTH			= 0x503,

	ICE_AQC_HEALTH_STATUS_ERR_DDP_AUTH			= 0x504,

	ICE_AQC_HEALTH_STATUS_ERR_NVM_COMPAT			= 0x505,

	ICE_AQC_HEALTH_STATUS_ERR_OROM_COMPAT			= 0x506,

	ICE_AQC_HEALTH_STATUS_ERR_NVM_SEC_VIOLATION		= 0x507,

	ICE_AQC_HEALTH_STATUS_ERR_OROM_SEC_VIOLATION		= 0x508,

	ICE_AQC_HEALTH_STATUS_ERR_DCB_MIB			= 0x509,

	ICE_AQC_HEALTH_STATUS_ERR_MNG_TIMEOUT			= 0x50A,

	ICE_AQC_HEALTH_STATUS_ERR_BMC_RESET			= 0x50B,

	ICE_AQC_HEALTH_STATUS_ERR_LAST_MNG_FAIL			= 0x50C,

	ICE_AQC_HEALTH_STATUS_ERR_RESOURCE_ALLOC_FAIL		= 0x50D,

	ICE_AQC_HEALTH_STATUS_ERR_FW_LOOP			= 0x1000,

	ICE_AQC_HEALTH_STATUS_ERR_FW_PFR_FAIL			= 0x1001,

	ICE_AQC_HEALTH_STATUS_ERR_LAST_FAIL_AQ			= 0x1002,

};

/* Get Health Status (indirect 0xFF22) */

struct ice_aqc_get_health_status {

	__le16 health_status_count;

	u8 reserved[6];

	__le32 addr_high;

	__le32 addr_low;

};

enum ice_aqc_health_status_scope {

	ICE_AQC_HEALTH_STATUS_PF	= 0x1,

	ICE_AQC_HEALTH_STATUS_PORT	= 0x2,

	ICE_AQC_HEALTH_STATUS_GLOBAL	= 0x3,

};

#define ICE_AQC_HEALTH_STATUS_UNDEFINED_DATA	0xDEADBEEF

/* Get Health Status event buffer entry (0xFF22),

 * repeated per reported health status.

 */

struct ice_aqc_health_status_elem {

	__le16 health_status_code;

	__le16 event_source;

	__le32 internal_data1;

	__le32 internal_data2;

};

/* Set FW Logging configuration (indirect 0xFF30)

 * Register for FW Logging (indirect 0xFF31)

 * Query FW Logging (indirect 0xFF32)

		struct ice_aqc_get_link_status get_link_status;

		struct ice_aqc_event_lan_overflow lan_overflow;

		struct ice_aqc_get_link_topo get_link_topo;

		struct ice_aqc_set_health_status_cfg set_health_status_cfg;

		struct ice_aqc_get_health_status get_health_status;

		struct ice_aqc_dnl_call_command dnl_call;

		struct ice_aqc_i2c read_write_i2c;

		struct ice_aqc_read_i2c_resp read_i2c_resp;

	/* Standalone Commands/Events */

	ice_aqc_opc_event_lan_overflow			= 0x1001,

	/* System Diagnostic commands */

	ice_aqc_opc_set_health_status_cfg		= 0xFF20,

	ice_aqc_opc_get_health_status			= 0xFF22,

	/* FW Logging Commands */

	ice_aqc_opc_fw_logs_config			= 0xFF30,

	ice_aqc_opc_fw_logs_register			= 0xFF31,

	return false;

}

/**

 * ice_is_fw_health_report_supported - checks if firmware supports health events

 * @hw: pointer to the hardware structure

 *

 * Return: true if firmware supports health status reports,

 * false otherwise

 */

bool ice_is_fw_health_report_supported(struct ice_hw *hw)

{

	return ice_is_fw_api_min_ver(hw, ICE_FW_API_HEALTH_REPORT_MAJ,

				     ICE_FW_API_HEALTH_REPORT_MIN,

				     ICE_FW_API_HEALTH_REPORT_PATCH);

}

/**

 * ice_aq_set_health_status_cfg - Configure FW health events

 * @hw: pointer to the HW struct

 * @event_source: type of diagnostic events to enable

 *

 * Configure the health status event types that the firmware will send to this

 * PF. The supported event types are: PF-specific, all PFs, and global.

 *

 * Return: 0 on success, negative error code otherwise.

 */

int ice_aq_set_health_status_cfg(struct ice_hw *hw, u8 event_source)

{

	struct ice_aqc_set_health_status_cfg *cmd;

	struct ice_aq_desc desc;

	cmd = &desc.params.set_health_status_cfg;

	ice_fill_dflt_direct_cmd_desc(&desc, ice_aqc_opc_set_health_status_cfg);

	cmd->event_source = event_source;

	return ice_aq_send_cmd(hw, &desc, NULL, 0, NULL);

}

/**

 * ice_aq_set_lldp_mib - Set the LLDP MIB

 * @hw: pointer to the HW struct

ice_get_link_default_override(struct ice_link_default_override_tlv *ldo,

			      struct ice_port_info *pi);

bool ice_is_phy_caps_an_enabled(struct ice_aqc_get_phy_caps_data *caps);

bool ice_is_fw_health_report_supported(struct ice_hw *hw);

int ice_aq_set_health_status_cfg(struct ice_hw *hw, u8 event_source);

int ice_aq_get_phy_equalization(struct ice_hw *hw, u16 data_in, u16 op_code,

				u8 serdes_num, int *output);

int