// SPDX-License-Identifier: GPL-2.0-only /* // Copyright (c) 2022 Pengutronix, Oleksij Rempel */ #ifndef _LINUX_PSE_CONTROLLER_H #define _LINUX_PSE_CONTROLLER_H #include #include #include #include #include #include /* Maximum current in uA according to IEEE 802.3-2022 Table 145-1 */ #define MAX_PI_CURRENT 1920000 /* Maximum power in mW according to IEEE 802.3-2022 Table 145-16 */ #define MAX_PI_PW 99900 struct net_device; struct phy_device; struct pse_controller_dev; struct netlink_ext_ack; /* C33 PSE extended state and substate. */ struct ethtool_c33_pse_ext_state_info { enum ethtool_c33_pse_ext_state c33_pse_ext_state; union { enum ethtool_c33_pse_ext_substate_error_condition error_condition; enum ethtool_c33_pse_ext_substate_mr_pse_enable mr_pse_enable; enum ethtool_c33_pse_ext_substate_option_detect_ted option_detect_ted; enum ethtool_c33_pse_ext_substate_option_vport_lim option_vport_lim; enum ethtool_c33_pse_ext_substate_ovld_detected ovld_detected; enum ethtool_c33_pse_ext_substate_power_not_available power_not_available; enum ethtool_c33_pse_ext_substate_short_detected short_detected; u32 __c33_pse_ext_substate; }; }; struct ethtool_c33_pse_pw_limit_range { u32 min; u32 max; }; /** * struct pse_irq_desc - notification sender description for IRQ based events. * * @name: the visible name for the IRQ * @map_event: driver callback to map IRQ status into PSE devices with events. */ struct pse_irq_desc { const char *name; int (*map_event)(int irq, struct pse_controller_dev *pcdev, unsigned long *notifs, unsigned long *notifs_mask); }; /** * struct pse_control_config - PSE control/channel configuration. * * @podl_admin_control: set PoDL PSE admin control as described in * IEEE 802.3-2018 30.15.1.2.1 acPoDLPSEAdminControl * @c33_admin_control: set PSE admin control as described in * IEEE 802.3-2022 30.9.1.2.1 acPSEAdminControl */ struct pse_control_config { enum ethtool_podl_pse_admin_state podl_admin_control; enum ethtool_c33_pse_admin_state c33_admin_control; }; /** * struct pse_admin_state - PSE operational state * * @podl_admin_state: operational state of the PoDL PSE * functions. IEEE 802.3-2018 30.15.1.1.2 aPoDLPSEAdminState * @c33_admin_state: operational state of the PSE * functions. IEEE 802.3-2022 30.9.1.1.2 aPSEAdminState */ struct pse_admin_state { enum ethtool_podl_pse_admin_state podl_admin_state; enum ethtool_c33_pse_admin_state c33_admin_state; }; /** * struct pse_pw_status - PSE power detection status * * @podl_pw_status: power detection status of the PoDL PSE. * IEEE 802.3-2018 30.15.1.1.3 aPoDLPSEPowerDetectionStatus: * @c33_pw_status: power detection status of the PSE. * IEEE 802.3-2022 30.9.1.1.5 aPSEPowerDetectionStatus: */ struct pse_pw_status { enum ethtool_podl_pse_pw_d_status podl_pw_status; enum ethtool_c33_pse_pw_d_status c33_pw_status; }; /** * struct pse_ext_state_info - PSE extended state information * * @c33_ext_state_info: extended state information of the PSE */ struct pse_ext_state_info { struct ethtool_c33_pse_ext_state_info c33_ext_state_info; }; /** * struct pse_pw_limit_ranges - PSE power limit configuration range * * @c33_pw_limit_ranges: supported power limit configuration range. The driver * is in charge of the memory allocation. */ struct pse_pw_limit_ranges { struct ethtool_c33_pse_pw_limit_range *c33_pw_limit_ranges; }; /** * struct ethtool_pse_control_status - PSE control/channel status. * * @pw_d_id: PSE power domain index. * @podl_admin_state: operational state of the PoDL PSE * functions. IEEE 802.3-2018 30.15.1.1.2 aPoDLPSEAdminState * @podl_pw_status: power detection status of the PoDL PSE. * IEEE 802.3-2018 30.15.1.1.3 aPoDLPSEPowerDetectionStatus: * @c33_admin_state: operational state of the PSE * functions. IEEE 802.3-2022 30.9.1.1.2 aPSEAdminState * @c33_pw_status: power detection status of the PSE. * IEEE 802.3-2022 30.9.1.1.5 aPSEPowerDetectionStatus: * @c33_pw_class: detected class of a powered PD * IEEE 802.3-2022 30.9.1.1.8 aPSEPowerClassification * @c33_actual_pw: power currently delivered by the PSE in mW * IEEE 802.3-2022 30.9.1.1.23 aPSEActualPower * @c33_ext_state_info: extended state information of the PSE * @c33_avail_pw_limit: available power limit of the PSE in mW * IEEE 802.3-2022 145.2.5.4 pse_avail_pwr * @c33_pw_limit_ranges: supported power limit configuration range. The driver * is in charge of the memory allocation * @c33_pw_limit_nb_ranges: number of supported power limit configuration * ranges * @prio_max: max priority allowed for the c33_prio variable value. * @prio: priority of the PSE. Managed by PSE core in case of static budget * evaluation strategy. */ struct ethtool_pse_control_status { u32 pw_d_id; enum ethtool_podl_pse_admin_state podl_admin_state; enum ethtool_podl_pse_pw_d_status podl_pw_status; enum ethtool_c33_pse_admin_state c33_admin_state; enum ethtool_c33_pse_pw_d_status c33_pw_status; u32 c33_pw_class; u32 c33_actual_pw; struct ethtool_c33_pse_ext_state_info c33_ext_state_info; u32 c33_avail_pw_limit; struct ethtool_c33_pse_pw_limit_range *c33_pw_limit_ranges; u32 c33_pw_limit_nb_ranges; u32 prio_max; u32 prio; }; /** * struct pse_controller_ops - PSE controller driver callbacks * * @setup_pi_matrix: Setup PI matrix of the PSE controller. * The PSE PIs devicetree nodes have already been parsed by * of_load_pse_pis() and the pcdev->pi[x]->pairset[y].np * populated. This callback should establish the * relationship between the PSE controller hardware ports * and the PSE Power Interfaces, either through software * mapping or hardware configuration. * @pi_get_admin_state: Get the operational state of the PSE PI. This ops * is mandatory. * @pi_get_pw_status: Get the power detection status of the PSE PI. This * ops is mandatory. * @pi_get_ext_state: Get the extended state of the PSE PI. * @pi_get_pw_class: Get the power class of the PSE PI. * @pi_get_actual_pw: Get actual power of the PSE PI in mW. * @pi_enable: Configure the PSE PI as enabled. * @pi_disable: Configure the PSE PI as disabled. * @pi_get_voltage: Return voltage similarly to get_voltage regulator * callback in uV. * @pi_get_pw_limit: Get the configured power limit of the PSE PI in mW. * @pi_set_pw_limit: Configure the power limit of the PSE PI in mW. * @pi_get_pw_limit_ranges: Get the supported power limit configuration * range. The driver is in charge of the memory * allocation and should return the number of * ranges. * @pi_get_prio: Get the PSE PI priority. * @pi_set_prio: Configure the PSE PI priority. * @pi_get_pw_req: Get the power requested by a PD before enabling the PSE PI. * This is only relevant when an interrupt is registered using * devm_pse_irq_helper helper. */ struct pse_controller_ops { int (*setup_pi_matrix)(struct pse_controller_dev *pcdev); int (*pi_get_admin_state)(struct pse_controller_dev *pcdev, int id, struct pse_admin_state *admin_state); int (*pi_get_pw_status)(struct pse_controller_dev *pcdev, int id, struct pse_pw_status *pw_status); int (*pi_get_ext_state)(struct pse_controller_dev *pcdev, int id, struct pse_ext_state_info *ext_state_info); int (*pi_get_pw_class)(struct pse_controller_dev *pcdev, int id); int (*pi_get_actual_pw)(struct pse_controller_dev *pcdev, int id); int (*pi_enable)(struct pse_controller_dev *pcdev, int id); int (*pi_disable)(struct pse_controller_dev *pcdev, int id); int (*pi_get_voltage)(struct pse_controller_dev *pcdev, int id); int (*pi_get_pw_limit)(struct pse_controller_dev *pcdev, int id); int (*pi_set_pw_limit)(struct pse_controller_dev *pcdev, int id, int max_mW); int (*pi_get_pw_limit_ranges)(struct pse_controller_dev *pcdev, int id, struct pse_pw_limit_ranges *pw_limit_ranges); int (*pi_get_prio)(struct pse_controller_dev *pcdev, int id); int (*pi_set_prio)(struct pse_controller_dev *pcdev, int id, unsigned int prio); int (*pi_get_pw_req)(struct pse_controller_dev *pcdev, int id); }; struct module; struct device_node; struct of_phandle_args; struct pse_control; struct ethtool_pse_control_status; /* PSE PI pairset pinout can either be Alternative A or Alternative B */ enum pse_pi_pairset_pinout { ALTERNATIVE_A, ALTERNATIVE_B, }; /** * struct pse_pi_pairset - PSE PI pairset entity describing the pinout * alternative ant its phandle * * @pinout: description of the pinout alternative * @np: device node pointer describing the pairset phandle */ struct pse_pi_pairset { enum pse_pi_pairset_pinout pinout; struct device_node *np; }; /** * struct pse_pi - PSE PI (Power Interface) entity as described in * IEEE 802.3-2022 145.2.4 * * @pairset: table of the PSE PI pinout alternative for the two pairset * @np: device node pointer of the PSE PI node * @rdev: regulator represented by the PSE PI * @admin_state_enabled: PI enabled state * @pw_d: Power domain of the PSE PI * @prio: Priority of the PSE PI. Used in static budget evaluation strategy * @isr_pd_detected: PSE PI detection status managed by the interruption * handler. This variable is relevant when the power enabled * management is managed in software like the static * budget evaluation strategy. * @pw_allocated_mW: Power allocated to a PSE PI to manage power budget in * static budget evaluation strategy. */ struct pse_pi { struct pse_pi_pairset pairset[2]; struct device_node *np; struct regulator_dev *rdev; bool admin_state_enabled; struct pse_power_domain *pw_d; int prio; bool isr_pd_detected; int pw_allocated_mW; }; /** * struct pse_ntf - PSE notification element * * @id: ID of the PSE control * @notifs: PSE notifications to be reported */ struct pse_ntf { int id; unsigned long notifs; }; /** * struct pse_controller_dev - PSE controller entity that might * provide multiple PSE controls * @ops: a pointer to device specific struct pse_controller_ops * @owner: kernel module of the PSE controller driver * @list: internal list of PSE controller devices * @pse_control_head: head of internal list of requested PSE controls * @dev: corresponding driver model device struct * @of_pse_n_cells: number of cells in PSE line specifiers * @nr_lines: number of PSE controls in this controller device * @lock: Mutex for serialization access to the PSE controller * @types: types of the PSE controller * @pi: table of PSE PIs described in this controller device * @no_of_pse_pi: flag set if the pse_pis devicetree node is not used * @irq: PSE interrupt * @pis_prio_max: Maximum value allowed for the PSE PIs priority * @supp_budget_eval_strategies: budget evaluation strategies supported * by the PSE * @ntf_work: workqueue for PSE notification management * @ntf_fifo: PSE notifications FIFO * @ntf_fifo_lock: protect @ntf_fifo writer */ struct pse_controller_dev { const struct pse_controller_ops *ops; struct module *owner; struct list_head list; struct list_head pse_control_head; struct device *dev; int of_pse_n_cells; unsigned int nr_lines; struct mutex lock; enum ethtool_pse_types types; struct pse_pi *pi; bool no_of_pse_pi; int irq; unsigned int pis_prio_max; u32 supp_budget_eval_strategies; struct work_struct ntf_work; DECLARE_KFIFO_PTR(ntf_fifo, struct pse_ntf); spinlock_t ntf_fifo_lock; /* Protect @ntf_fifo writer */ }; /** * enum pse_budget_eval_strategies - PSE budget evaluation strategies. * @PSE_BUDGET_EVAL_STRAT_DISABLED: Budget evaluation strategy disabled. * @PSE_BUDGET_EVAL_STRAT_STATIC: PSE static budget evaluation strategy. * Budget evaluation strategy based on the power requested during PD * classification. This strategy is managed by the PSE core. * @PSE_BUDGET_EVAL_STRAT_DYNAMIC: PSE dynamic budget evaluation * strategy. Budget evaluation strategy based on the current consumption * per ports compared to the total power budget. This mode is managed by * the PSE controller. */ enum pse_budget_eval_strategies { PSE_BUDGET_EVAL_STRAT_DISABLED = 1 << 0, PSE_BUDGET_EVAL_STRAT_STATIC = 1 << 1, PSE_BUDGET_EVAL_STRAT_DYNAMIC = 1 << 2, }; #if IS_ENABLED(CONFIG_PSE_CONTROLLER) int pse_controller_register(struct pse_controller_dev *pcdev); void pse_controller_unregister(struct pse_controller_dev *pcdev); struct device; int devm_pse_controller_register(struct device *dev, struct pse_controller_dev *pcdev); int devm_pse_irq_helper(struct pse_controller_dev *pcdev, int irq, int irq_flags, const struct pse_irq_desc *d); struct pse_control *of_pse_control_get(struct device_node *node, struct phy_device *phydev); void pse_control_put(struct pse_control *psec); int pse_ethtool_get_status(struct pse_control *psec, struct netlink_ext_ack *extack, struct ethtool_pse_control_status *status); int pse_ethtool_set_config(struct pse_control *psec, struct netlink_ext_ack *extack, const struct pse_control_config *config); int pse_ethtool_set_pw_limit(struct pse_control *psec, struct netlink_ext_ack *extack, const unsigned int pw_limit); int pse_ethtool_set_prio(struct pse_control *psec, struct netlink_ext_ack *extack, unsigned int prio); bool pse_has_podl(struct pse_control *psec); bool pse_has_c33(struct pse_control *psec); #else static inline struct pse_control *of_pse_control_get(struct device_node *node, struct phy_device *phydev) { return ERR_PTR(-ENOENT); } static inline void pse_control_put(struct pse_control *psec) { } static inline int pse_ethtool_get_status(struct pse_control *psec, struct netlink_ext_ack *extack, struct ethtool_pse_control_status *status) { return -EOPNOTSUPP; } static inline int pse_ethtool_set_config(struct pse_control *psec, struct netlink_ext_ack *extack, const struct pse_control_config *config) { return -EOPNOTSUPP; } static inline int pse_ethtool_set_pw_limit(struct pse_control *psec, struct netlink_ext_ack *extack, const unsigned int pw_limit) { return -EOPNOTSUPP; } static inline int pse_ethtool_set_prio(struct pse_control *psec, struct netlink_ext_ack *extack, unsigned int prio) { return -EOPNOTSUPP; } static inline bool pse_has_podl(struct pse_control *psec) { return false; } static inline bool pse_has_c33(struct pse_control *psec) { return false; } #endif #endif