drivers/staging/bcm/led_control.h - nest-hello/linux-3.10 - Git at Google

 #ifndef _LED_CONTROL_H
 #define _LED_CONTROL_H

 #define NUM_OF_LEDS				4
 #define DSD_START_OFFSET			0x0200
 #define EEPROM_VERSION_OFFSET			0x020E
 #define EEPROM_HW_PARAM_POINTER_ADDRESS		0x0218
 #define EEPROM_HW_PARAM_POINTER_ADDRRES_MAP5	0x0220
 #define GPIO_SECTION_START_OFFSET		0x03
 #define COMPATIBILITY_SECTION_LENGTH		42
 #define COMPATIBILITY_SECTION_LENGTH_MAP5	84
 #define EEPROM_MAP5_MAJORVERSION		5
 #define EEPROM_MAP5_MINORVERSION		0
 #define MAX_NUM_OF_BLINKS			10
 #define NUM_OF_GPIO_PINS			16
 #define DISABLE_GPIO_NUM			0xFF
 #define EVENT_SIGNALED				1
 #define MAX_FILE_NAME_BUFFER_SIZE		100

 #define TURN_ON_LED(GPIO, index) do {					\
 		unsigned int gpio_val = GPIO;					\
 		(Adapter->LEDInfo.LEDState[index].BitPolarity == 1) ?	\
 			wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_SET_REG, &gpio_val, sizeof(gpio_val)) : \
 			wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_CLR_REG, &gpio_val, sizeof(gpio_val)); \
 	} while (0)

 #define TURN_OFF_LED(GPIO, index)  do {					\
 		unsigned int gpio_val = GPIO;					\
 		(Adapter->LEDInfo.LEDState[index].BitPolarity == 1) ?	\
 			wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_CLR_REG, &gpio_val, sizeof(gpio_val)) : \
 			wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_SET_REG, &gpio_val, sizeof(gpio_val)); \
 	} while (0)

 enum bcm_led_colors {
 	RED_LED		= 1,
 	BLUE_LED	= 2,
 	YELLOW_LED	= 3,
 	GREEN_LED	= 4
 };

 enum bcm_led_events {
 	SHUTDOWN_EXIT		= 0x00,
 	DRIVER_INIT		= 0x1,
 	FW_DOWNLOAD		= 0x2,
 	FW_DOWNLOAD_DONE	= 0x4,
 	NO_NETWORK_ENTRY	= 0x8,
 	NORMAL_OPERATION	= 0x10,
 	LOWPOWER_MODE_ENTER	= 0x20,
 	IDLEMODE_CONTINUE	= 0x40,
 	IDLEMODE_EXIT		= 0x80,
 	LED_THREAD_INACTIVE	= 0x100,  /* Makes the LED thread Inactivce. It wil be equivallent to putting the thread on hold. */
 	LED_THREAD_ACTIVE	= 0x200,  /* Makes the LED Thread Active back. */
 	DRIVER_HALT		= 0xff
 }; /* Enumerated values of different driver states */

 /*
  * Structure which stores the information of different LED types
  * and corresponding LED state information of driver states
  */
 struct bcm_led_state_info {
 	unsigned char LED_Type; /* specify GPIO number - use 0xFF if not used */
 	unsigned char LED_On_State; /* Bits set or reset for different states */
 	unsigned char LED_Blink_State; /* Bits set or reset for blinking LEDs for different states */
 	unsigned char GPIO_Num;
 	unsigned char BitPolarity; /* To represent whether H/W is normal polarity or reverse polarity */
 };

 struct bcm_led_info {
 	struct bcm_led_state_info LEDState[NUM_OF_LEDS];
 	bool		bIdleMode_tx_from_host; /* Variable to notify whether driver came out from idlemode due to Host or target */
 	bool		bIdle_led_off;
 	wait_queue_head_t	notify_led_event;
 	wait_queue_head_t	idleModeSyncEvent;
 	struct task_struct	*led_cntrl_threadid;
 	int		led_thread_running;
 	bool		bLedInitDone;
 };

 /* LED Thread state. */
 #define BCM_LED_THREAD_DISABLED		0   /* LED Thread is not running. */
 #define BCM_LED_THREAD_RUNNING_ACTIVELY	1   /* LED thread is running. */
 #define BCM_LED_THREAD_RUNNING_INACTIVELY 2 /* LED thread has been put on hold */

 #endif
	#ifndef _LED_CONTROL_H
	#define _LED_CONTROL_H

	#define NUM_OF_LEDS 4
	#define DSD_START_OFFSET 0x0200
	#define EEPROM_VERSION_OFFSET 0x020E
	#define EEPROM_HW_PARAM_POINTER_ADDRESS 0x0218
	#define EEPROM_HW_PARAM_POINTER_ADDRRES_MAP5 0x0220
	#define GPIO_SECTION_START_OFFSET 0x03
	#define COMPATIBILITY_SECTION_LENGTH 42
	#define COMPATIBILITY_SECTION_LENGTH_MAP5 84
	#define EEPROM_MAP5_MAJORVERSION 5
	#define EEPROM_MAP5_MINORVERSION 0
	#define MAX_NUM_OF_BLINKS 10
	#define NUM_OF_GPIO_PINS 16
	#define DISABLE_GPIO_NUM 0xFF
	#define EVENT_SIGNALED 1
	#define MAX_FILE_NAME_BUFFER_SIZE 100

	#define TURN_ON_LED(GPIO, index) do { \
	unsigned int gpio_val = GPIO; \
	(Adapter->LEDInfo.LEDState[index].BitPolarity == 1) ? \
	wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_SET_REG, &gpio_val, sizeof(gpio_val)) : \
	wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_CLR_REG, &gpio_val, sizeof(gpio_val)); \
	} while (0)

	#define TURN_OFF_LED(GPIO, index) do { \
	unsigned int gpio_val = GPIO; \
	(Adapter->LEDInfo.LEDState[index].BitPolarity == 1) ? \
	wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_CLR_REG, &gpio_val, sizeof(gpio_val)) : \
	wrmaltWithLock(Adapter, BCM_GPIO_OUTPUT_SET_REG, &gpio_val, sizeof(gpio_val)); \
	} while (0)

	enum bcm_led_colors {
	RED_LED = 1,
	BLUE_LED = 2,
	YELLOW_LED = 3,
	GREEN_LED = 4
	};

	enum bcm_led_events {
	SHUTDOWN_EXIT = 0x00,
	DRIVER_INIT = 0x1,
	FW_DOWNLOAD = 0x2,
	FW_DOWNLOAD_DONE = 0x4,
	NO_NETWORK_ENTRY = 0x8,
	NORMAL_OPERATION = 0x10,
	LOWPOWER_MODE_ENTER = 0x20,
	IDLEMODE_CONTINUE = 0x40,
	IDLEMODE_EXIT = 0x80,
	LED_THREAD_INACTIVE = 0x100, /* Makes the LED thread Inactivce. It wil be equivallent to putting the thread on hold. */
	LED_THREAD_ACTIVE = 0x200, /* Makes the LED Thread Active back. */
	DRIVER_HALT = 0xff
	}; /* Enumerated values of different driver states */

	/*
	* Structure which stores the information of different LED types
	* and corresponding LED state information of driver states
	*/
	struct bcm_led_state_info {
	unsigned char LED_Type; /* specify GPIO number - use 0xFF if not used */
	unsigned char LED_On_State; /* Bits set or reset for different states */
	unsigned char LED_Blink_State; /* Bits set or reset for blinking LEDs for different states */
	unsigned char GPIO_Num;
	unsigned char BitPolarity; /* To represent whether H/W is normal polarity or reverse polarity */
	};

	struct bcm_led_info {
	struct bcm_led_state_info LEDState[NUM_OF_LEDS];
	bool bIdleMode_tx_from_host; /* Variable to notify whether driver came out from idlemode due to Host or target */
	bool bIdle_led_off;
	wait_queue_head_t notify_led_event;
	wait_queue_head_t idleModeSyncEvent;
	struct task_struct *led_cntrl_threadid;
	int led_thread_running;
	bool bLedInitDone;
	};

	/* LED Thread state. */
	#define BCM_LED_THREAD_DISABLED 0 /* LED Thread is not running. */
	#define BCM_LED_THREAD_RUNNING_ACTIVELY 1 /* LED thread is running. */
	#define BCM_LED_THREAD_RUNNING_INACTIVELY 2 /* LED thread has been put on hold */

	#endif