drivers/thunderbolt/tb.h - nest-learning-thermostat/5.9.1/linux-imx-ul - Git at Google

 /*
  * Thunderbolt Cactus Ridge driver - bus logic (NHI independent)
  *
  * Copyright (c) 2014 Andreas Noever <andreas.noever@gmail.com>
  */

 #ifndef TB_H_
 #define TB_H_

 #include <linux/pci.h>

 #include "tb_regs.h"
 #include "ctl.h"

 /**
  * struct tb_switch - a thunderbolt switch
  */
 struct tb_switch {
 	struct tb_regs_switch_header config;
 	struct tb_port *ports;
 	struct tb *tb;
 	u64 uid;
 	int cap_plug_events; /* offset, zero if not found */
 	bool is_unplugged; /* unplugged, will go away */
 	u8 *drom;
 };

 /**
  * struct tb_port - a thunderbolt port, part of a tb_switch
  */
 struct tb_port {
 	struct tb_regs_port_header config;
 	struct tb_switch *sw;
 	struct tb_port *remote; /* remote port, NULL if not connected */
 	int cap_phy; /* offset, zero if not found */
 	u8 port; /* port number on switch */
 	bool disabled; /* disabled by eeprom */
 	struct tb_port *dual_link_port;
 	u8 link_nr:1;
 };

 /**
  * struct tb_path_hop - routing information for a tb_path
  *
  * Hop configuration is always done on the IN port of a switch.
  * in_port and out_port have to be on the same switch. Packets arriving on
  * in_port with "hop" = in_hop_index will get routed to through out_port. The
  * next hop to take (on out_port->remote) is determined by next_hop_index.
  *
  * in_counter_index is the index of a counter (in TB_CFG_COUNTERS) on the in
  * port.
  */
 struct tb_path_hop {
 	struct tb_port *in_port;
 	struct tb_port *out_port;
 	int in_hop_index;
 	int in_counter_index; /* write -1 to disable counters for this hop. */
 	int next_hop_index;
 };

 /**
  * enum tb_path_port - path options mask
  */
 enum tb_path_port {
 	TB_PATH_NONE = 0,
 	TB_PATH_SOURCE = 1, /* activate on the first hop (out of src) */
 	TB_PATH_INTERNAL = 2, /* activate on other hops (not the first/last) */
 	TB_PATH_DESTINATION = 4, /* activate on the last hop (into dst) */
 	TB_PATH_ALL = 7,
 };

 /**
  * struct tb_path - a unidirectional path between two ports
  *
  * A path consists of a number of hops (see tb_path_hop). To establish a PCIe
  * tunnel two paths have to be created between the two PCIe ports.
  *
  */
 struct tb_path {
 	struct tb *tb;
 	int nfc_credits; /* non flow controlled credits */
 	enum tb_path_port ingress_shared_buffer;
 	enum tb_path_port egress_shared_buffer;
 	enum tb_path_port ingress_fc_enable;
 	enum tb_path_port egress_fc_enable;

 	int priority:3;
 	int weight:4;
 	bool drop_packages;
 	bool activated;
 	struct tb_path_hop *hops;
 	int path_length; /* number of hops */
 };


 /**
  * struct tb - main thunderbolt bus structure
  */
 struct tb {
 	struct mutex lock;	/*
 				 * Big lock. Must be held when accessing cfg or
 				 * any struct tb_switch / struct tb_port.
 				 */
 	struct tb_nhi *nhi;
 	struct tb_ctl *ctl;
 	struct workqueue_struct *wq; /* ordered workqueue for plug events */
 	struct tb_switch *root_switch;
 	struct list_head tunnel_list; /* list of active PCIe tunnels */
 	bool hotplug_active; /*
 			      * tb_handle_hotplug will stop progressing plug
 			      * events and exit if this is not set (it needs to
 			      * acquire the lock one more time). Used to drain
 			      * wq after cfg has been paused.
 			      */

 };

 /* helper functions & macros */

 /**
  * tb_upstream_port() - return the upstream port of a switch
  *
  * Every switch has an upstream port (for the root switch it is the NHI).
  *
  * During switch alloc/init tb_upstream_port()->remote may be NULL, even for
  * non root switches (on the NHI port remote is always NULL).
  *
  * Return: Returns the upstream port of the switch.
  */
 static inline struct tb_port *tb_upstream_port(struct tb_switch *sw)
 {
 	return &sw->ports[sw->config.upstream_port_number];
 }

 static inline u64 tb_route(struct tb_switch *sw)
 {
 	return ((u64) sw->config.route_hi) << 32 | sw->config.route_lo;
 }

 static inline int tb_sw_read(struct tb_switch *sw, void *buffer,
 			     enum tb_cfg_space space, u32 offset, u32 length)
 {
 	return tb_cfg_read(sw->tb->ctl,
 			   buffer,
 			   tb_route(sw),
 			   0,
 			   space,
 			   offset,
 			   length);
 }

 static inline int tb_sw_write(struct tb_switch *sw, void *buffer,
 			      enum tb_cfg_space space, u32 offset, u32 length)
 {
 	return tb_cfg_write(sw->tb->ctl,
 			    buffer,
 			    tb_route(sw),
 			    0,
 			    space,
 			    offset,
 			    length);
 }

 static inline int tb_port_read(struct tb_port *port, void *buffer,
 			       enum tb_cfg_space space, u32 offset, u32 length)
 {
 	return tb_cfg_read(port->sw->tb->ctl,
 			   buffer,
 			   tb_route(port->sw),
 			   port->port,
 			   space,
 			   offset,
 			   length);
 }

 static inline int tb_port_write(struct tb_port *port, void *buffer,
 				enum tb_cfg_space space, u32 offset, u32 length)
 {
 	return tb_cfg_write(port->sw->tb->ctl,
 			    buffer,
 			    tb_route(port->sw),
 			    port->port,
 			    space,
 			    offset,
 			    length);
 }

 #define tb_err(tb, fmt, arg...) dev_err(&(tb)->nhi->pdev->dev, fmt, ## arg)
 #define tb_WARN(tb, fmt, arg...) dev_WARN(&(tb)->nhi->pdev->dev, fmt, ## arg)
 #define tb_warn(tb, fmt, arg...) dev_warn(&(tb)->nhi->pdev->dev, fmt, ## arg)
 #define tb_info(tb, fmt, arg...) dev_info(&(tb)->nhi->pdev->dev, fmt, ## arg)


 #define __TB_SW_PRINT(level, sw, fmt, arg...)           \
 	do {                                            \
 		struct tb_switch *__sw = (sw);          \
 		level(__sw->tb, "%llx: " fmt,           \
 		      tb_route(__sw), ## arg);          \
 	} while (0)
 #define tb_sw_WARN(sw, fmt, arg...) __TB_SW_PRINT(tb_WARN, sw, fmt, ##arg)
 #define tb_sw_warn(sw, fmt, arg...) __TB_SW_PRINT(tb_warn, sw, fmt, ##arg)
 #define tb_sw_info(sw, fmt, arg...) __TB_SW_PRINT(tb_info, sw, fmt, ##arg)


 #define __TB_PORT_PRINT(level, _port, fmt, arg...)                      \
 	do {                                                            \
 		struct tb_port *__port = (_port);                       \
 		level(__port->sw->tb, "%llx:%x: " fmt,                  \
 		      tb_route(__port->sw), __port->port, ## arg);      \
 	} while (0)
 #define tb_port_WARN(port, fmt, arg...) \
 	__TB_PORT_PRINT(tb_WARN, port, fmt, ##arg)
 #define tb_port_warn(port, fmt, arg...) \
 	__TB_PORT_PRINT(tb_warn, port, fmt, ##arg)
 #define tb_port_info(port, fmt, arg...) \
 	__TB_PORT_PRINT(tb_info, port, fmt, ##arg)


 struct tb *thunderbolt_alloc_and_start(struct tb_nhi *nhi);
 void thunderbolt_shutdown_and_free(struct tb *tb);
 void thunderbolt_suspend(struct tb *tb);
 void thunderbolt_resume(struct tb *tb);

 struct tb_switch *tb_switch_alloc(struct tb *tb, u64 route);
 void tb_switch_free(struct tb_switch *sw);
 void tb_switch_suspend(struct tb_switch *sw);
 int tb_switch_resume(struct tb_switch *sw);
 int tb_switch_reset(struct tb *tb, u64 route);
 void tb_sw_set_unpplugged(struct tb_switch *sw);
 struct tb_switch *get_switch_at_route(struct tb_switch *sw, u64 route);

 int tb_wait_for_port(struct tb_port *port, bool wait_if_unplugged);
 int tb_port_add_nfc_credits(struct tb_port *port, int credits);
 int tb_port_clear_counter(struct tb_port *port, int counter);

 int tb_find_cap(struct tb_port *port, enum tb_cfg_space space, enum tb_cap cap);

 struct tb_path *tb_path_alloc(struct tb *tb, int num_hops);
 void tb_path_free(struct tb_path *path);
 int tb_path_activate(struct tb_path *path);
 void tb_path_deactivate(struct tb_path *path);
 bool tb_path_is_invalid(struct tb_path *path);

 int tb_drom_read(struct tb_switch *sw);
 int tb_drom_read_uid_only(struct tb_switch *sw, u64 *uid);


 static inline int tb_route_length(u64 route)
 {
 	return (fls64(route) + TB_ROUTE_SHIFT - 1) / TB_ROUTE_SHIFT;
 }

 static inline bool tb_is_upstream_port(struct tb_port *port)
 {
 	return port == tb_upstream_port(port->sw);
 }

 /**
  * tb_downstream_route() - get route to downstream switch
  *
  * Port must not be the upstream port (otherwise a loop is created).
  *
  * Return: Returns a route to the switch behind @port.
  */
 static inline u64 tb_downstream_route(struct tb_port *port)
 {
 	return tb_route(port->sw)
 	       | ((u64) port->port << (port->sw->config.depth * 8));
 }

 #endif
	/*
	* Thunderbolt Cactus Ridge driver - bus logic (NHI independent)
	*
	* Copyright (c) 2014 Andreas Noever <andreas.noever@gmail.com>
	*/

	#ifndef TB_H_
	#define TB_H_

	#include <linux/pci.h>

	#include "tb_regs.h"
	#include "ctl.h"

	/**
	* struct tb_switch - a thunderbolt switch
	*/
	struct tb_switch {
	struct tb_regs_switch_header config;
	struct tb_port *ports;
	struct tb *tb;
	u64 uid;
	int cap_plug_events; /* offset, zero if not found */
	bool is_unplugged; /* unplugged, will go away */
	u8 *drom;
	};

	/**
	* struct tb_port - a thunderbolt port, part of a tb_switch
	*/
	struct tb_port {
	struct tb_regs_port_header config;
	struct tb_switch *sw;
	struct tb_port remote; / remote port, NULL if not connected */
	int cap_phy; /* offset, zero if not found */
	u8 port; /* port number on switch */
	bool disabled; /* disabled by eeprom */
	struct tb_port *dual_link_port;
	u8 link_nr:1;
	};

	/**
	* struct tb_path_hop - routing information for a tb_path
	*
	* Hop configuration is always done on the IN port of a switch.
	* in_port and out_port have to be on the same switch. Packets arriving on
	* in_port with "hop" = in_hop_index will get routed to through out_port. The
	* next hop to take (on out_port->remote) is determined by next_hop_index.
	*
	* in_counter_index is the index of a counter (in TB_CFG_COUNTERS) on the in
	* port.
	*/
	struct tb_path_hop {
	struct tb_port *in_port;
	struct tb_port *out_port;
	int in_hop_index;
	int in_counter_index; /* write -1 to disable counters for this hop. */
	int next_hop_index;
	};

	/**
	* enum tb_path_port - path options mask
	*/
	enum tb_path_port {
	TB_PATH_NONE = 0,
	TB_PATH_SOURCE = 1, /* activate on the first hop (out of src) */
	TB_PATH_INTERNAL = 2, /* activate on other hops (not the first/last) */
	TB_PATH_DESTINATION = 4, /* activate on the last hop (into dst) */
	TB_PATH_ALL = 7,
	};

	/**
	* struct tb_path - a unidirectional path between two ports
	*
	* A path consists of a number of hops (see tb_path_hop). To establish a PCIe
	* tunnel two paths have to be created between the two PCIe ports.
	*
	*/
	struct tb_path {
	struct tb *tb;
	int nfc_credits; /* non flow controlled credits */
	enum tb_path_port ingress_shared_buffer;
	enum tb_path_port egress_shared_buffer;
	enum tb_path_port ingress_fc_enable;
	enum tb_path_port egress_fc_enable;

	int priority:3;
	int weight:4;
	bool drop_packages;
	bool activated;
	struct tb_path_hop *hops;
	int path_length; /* number of hops */
	};


	/**
	* struct tb - main thunderbolt bus structure
	*/
	struct tb {
	struct mutex lock; /*
	* Big lock. Must be held when accessing cfg or
	* any struct tb_switch / struct tb_port.
	*/
	struct tb_nhi *nhi;
	struct tb_ctl *ctl;
	struct workqueue_struct wq; / ordered workqueue for plug events */
	struct tb_switch *root_switch;
	struct list_head tunnel_list; /* list of active PCIe tunnels */
	bool hotplug_active; /*
	* tb_handle_hotplug will stop progressing plug
	* events and exit if this is not set (it needs to
	* acquire the lock one more time). Used to drain
	* wq after cfg has been paused.
	*/

	};

	/* helper functions & macros */

	/**
	* tb_upstream_port() - return the upstream port of a switch
	*
	* Every switch has an upstream port (for the root switch it is the NHI).
	*
	* During switch alloc/init tb_upstream_port()->remote may be NULL, even for
	* non root switches (on the NHI port remote is always NULL).
	*
	* Return: Returns the upstream port of the switch.
	*/
	static inline struct tb_port tb_upstream_port(struct tb_switch sw)
	{
	return &sw->ports[sw->config.upstream_port_number];
	}

	static inline u64 tb_route(struct tb_switch *sw)
	{
	return ((u64) sw->config.route_hi) << 32 \| sw->config.route_lo;
	}

	static inline int tb_sw_read(struct tb_switch sw, void buffer,
	enum tb_cfg_space space, u32 offset, u32 length)
	{
	return tb_cfg_read(sw->tb->ctl,
	buffer,
	tb_route(sw),
	0,
	space,
	offset,
	length);
	}

	static inline int tb_sw_write(struct tb_switch sw, void buffer,
	enum tb_cfg_space space, u32 offset, u32 length)
	{
	return tb_cfg_write(sw->tb->ctl,
	buffer,
	tb_route(sw),
	0,
	space,
	offset,
	length);
	}

	static inline int tb_port_read(struct tb_port port, void buffer,
	enum tb_cfg_space space, u32 offset, u32 length)
	{
	return tb_cfg_read(port->sw->tb->ctl,
	buffer,
	tb_route(port->sw),
	port->port,
	space,
	offset,
	length);
	}

	static inline int tb_port_write(struct tb_port port, void buffer,
	enum tb_cfg_space space, u32 offset, u32 length)
	{
	return tb_cfg_write(port->sw->tb->ctl,
	buffer,
	tb_route(port->sw),
	port->port,
	space,
	offset,
	length);
	}

	#define tb_err(tb, fmt, arg...) dev_err(&(tb)->nhi->pdev->dev, fmt, ## arg)
	#define tb_WARN(tb, fmt, arg...) dev_WARN(&(tb)->nhi->pdev->dev, fmt, ## arg)
	#define tb_warn(tb, fmt, arg...) dev_warn(&(tb)->nhi->pdev->dev, fmt, ## arg)
	#define tb_info(tb, fmt, arg...) dev_info(&(tb)->nhi->pdev->dev, fmt, ## arg)


	#define __TB_SW_PRINT(level, sw, fmt, arg...) \
	do { \
	struct tb_switch *__sw = (sw); \
	level(__sw->tb, "%llx: " fmt, \
	tb_route(__sw), ## arg); \
	} while (0)
	#define tb_sw_WARN(sw, fmt, arg...) __TB_SW_PRINT(tb_WARN, sw, fmt, ##arg)
	#define tb_sw_warn(sw, fmt, arg...) __TB_SW_PRINT(tb_warn, sw, fmt, ##arg)
	#define tb_sw_info(sw, fmt, arg...) __TB_SW_PRINT(tb_info, sw, fmt, ##arg)


	#define __TB_PORT_PRINT(level, _port, fmt, arg...) \
	do { \
	struct tb_port *__port = (_port); \
	level(__port->sw->tb, "%llx:%x: " fmt, \
	tb_route(__port->sw), __port->port, ## arg); \
	} while (0)
	#define tb_port_WARN(port, fmt, arg...) \
	__TB_PORT_PRINT(tb_WARN, port, fmt, ##arg)
	#define tb_port_warn(port, fmt, arg...) \
	__TB_PORT_PRINT(tb_warn, port, fmt, ##arg)
	#define tb_port_info(port, fmt, arg...) \
	__TB_PORT_PRINT(tb_info, port, fmt, ##arg)


	struct tb thunderbolt_alloc_and_start(struct tb_nhi nhi);
	void thunderbolt_shutdown_and_free(struct tb *tb);
	void thunderbolt_suspend(struct tb *tb);
	void thunderbolt_resume(struct tb *tb);

	struct tb_switch tb_switch_alloc(struct tb tb, u64 route);
	void tb_switch_free(struct tb_switch *sw);
	void tb_switch_suspend(struct tb_switch *sw);
	int tb_switch_resume(struct tb_switch *sw);
	int tb_switch_reset(struct tb *tb, u64 route);
	void tb_sw_set_unpplugged(struct tb_switch *sw);
	struct tb_switch get_switch_at_route(struct tb_switch sw, u64 route);

	int tb_wait_for_port(struct tb_port *port, bool wait_if_unplugged);
	int tb_port_add_nfc_credits(struct tb_port *port, int credits);
	int tb_port_clear_counter(struct tb_port *port, int counter);

	int tb_find_cap(struct tb_port *port, enum tb_cfg_space space, enum tb_cap cap);

	struct tb_path tb_path_alloc(struct tb tb, int num_hops);
	void tb_path_free(struct tb_path *path);
	int tb_path_activate(struct tb_path *path);
	void tb_path_deactivate(struct tb_path *path);
	bool tb_path_is_invalid(struct tb_path *path);

	int tb_drom_read(struct tb_switch *sw);
	int tb_drom_read_uid_only(struct tb_switch sw, u64 uid);


	static inline int tb_route_length(u64 route)
	{
	return (fls64(route) + TB_ROUTE_SHIFT - 1) / TB_ROUTE_SHIFT;
	}

	static inline bool tb_is_upstream_port(struct tb_port *port)
	{
	return port == tb_upstream_port(port->sw);
	}

	/**
	* tb_downstream_route() - get route to downstream switch
	*
	* Port must not be the upstream port (otherwise a loop is created).
	*
	* Return: Returns a route to the switch behind @port.
	*/
	static inline u64 tb_downstream_route(struct tb_port *port)
	{
	return tb_route(port->sw)
	\| ((u64) port->port << (port->sw->config.depth * 8));
	}

	#endif