/* * linux/arch/arm/kernel/leds-sa1100.c * * Copyright (C) 2000 John Dorsey * * Original (leds-footbridge.c) by Russell King * * Added Brutus LEDs support * Nicolas Pitre, Mar 19, 2000 * * Added LART LED support * Erik Mouw (J.A.K.Mouw@its.tudelft.nl), April 21, 2000 * * * Assabet uses the LEDs as follows: * - Green - toggles state every 50 timer interrupts * - Red - on if system is not idle * * Brutus uses the LEDs as follows: * - D3 (Green, GPIO9) - toggles state every 50 timer interrupts * - D17 (Red, GPIO20) - on if system is not idle * - D4 (Green, GPIO8) - misc function * * LART uses the LED as follows: * - GPIO23 is the LED, on if system is not idle * You can use both CONFIG_LEDS_CPU and CONFIG_LEDS_TIMER at the same * time, but in that case the timer events will still dictate the * pace of the LED. * */ #include #include #include #include #include #include #include #include #include #define LED_STATE_ENABLED 1 #define LED_STATE_CLAIMED 2 static unsigned int led_state; static unsigned int hw_led_state; #ifdef CONFIG_SA1100_ASSABET #define BCR_LED_MASK (BCR_LED_GREEN | BCR_LED_RED) static void assabet_leds_event(led_event_t evt) { unsigned long flags; local_irq_save(flags); switch (evt) { case led_start: hw_led_state = BCR_LED_RED | BCR_LED_GREEN; led_state = LED_STATE_ENABLED; break; case led_stop: led_state &= ~LED_STATE_ENABLED; break; case led_claim: led_state |= LED_STATE_CLAIMED; hw_led_state = BCR_LED_RED | BCR_LED_GREEN; break; case led_release: led_state &= ~LED_STATE_CLAIMED; hw_led_state = BCR_LED_RED | BCR_LED_GREEN; break; #ifdef CONFIG_LEDS_TIMER case led_timer: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state ^= BCR_LED_GREEN; break; #endif #ifdef CONFIG_LEDS_CPU case led_idle_start: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= BCR_LED_RED; break; case led_idle_end: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~BCR_LED_RED; break; #endif case led_halted: break; case led_green_on: if (led_state & LED_STATE_CLAIMED) hw_led_state &= ~BCR_LED_GREEN; break; case led_green_off: if (led_state & LED_STATE_CLAIMED) hw_led_state |= BCR_LED_GREEN; break; case led_amber_on: break; case led_amber_off: break; case led_red_on: if (led_state & LED_STATE_CLAIMED) hw_led_state &= ~BCR_LED_RED; break; case led_red_off: if (led_state & LED_STATE_CLAIMED) hw_led_state |= BCR_LED_RED; break; default: break; } if (led_state & LED_STATE_ENABLED) BCR = BCR_value = (BCR_value & ~BCR_LED_MASK) | hw_led_state; local_irq_restore(flags); } #endif /* CONFIG_SA1100_ASSABET */ #ifdef CONFIG_SA1100_BRUTUS #define LED_D3 GPIO_GPIO(9) #define LED_D4 GPIO_GPIO(8) #define LED_D17 GPIO_GPIO(20) #define LED_MASK (LED_D3|LED_D4|LED_D17) static void brutus_leds_event(led_event_t evt) { unsigned long flags; local_irq_save(flags); switch (evt) { case led_start: hw_led_state = LED_MASK; led_state = LED_STATE_ENABLED; break; case led_stop: led_state &= ~LED_STATE_ENABLED; break; case led_claim: led_state |= LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; case led_release: led_state &= ~LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; #ifdef CONFIG_LEDS_TIMER case led_timer: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state ^= LED_D3; break; #endif #ifdef CONFIG_LEDS_CPU case led_idle_start: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_D17; break; case led_idle_end: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_D17; break; #endif case led_green_on: hw_led_state &= ~LED_D4; break; case led_green_off: hw_led_state |= LED_D4; break; case led_amber_on: break; case led_amber_off: break; case led_red_on: if (led_state & LED_STATE_CLAIMED) hw_led_state &= ~LED_D17; break; case led_red_off: if (led_state & LED_STATE_CLAIMED) hw_led_state |= LED_D17; break; default: break; } if (led_state & LED_STATE_ENABLED) { GPSR = hw_led_state; GPCR = hw_led_state ^ LED_MASK; } local_irq_restore(flags); } #endif /* CONFIG_SA1100_BRUTUS */ #ifdef CONFIG_SA1100_LART #define LED_23 GPIO_GPIO23 #define LED_MASK (LED_23) static void lart_leds_event(led_event_t evt) { unsigned long flags; local_irq_save(flags); switch(evt) { case led_start: hw_led_state = LED_MASK; led_state = LED_STATE_ENABLED; break; case led_stop: led_state &= ~LED_STATE_ENABLED; break; case led_claim: led_state |= LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; case led_release: led_state &= ~LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; #ifdef CONFIG_LEDS_TIMER case led_timer: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state ^= LED_23; break; #endif #ifdef CONFIG_LEDS_CPU case led_idle_start: /* The LART people like the LED to be off when the system is idle... */ if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_23; break; case led_idle_end: /* ... and on if the system is not idle */ if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_23; break; #endif case led_red_on: if (led_state & LED_STATE_CLAIMED) hw_led_state &= ~LED_23; break; case led_red_off: if (led_state & LED_STATE_CLAIMED) hw_led_state |= LED_23; break; default: break; } /* Now set the GPIO state, or nothing will happen at all */ if (led_state & LED_STATE_ENABLED) { GPSR = hw_led_state; GPCR = hw_led_state ^ LED_MASK; } local_irq_restore(flags); } #endif /* CONFIG_SA1100_LART */ #ifdef CONFIG_SA1100_CERF #define LED_D0 GPIO_GPIO(0) #define LED_D1 GPIO_GPIO(1) #define LED_D2 GPIO_GPIO(2) #define LED_D3 GPIO_GPIO(3) #define LED_MASK (LED_D0|LED_D1|LED_D2|LED_D3) static void cerf_leds_event(led_event_t evt) { unsigned long flags; local_irq_save(flags); switch (evt) { case led_start: hw_led_state = LED_MASK; led_state = LED_STATE_ENABLED; break; case led_stop: led_state &= ~LED_STATE_ENABLED; break; case led_claim: led_state |= LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; case led_release: led_state &= ~LED_STATE_CLAIMED; hw_led_state = LED_MASK; break; #ifdef CONFIG_LEDS_TIMER case led_timer: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state ^= LED_D0; break; #endif #ifdef CONFIG_LEDS_CPU case led_idle_start: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_D1; break; case led_idle_end: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_D1; break; #endif case led_green_on: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_D2; break; case led_green_off: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_D2; break; case led_amber_on: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_D3; break; case led_amber_off: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_D3; break; case led_red_on: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state &= ~LED_D1; break; case led_red_off: if (!(led_state & LED_STATE_CLAIMED)) hw_led_state |= LED_D1; break; default: break; } if (led_state & LED_STATE_ENABLED) { GPSR = hw_led_state; GPCR = hw_led_state ^ LED_MASK; } local_irq_restore(flags); } #endif /* CONFIG_SA1100_CERF */ static int __init sa1100_leds_init(void) { #ifdef CONFIG_SA1100_ASSABET if (machine_is_assabet()) leds_event = assabet_leds_event; #endif #ifdef CONFIG_SA1100_BRUTUS if (machine_is_brutus()) leds_event = brutus_leds_event; #endif #ifdef CONFIG_SA1100_LART if (machine_is_lart()) leds_event = lart_leds_event; #endif #ifdef CONFIG_SA1100_CERF if (machine_is_cerf()) { //GPDR |= 0x0000000F; leds_event = cerf_leds_event; } #endif leds_event(led_start); return 0; } __initcall(sa1100_leds_init);