/* * linux/arch/arm/mach-at91rm9200/gpio.c * * Copyright (C) 2005 HP Labs * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. */ #include #include #include #include #include #include #include #include static const u32 pio_controller_offset[4] = { AT91_PIOA, AT91_PIOB, AT91_PIOC, AT91_PIOD, }; static inline void __iomem *pin_to_controller(unsigned pin) { void __iomem *sys_base = (void __iomem *) AT91_VA_BASE_SYS; pin -= PIN_BASE; pin /= 32; if (likely(pin < BGA_GPIO_BANKS)) return sys_base + pio_controller_offset[pin]; return NULL; } static inline unsigned pin_to_mask(unsigned pin) { pin -= PIN_BASE; return 1 << (pin % 32); } /*--------------------------------------------------------------------------*/ /* Not all hardware capabilities are exposed through these calls; they * only encapsulate the most common features and modes. (So if you * want to change signals in groups, do it directly.) * * Bootloaders will usually handle some of the pin multiplexing setup. * The intent is certainly that by the time Linux is fully booted, all * pins should have been fully initialized. These setup calls should * only be used by board setup routines, or possibly in driver probe(). * * For bootloaders doing all that setup, these calls could be inlined * as NOPs so Linux won't duplicate any setup code */ /* * mux the pin to the "A" internal peripheral role. */ int __init_or_module at91_set_A_periph(unsigned pin, int use_pullup) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + PIO_IDR); __raw_writel(mask, pio + (use_pullup ? PIO_PUER : PIO_PUDR)); __raw_writel(mask, pio + PIO_ASR); __raw_writel(mask, pio + PIO_PDR); return 0; } EXPORT_SYMBOL(at91_set_A_periph); /* * mux the pin to the "B" internal peripheral role. */ int __init_or_module at91_set_B_periph(unsigned pin, int use_pullup) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + PIO_IDR); __raw_writel(mask, pio + (use_pullup ? PIO_PUER : PIO_PUDR)); __raw_writel(mask, pio + PIO_BSR); __raw_writel(mask, pio + PIO_PDR); return 0; } EXPORT_SYMBOL(at91_set_B_periph); /* * mux the pin to the gpio controller (instead of "A" or "B" peripheral), and * configure it for an input. */ int __init_or_module at91_set_gpio_input(unsigned pin, int use_pullup) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + PIO_IDR); __raw_writel(mask, pio + (use_pullup ? PIO_PUER : PIO_PUDR)); __raw_writel(mask, pio + PIO_ODR); __raw_writel(mask, pio + PIO_PER); return 0; } EXPORT_SYMBOL(at91_set_gpio_input); /* * mux the pin to the gpio controller (instead of "A" or "B" peripheral), * and configure it for an output. */ int __init_or_module at91_set_gpio_output(unsigned pin, int value) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + PIO_IDR); __raw_writel(mask, pio + PIO_PUDR); __raw_writel(mask, pio + (value ? PIO_SODR : PIO_CODR)); __raw_writel(mask, pio + PIO_OER); __raw_writel(mask, pio + PIO_PER); return 0; } EXPORT_SYMBOL(at91_set_gpio_output); /* * enable/disable the glitch filter; mostly used with IRQ handling. */ int __init_or_module at91_set_deglitch(unsigned pin, int is_on) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + (is_on ? PIO_IFER : PIO_IFDR)); return 0; } EXPORT_SYMBOL(at91_set_deglitch); /* * enable/disable the multi-driver; This is only valid for output and * allows the output pin to run as an open collector output. */ int __init_or_module at91_set_multi_drive(unsigned pin, int is_on) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + (is_on ? PIO_MDER : PIO_MDDR)); return 0; } EXPORT_SYMBOL(at91_set_multi_drive); /*--------------------------------------------------------------------------*/ /* * assuming the pin is muxed as a gpio output, set its value. */ int at91_set_gpio_value(unsigned pin, int value) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (!pio) return -EINVAL; __raw_writel(mask, pio + (value ? PIO_SODR : PIO_CODR)); return 0; } EXPORT_SYMBOL(at91_set_gpio_value); /* * read the pin's value (works even if it's not muxed as a gpio). */ int at91_get_gpio_value(unsigned pin) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); u32 pdsr; if (!pio) return -EINVAL; pdsr = __raw_readl(pio + PIO_PDSR); return (pdsr & mask) != 0; } EXPORT_SYMBOL(at91_get_gpio_value); /*--------------------------------------------------------------------------*/ /* Several AIC controller irqs are dispatched through this GPIO handler. * To use any AT91_PIN_* as an externally triggered IRQ, first call * at91_set_gpio_input() then maybe enable its glitch filter. * Then just request_irq() with the pin ID; it works like any ARM IRQ * handler, though it always triggers on rising and falling edges. * * Alternatively, certain pins may be used directly as IRQ0..IRQ6 after * configuring them with at91_set_a_periph() or at91_set_b_periph(). * IRQ0..IRQ6 should be configurable, e.g. level vs edge triggering. */ static void gpio_irq_mask(unsigned pin) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (pio) __raw_writel(mask, pio + PIO_IDR); } static void gpio_irq_unmask(unsigned pin) { void __iomem *pio = pin_to_controller(pin); unsigned mask = pin_to_mask(pin); if (pio) __raw_writel(mask, pio + PIO_IER); } static int gpio_irq_type(unsigned pin, unsigned type) { return (type == IRQT_BOTHEDGE) ? 0 : -EINVAL; } static struct irqchip gpio_irqchip = { .mask = gpio_irq_mask, .unmask = gpio_irq_unmask, .set_type = gpio_irq_type, }; static void gpio_irq_handler(unsigned irq, struct irqdesc *desc, struct pt_regs *regs) { unsigned pin; struct irqdesc *gpio; void __iomem *pio; u32 isr; pio = desc->base; /* temporarily mask (level sensitive) parent IRQ */ desc->chip->ack(irq); for (;;) { isr = __raw_readl(pio + PIO_ISR) & __raw_readl(pio + PIO_IMR); if (!isr) break; pin = (unsigned) desc->data; gpio = &irq_desc[pin]; while (isr) { if (isr & 1) { if (unlikely(gpio->disable_depth)) { /* * The core ARM interrupt handler lazily disables IRQs so * another IRQ must be generated before it actually gets * here to be disabled on the GPIO controller. */ gpio_irq_mask(pin); } else gpio->handle(pin, gpio, regs); } pin++; gpio++; isr >>= 1; } } desc->chip->unmask(irq); /* now it may re-trigger */ } /* call this from board-specific init_irq */ void __init at91_gpio_irq_setup(unsigned banks) { unsigned pioc, pin, id; if (banks > 4) banks = 4; for (pioc = 0, pin = PIN_BASE, id = AT91_ID_PIOA; pioc < banks; pioc++, id++) { void __iomem *controller; unsigned i; controller = (void __iomem *) AT91_VA_BASE_SYS + pio_controller_offset[pioc]; __raw_writel(~0, controller + PIO_IDR); set_irq_data(id, (void *) pin); set_irq_chipdata(id, controller); for (i = 0; i < 32; i++, pin++) { set_irq_chip(pin, &gpio_irqchip); set_irq_handler(pin, do_simple_IRQ); set_irq_flags(pin, IRQF_VALID); } set_irq_chained_handler(id, gpio_irq_handler); /* enable the PIO peripheral clock */ at91_sys_write(AT91_PMC_PCER, 1 << id); } pr_info("AT91: %d gpio irqs in %d banks\n", pin - PIN_BASE, banks); }