/* * Copyright (c) 2020 Raspberry Pi (Trading) Ltd. * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef _HARDWARE_GPIO_H #define _HARDWARE_GPIO_H #include "pico.h" #include "hardware/structs/sio.h" #include "hardware/structs/pads_bank0.h" #include "hardware/structs/io_bank0.h" #include "hardware/irq.h" // PICO_CONFIG: PICO_USE_GPIO_COPROCESSOR, Enable/disable use of the GPIO coprocessor for GPIO access, type=bool, default=1, group=hardware_gpio #if !defined(PICO_USE_GPIO_COPROCESSOR) && HAS_GPIO_COPROCESSOR #define PICO_USE_GPIO_COPROCESSOR 1 #endif #if PICO_USE_GPIO_COPROCESSOR #include "hardware/gpio_coproc.h" #endif #ifdef __cplusplus extern "C" { #endif // PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_HARDWARE_GPIO, Enable/disable assertions in the hardware_gpio module, type=bool, default=0, group=hardware_gpio #ifndef PARAM_ASSERTIONS_ENABLED_HARDWARE_GPIO #ifdef PARAM_ASSERTIONS_ENABLED_GPIO // backwards compatibility with SDK < 2.0.0 #define PARAM_ASSERTIONS_ENABLED_HARDWARE_GPIO PARAM_ASSERTIONS_ENABLED_GPIO #else #define PARAM_ASSERTIONS_ENABLED_HARDWARE_GPIO 0 #endif #endif /** \file gpio.h * \defgroup hardware_gpio hardware_gpio * * \brief General Purpose Input/Output (GPIO) API * * RP-series microcontrollers have two banks of General Purpose Input / Output (GPIO) pins, which are assigned as follows: * * \if rp2040_specific * RP2040 has 30 user GPIO pins in bank 0, and 6 QSPI pins in the QSPI bank 1 (QSPI_SS, QSPI_SCLK and QSPI_SD0 to QSPI_SD3). The QSPI * pins are used to execute code from an external flash device, leaving the User bank (GPIO0 to GPIO29) for the programmer to use. * \endif * * \if rp2350_specific * The number of GPIO pins available depends on the package. There are 30 user GPIOs in bank 0 in the QFN-60 package (RP2350A), or 48 user GPIOs * in the QFN-80 package. Bank 1 contains the 6 QSPI pins and the USB DP/DM pins. * \endif * * All GPIOs support digital input and output, but a subset can also be used as inputs to the chip’s Analogue to Digital * Converter (ADC). The allocation of GPIO pins to the ADC depends on the packaging. * * RP2040 and RP2350 QFN-60 GPIO, ADC pins are 26-29. * RP2350 QFN-80, ADC pins are 40-47. * * Each GPIO can be controlled directly by software running on the processors, or by a number of other functional blocks. * * The function allocated to each GPIO is selected by calling the \ref gpio_set_function function. \note Not all functions * are available on all pins. * * Each GPIO can have one function selected at a time. Likewise, each peripheral input (e.g. UART0 RX) should only be selected on * one _GPIO_ at a time. If the same peripheral input is connected to multiple GPIOs, the peripheral sees the logical OR of these * GPIO inputs. Please refer to the datasheet for more information on GPIO function select. * * ### Function Select Table * * \if rp2040_specific * On RP2040 the function selects are: * * | GPIO | F1 | F2 | F3 | F4 | F5 | F6 | F7 | F8 | F9 | * |--------|----------|-----------|----------|--------|-----|------|------|---------------|---------------| * | 0 | SPI0 RX | UART0 TX | I2C0 SDA | PWM0 A | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 1 | SPI0 CSn | UART0 RX | I2C0 SCL | PWM0 B | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 2 | SPI0 SCK | UART0 CTS | I2C1 SDA | PWM1 A | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 3 | SPI0 TX | UART0 RTS | I2C1 SCL | PWM1 B | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 4 | SPI0 RX | UART1 TX | I2C0 SDA | PWM2 A | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 5 | SPI0 CSn | UART1 RX | I2C0 SCL | PWM2 B | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 6 | SPI0 SCK | UART1 CTS | I2C1 SDA | PWM3 A | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 7 | SPI0 TX | UART1 RTS | I2C1 SCL | PWM3 B | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 8 | SPI1 RX | UART1 TX | I2C0 SDA | PWM4 A | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 9 | SPI1 CSn | UART1 RX | I2C0 SCL | PWM4 B | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 10 | SPI1 SCK | UART1 CTS | I2C1 SDA | PWM5 A | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 11 | SPI1 TX | UART1 RTS | I2C1 SCL | PWM5 B | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 12 | SPI1 RX | UART0 TX | I2C0 SDA | PWM6 A | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 13 | SPI1 CSn | UART0 RX | I2C0 SCL | PWM6 B | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 14 | SPI1 SCK | UART0 CTS | I2C1 SDA | PWM7 A | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 15 | SPI1 TX | UART0 RTS | I2C1 SCL | PWM7 B | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 16 | SPI0 RX | UART0 TX | I2C0 SDA | PWM0 A | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 17 | SPI0 CSn | UART0 RX | I2C0 SCL | PWM0 B | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 18 | SPI0 SCK | UART0 CTS | I2C1 SDA | PWM1 A | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 19 | SPI0 TX | UART0 RTS | I2C1 SCL | PWM1 B | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 20 | SPI0 RX | UART1 TX | I2C0 SDA | PWM2 A | SIO | PIO0 | PIO1 | CLOCK GPIN0 | USB VBUS EN | * | 21 | SPI0 CSn | UART1 RX | I2C0 SCL | PWM2 B | SIO | PIO0 | PIO1 | CLOCK GPOUT0 | USB OVCUR DET | * | 22 | SPI0 SCK | UART1 CTS | I2C1 SDA | PWM3 A | SIO | PIO0 | PIO1 | CLOCK GPIN1 | USB VBUS DET | * | 23 | SPI0 TX | UART1 RTS | I2C1 SCL | PWM3 B | SIO | PIO0 | PIO1 | CLOCK GPOUT1 | USB VBUS EN | * | 24 | SPI1 RX | UART1 TX | I2C0 SDA | PWM4 A | SIO | PIO0 | PIO1 | CLOCK GPOUT2 | USB OVCUR DET | * | 25 | SPI1 CSn | UART1 RX | I2C0 SCL | PWM4 B | SIO | PIO0 | PIO1 | CLOCK GPOUT3 | USB VBUS DET | * | 26 | SPI1 SCK | UART1 CTS | I2C1 SDA | PWM5 A | SIO | PIO0 | PIO1 | | USB VBUS EN | * | 27 | SPI1 TX | UART1 RTS | I2C1 SCL | PWM5 B | SIO | PIO0 | PIO1 | | USB OVCUR DET | * | 28 | SPI1 RX | UART0 TX | I2C0 SDA | PWM6 A | SIO | PIO0 | PIO1 | | USB VBUS DET | * | 29 | SPI1 CSn | UART0 RX | I2C0 SCL | PWM6 B | SIO | PIO0 | PIO1 | | USB VBUS EN | * \endif * \if rp2350_specific * On RP2350 the function selects are: * * | GPIO | F0 | F1 | F2 | F3 | F4 | F5 | F6 | F7 | F8 | F9 | F10 | F11 | * |-------|------|----------|-----------|----------|--------|-----|------|------|------|--------------|---------------|----------| * | 0 | | SPI0 RX | UART0 TX | I2C0 SDA | PWM0 A | SIO | PIO0 | PIO1 | PIO2 | XIP_CS1n | USB OVCUR DET | | * | 1 | | SPI0 CSn | UART0 RX | I2C0 SCL | PWM0 B | SIO | PIO0 | PIO1 | PIO2 | TRACECLK | USB VBUS DET | | * | 2 | | SPI0 SCK | UART0 CTS | I2C1 SDA | PWM1 A | SIO | PIO0 | PIO1 | PIO2 | TRACEDATA0 | USB VBUS EN | UART0 TX | * | 3 | | SPI0 TX | UART0 RTS | I2C1 SCL | PWM1 B | SIO | PIO0 | PIO1 | PIO2 | TRACEDATA1 | USB OVCUR DET | UART0 RX | * | 4 | | SPI0 RX | UART1 TX | I2C0 SDA | PWM2 A | SIO | PIO0 | PIO1 | PIO2 | TRACEDATA2 | USB VBUS DET | | * | 5 | | SPI0 CSn | UART1 RX | I2C0 SCL | PWM2 B | SIO | PIO0 | PIO1 | PIO2 | TRACEDATA3 | USB VBUS EN | | * | 6 | | SPI0 SCK | UART1 CTS | I2C1 SDA | PWM3 A | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART1 TX | * | 7 | | SPI0 TX | UART1 RTS | I2C1 SCL | PWM3 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART1 RX | * | 8 | | SPI1 RX | UART1 TX | I2C0 SDA | PWM4 A | SIO | PIO0 | PIO1 | PIO2 | XIP_CS1n | USB VBUS EN | | * | 9 | | SPI1 CSn | UART1 RX | I2C0 SCL | PWM4 B | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | | * | 10 | | SPI1 SCK | UART1 CTS | I2C1 SDA | PWM5 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART1 TX | * | 11 | | SPI1 TX | UART1 RTS | I2C1 SCL | PWM5 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | UART1 RX | * | 12 | HSTX | SPI1 RX | UART0 TX | I2C0 SDA | PWM6 A | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPIN0 | USB OVCUR DET | | * | 13 | HSTX | SPI1 CSn | UART0 RX | I2C0 SCL | PWM6 B | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT0 | USB VBUS DET | | * | 14 | HSTX | SPI1 SCK | UART0 CTS | I2C1 SDA | PWM7 A | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPIN1 | USB VBUS EN | UART0 TX | * | 15 | HSTX | SPI1 TX | UART0 RTS | I2C1 SCL | PWM7 B | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT1 | USB OVCUR DET | UART0 RX | * | 16 | HSTX | SPI0 RX | UART0 TX | I2C0 SDA | PWM0 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | | * | 17 | HSTX | SPI0 CSn | UART0 RX | I2C0 SCL | PWM0 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | | * | 18 | HSTX | SPI0 SCK | UART0 CTS | I2C1 SDA | PWM1 A | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART0 TX | * | 19 | HSTX | SPI0 TX | UART0 RTS | I2C1 SCL | PWM1 B | SIO | PIO0 | PIO1 | PIO2 | XIP_CS1n | USB VBUS DET | UART0 RX | * | 20 | | SPI0 RX | UART1 TX | I2C0 SDA | PWM2 A | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPIN0 | USB VBUS EN | | * | 21 | | SPI0 CSn | UART1 RX | I2C0 SCL | PWM2 B | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT0 | USB OVCUR DET | | * | 22 | | SPI0 SCK | UART1 CTS | I2C1 SDA | PWM3 A | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPIN1 | USB VBUS DET | UART1 TX | * | 23 | | SPI0 TX | UART1 RTS | I2C1 SCL | PWM3 B | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT1 | USB VBUS EN | UART1 RX | * | 24 | | SPI1 RX | UART1 TX | I2C0 SDA | PWM4 A | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT2 | USB OVCUR DET | | * | 25 | | SPI1 CSn | UART1 RX | I2C0 SCL | PWM4 B | SIO | PIO0 | PIO1 | PIO2 | CLOCK GPOUT3 | USB VBUS DET | | * | 26 | | SPI1 SCK | UART1 CTS | I2C1 SDA | PWM5 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | UART1 TX | * | 27 | | SPI1 TX | UART1 RTS | I2C1 SCL | PWM5 B | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART1 RX | * | 28 | | SPI1 RX | UART0 TX | I2C0 SDA | PWM6 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | | * | 29 | | SPI1 CSn | UART0 RX | I2C0 SCL | PWM6 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | | * * GPIOs 30 through 47 are QFN-80 only: * * | GPIO | F0 | F1 | F2 | F3 | F4 | F5 | F6 | F7 | F8 | F9 | F10 | F11 | * |------|----|----------|----------|-----------|---------|-----|------|------|------|----------|---------------|----------| * | 30 | | SPI1 SCK | UART0 CTS | I2C1 SDA | PWM7 A | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART0 TX | * | 31 | | SPI1 TX | UART0 RTS | I2C1 SCL | PWM7 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART0 RX | * | 32 | | SPI0 RX | UART0 TX | I2C0 SDA | PWM8 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | | * | 33 | | SPI0 CSn | UART0 RX | I2C0 SCL | PWM8 B | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | | * | 34 | | SPI0 SCK | UART0 CTS | I2C1 SDA | PWM9 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART0 TX | * | 35 | | SPI0 TX | UART0 RTS | I2C1 SCL | PWM9 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | UART0 RX | * | 36 | | SPI0 RX | UART1 TX | I2C0 SDA | PWM10 A | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | | * | 37 | | SPI0 CSn | UART1 RX | I2C0 SCL | PWM10 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | | * | 38 | | SPI0 SCK | UART1 CTS | I2C1 SDA | PWM11 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | UART1 TX | * | 39 | | SPI0 TX | UART1 RTS | I2C1 SCL | PWM11 B | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART1 RX | * | 40 | | SPI1 RX | UART1 TX | I2C0 SDA | PWM8 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | | * | 41 | | SPI1 CSn | UART1 RX | I2C0 SCL | PWM8 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | | * | 42 | | SPI1 SCK | UART1 CTS | I2C1 SDA | PWM9 A | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | UART1 TX | * | 43 | | SPI1 TX | UART1 RTS | I2C1 SCL | PWM9 B | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART1 RX | * | 44 | | SPI1 RX | UART0 TX | I2C0 SDA | PWM10 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS EN | | * | 45 | | SPI1 CSn | UART0 RX | I2C0 SCL | PWM10 B | SIO | PIO0 | PIO1 | PIO2 | | USB OVCUR DET | | * | 46 | | SPI1 SCK | UART0 CTS | I2C1 SDA | PWM11 A | SIO | PIO0 | PIO1 | PIO2 | | USB VBUS DET | UART0 TX | * | 47 | | SPI1 TX | UART0 RTS | I2C1 SCL | PWM11 B | SIO | PIO0 | PIO1 | PIO2 | XIP_CS1n | USB VBUS EN | UART0 RX | * * \endif */ enum gpio_dir { GPIO_OUT = 1u, ///< set GPIO to output GPIO_IN = 0u, ///< set GPIO to input }; /*! \brief GPIO Interrupt level definitions (GPIO events) * \ingroup hardware_gpio * \brief GPIO Interrupt levels * * An interrupt can be generated for every GPIO pin in 4 scenarios: * * * Level High: the GPIO pin is a logical 1 * * Level Low: the GPIO pin is a logical 0 * * Edge High: the GPIO has transitioned from a logical 0 to a logical 1 * * Edge Low: the GPIO has transitioned from a logical 1 to a logical 0 * * The level interrupts are not latched. This means that if the pin is a logical 1 and the level high interrupt is active, it will * become inactive as soon as the pin changes to a logical 0. The edge interrupts are stored in the INTR register and can be * cleared by writing to the INTR register. */ enum gpio_irq_level { GPIO_IRQ_LEVEL_LOW = 0x1u, ///< IRQ when the GPIO pin is a logical 0 GPIO_IRQ_LEVEL_HIGH = 0x2u, ///< IRQ when the GPIO pin is a logical 1 GPIO_IRQ_EDGE_FALL = 0x4u, ///< IRQ when the GPIO has transitioned from a logical 1 to a logical 0 GPIO_IRQ_EDGE_RISE = 0x8u, ///< IRQ when the GPIO has transitioned from a logical 0 to a logical 1 }; /*! Callback function type for GPIO events * \ingroup hardware_gpio * * \param gpio Which GPIO caused this interrupt * \param event_mask Which events caused this interrupt. See \ref gpio_irq_level for details. * \sa gpio_set_irq_enabled_with_callback() * \sa gpio_set_irq_callback() */ typedef void (*gpio_irq_callback_t)(uint gpio, uint32_t event_mask); enum gpio_override { GPIO_OVERRIDE_NORMAL = 0, ///< peripheral signal selected via \ref gpio_set_function GPIO_OVERRIDE_INVERT = 1, ///< invert peripheral signal selected via \ref gpio_set_function GPIO_OVERRIDE_LOW = 2, ///< drive low/disable output GPIO_OVERRIDE_HIGH = 3, ///< drive high/enable output }; /*! \brief Slew rate limiting levels for GPIO outputs * \ingroup hardware_gpio * * Slew rate limiting increases the minimum rise/fall time when a GPIO output * is lightly loaded, which can help to reduce electromagnetic emissions. * \sa gpio_set_slew_rate */ enum gpio_slew_rate { GPIO_SLEW_RATE_SLOW = 0, ///< Slew rate limiting enabled GPIO_SLEW_RATE_FAST = 1 ///< Slew rate limiting disabled }; /*! \brief Drive strength levels for GPIO outputs * \ingroup hardware_gpio * * Drive strength levels for GPIO outputs. * \sa gpio_set_drive_strength */ enum gpio_drive_strength { GPIO_DRIVE_STRENGTH_2MA = 0, ///< 2 mA nominal drive strength GPIO_DRIVE_STRENGTH_4MA = 1, ///< 4 mA nominal drive strength GPIO_DRIVE_STRENGTH_8MA = 2, ///< 8 mA nominal drive strength GPIO_DRIVE_STRENGTH_12MA = 3 ///< 12 mA nominal drive strength }; static inline void check_gpio_param(__unused uint gpio) { invalid_params_if(HARDWARE_GPIO, gpio >= NUM_BANK0_GPIOS); } // ---------------------------------------------------------------------------- // Pad Controls + IO Muxing // ---------------------------------------------------------------------------- // Declarations for gpio.c /*! \brief Select GPIO function * \ingroup hardware_gpio * * \param gpio GPIO number * \param fn Which GPIO function select to use from list \ref gpio_function_t */ void gpio_set_function(uint gpio, gpio_function_t fn); /*! \brief Select the function for multiple GPIOs * \ingroup hardware_gpio * * \sa gpio_set_function * \param gpio_mask Mask with 1 bit per GPIO number to set the function for * \param fn Which GPIO function select to use from list \ref gpio_function_t */ void gpio_set_function_masked(uint32_t gpio_mask, gpio_function_t fn); /*! \brief Select the function for multiple GPIOs * \ingroup hardware_gpio * * \sa gpio_set_function * \param gpio_mask Mask with 1 bit per GPIO number to set the function for * \param fn Which GPIO function select to use from list \ref gpio_function_t */ void gpio_set_function_masked64(uint64_t gpio_mask, gpio_function_t fn); /*! \brief Determine current GPIO function * \ingroup hardware_gpio * * \param gpio GPIO number * \return Which GPIO function is currently selected from list \ref gpio_function_t */ gpio_function_t gpio_get_function(uint gpio); /*! \brief Select up and down pulls on specific GPIO * \ingroup hardware_gpio * * \param gpio GPIO number * \param up If true set a pull up on the GPIO * \param down If true set a pull down on the GPIO * * \note On the RP2040, setting both pulls enables a "bus keep" function, * i.e. a weak pull to whatever is current high/low state of GPIO. */ void gpio_set_pulls(uint gpio, bool up, bool down); /*! \brief Set specified GPIO to be pulled up. * \ingroup hardware_gpio * * \param gpio GPIO number */ static inline void gpio_pull_up(uint gpio) { gpio_set_pulls(gpio, true, false); } /*! \brief Determine if the specified GPIO is pulled up. * \ingroup hardware_gpio * * \param gpio GPIO number * \return true if the GPIO is pulled up */ static inline bool gpio_is_pulled_up(uint gpio) { return (pads_bank0_hw->io[gpio] & PADS_BANK0_GPIO0_PUE_BITS) != 0; } /*! \brief Set specified GPIO to be pulled down. * \ingroup hardware_gpio * * \param gpio GPIO number */ static inline void gpio_pull_down(uint gpio) { gpio_set_pulls(gpio, false, true); } /*! \brief Determine if the specified GPIO is pulled down. * \ingroup hardware_gpio * * \param gpio GPIO number * \return true if the GPIO is pulled down */ static inline bool gpio_is_pulled_down(uint gpio) { return (pads_bank0_hw->io[gpio] & PADS_BANK0_GPIO0_PDE_BITS) != 0; } /*! \brief Disable pulls on specified GPIO * \ingroup hardware_gpio * * \param gpio GPIO number */ static inline void gpio_disable_pulls(uint gpio) { gpio_set_pulls(gpio, false, false); } /*! \brief Set GPIO IRQ override * \ingroup hardware_gpio * * Optionally invert a GPIO IRQ signal, or drive it high or low * * \param gpio GPIO number * \param value See \ref gpio_override */ void gpio_set_irqover(uint gpio, uint value); /*! \brief Set GPIO output override * \ingroup hardware_gpio * * \param gpio GPIO number * \param value See \ref gpio_override */ void gpio_set_outover(uint gpio, uint value); /*! \brief Select GPIO input override * \ingroup hardware_gpio * * \param gpio GPIO number * \param value See \ref gpio_override */ void gpio_set_inover(uint gpio, uint value); /*! \brief Select GPIO output enable override * \ingroup hardware_gpio * * \param gpio GPIO number * \param value See \ref gpio_override */ void gpio_set_oeover(uint gpio, uint value); /*! \brief Enable GPIO input * \ingroup hardware_gpio * * \param gpio GPIO number * \param enabled true to enable input on specified GPIO */ void gpio_set_input_enabled(uint gpio, bool enabled); /*! \brief Enable/disable GPIO input hysteresis (Schmitt trigger) * \ingroup hardware_gpio * * Enable or disable the Schmitt trigger hysteresis on a given GPIO. This is * enabled on all GPIOs by default. Disabling input hysteresis can lead to * inconsistent readings when the input signal has very long rise or fall * times, but slightly reduces the GPIO's input delay. * * \sa gpio_is_input_hysteresis_enabled * \param gpio GPIO number * \param enabled true to enable input hysteresis on specified GPIO */ void gpio_set_input_hysteresis_enabled(uint gpio, bool enabled); /*! \brief Determine whether input hysteresis is enabled on a specified GPIO * \ingroup hardware_gpio * * \sa gpio_set_input_hysteresis_enabled * \param gpio GPIO number */ bool gpio_is_input_hysteresis_enabled(uint gpio); /*! \brief Set slew rate for a specified GPIO * \ingroup hardware_gpio * * \sa gpio_get_slew_rate * \param gpio GPIO number * \param slew GPIO output slew rate */ void gpio_set_slew_rate(uint gpio, enum gpio_slew_rate slew); /*! \brief Determine current slew rate for a specified GPIO * \ingroup hardware_gpio * * \sa gpio_set_slew_rate * \param gpio GPIO number * \return Current slew rate of that GPIO */ enum gpio_slew_rate gpio_get_slew_rate(uint gpio); /*! \brief Set drive strength for a specified GPIO * \ingroup hardware_gpio * * \sa gpio_get_drive_strength * \param gpio GPIO number * \param drive GPIO output drive strength */ void gpio_set_drive_strength(uint gpio, enum gpio_drive_strength drive); /*! \brief Determine current drive strength for a specified GPIO * \ingroup hardware_gpio * * \sa gpio_set_drive_strength * \param gpio GPIO number * \return Current drive strength of that GPIO */ enum gpio_drive_strength gpio_get_drive_strength(uint gpio); /*! \brief Enable or disable specific interrupt events for specified GPIO * \ingroup hardware_gpio * * This function sets which GPIO events cause a GPIO interrupt on the calling core. See * \ref gpio_set_irq_callback, \ref gpio_set_irq_enabled_with_callback and * \ref gpio_add_raw_irq_handler to set up a GPIO interrupt handler to handle the events. * * \note The IO IRQs are independent per-processor. This configures the interrupt events for * the processor that calls the function. * * \param gpio GPIO number * \param event_mask Which events will cause an interrupt * \param enabled Enable or disable flag * * Events is a bitmask of the following \ref gpio_irq_level values: * * bit | constant | interrupt * ----|---------------------|------------------------------------ * 0 | GPIO_IRQ_LEVEL_LOW | Continuously while level is low * 1 | GPIO_IRQ_LEVEL_HIGH | Continuously while level is high * 2 | GPIO_IRQ_EDGE_FALL | On each transition from high to low * 3 | GPIO_IRQ_EDGE_RISE | On each transition from low to high * * which are specified in \ref gpio_irq_level */ void gpio_set_irq_enabled(uint gpio, uint32_t event_mask, bool enabled); // PICO_CONFIG: GPIO_IRQ_CALLBACK_ORDER_PRIORITY, IRQ priority order of the default IRQ callback, min=0, max=255, default=PICO_SHARED_IRQ_HANDLER_LOWEST_ORDER_PRIORITY, group=hardware_gpio #ifndef GPIO_IRQ_CALLBACK_ORDER_PRIORITY #define GPIO_IRQ_CALLBACK_ORDER_PRIORITY PICO_SHARED_IRQ_HANDLER_LOWEST_ORDER_PRIORITY #endif // PICO_CONFIG: GPIO_RAW_IRQ_HANDLER_DEFAULT_ORDER_PRIORITY, IRQ priority order of raw IRQ handlers if the priority is not specified, min=0, max=255, default=PICO_SHARED_IRQ_HANDLER_DEFAULT_ORDER_PRIORITY, group=hardware_gpio #ifndef GPIO_RAW_IRQ_HANDLER_DEFAULT_ORDER_PRIORITY #define GPIO_RAW_IRQ_HANDLER_DEFAULT_ORDER_PRIORITY PICO_SHARED_IRQ_HANDLER_DEFAULT_ORDER_PRIORITY #endif /*! \brief Set the generic callback used for GPIO IRQ events for the current core * \ingroup hardware_gpio * * This function sets the callback used for all GPIO IRQs on the current core that are not explicitly * hooked via \ref gpio_add_raw_irq_handler or other gpio_add_raw_irq_handler_ functions. * * This function is called with the GPIO number and event mask for each of the (not explicitly hooked) * GPIOs that have events enabled and that are pending (see \ref gpio_get_irq_event_mask). * * \note The IO IRQs are independent per-processor. This function affects * the processor that calls the function. * * \param callback default user function to call on GPIO irq. Note only one of these can be set per processor. */ void gpio_set_irq_callback(gpio_irq_callback_t callback); /*! \brief Convenience function which performs multiple GPIO IRQ related initializations * \ingroup hardware_gpio * * This method is a slightly eclectic mix of initialization, that: * * \li Updates whether the specified events for the specified GPIO causes an interrupt on the calling core based * on the enable flag. * * \li Sets the callback handler for the calling core to callback (or clears the handler if the callback is NULL). * * \li Enables GPIO IRQs on the current core if enabled is true. * * This method is commonly used to perform a one time setup, and following that any additional IRQs/events are enabled * via \ref gpio_set_irq_enabled. All GPIOs/events added in this way on the same core share the same callback; for multiple * independent handlers for different GPIOs you should use \ref gpio_add_raw_irq_handler and related functions. * * This method is equivalent to: * * \code{.c} * gpio_set_irq_enabled(gpio, event_mask, enabled); * gpio_set_irq_callback(callback); * if (enabled) irq_set_enabled(IO_IRQ_BANK0, true); * \endcode * * \note The IO IRQs are independent per-processor. This method affects only the processor that calls the function. * * \param gpio GPIO number * \param event_mask Which events will cause an interrupt. See \ref gpio_irq_level for details. * \param enabled Enable or disable flag * \param callback user function to call on GPIO irq. if NULL, the callback is removed */ void gpio_set_irq_enabled_with_callback(uint gpio, uint32_t event_mask, bool enabled, gpio_irq_callback_t callback); /*! \brief Enable dormant wake up interrupt for specified GPIO and events * \ingroup hardware_gpio * * This configures IRQs to restart the XOSC or ROSC when they are * disabled in dormant mode * * \param gpio GPIO number * \param event_mask Which events will cause an interrupt. See \ref gpio_irq_level for details. * \param enabled Enable/disable flag */ void gpio_set_dormant_irq_enabled(uint gpio, uint32_t event_mask, bool enabled); /*! \brief Return the current interrupt status (pending events) for the given GPIO * \ingroup hardware_gpio * * \param gpio GPIO number * \return Bitmask of events that are currently pending for the GPIO. See \ref gpio_irq_level for details. * \sa gpio_acknowledge_irq */ static inline uint32_t gpio_get_irq_event_mask(uint gpio) { check_gpio_param(gpio); io_bank0_irq_ctrl_hw_t *irq_ctrl_base = get_core_num() ? &io_bank0_hw->proc1_irq_ctrl : &io_bank0_hw->proc0_irq_ctrl; io_ro_32 *status_reg = &irq_ctrl_base->ints[gpio >> 3u]; return (*status_reg >> (4 * (gpio & 7u))) & 0xfu; } /*! \brief Acknowledge a GPIO interrupt for the specified events on the calling core * \ingroup hardware_gpio * * \note This may be called with a mask of any of valid bits specified in \ref gpio_irq_level, however * it has no effect on \a level sensitive interrupts which remain pending while the GPIO is at the specified * level. When handling \a level sensitive interrupts, you should generally disable the interrupt (see * \ref gpio_set_irq_enabled) and then set it up again later once the GPIO level has changed (or to catch * the opposite level). * * \param gpio GPIO number * * \note For callbacks set with \ref gpio_set_irq_enabled_with_callback, or \ref gpio_set_irq_callback, this function is called automatically. * \param event_mask Bitmask of events to clear. See \ref gpio_irq_level for details. */ void gpio_acknowledge_irq(uint gpio, uint32_t event_mask); /*! \brief Adds a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default callback. The order * relative to the default callback can be controlled via the order_priority parameter (the default callback has the priority * \ref GPIO_IRQ_CALLBACK_ORDER_PRIORITY which defaults to the lowest priority with the intention of it running last). * * This method adds such an explicit GPIO IRQ handler, and disables the "default" callback for the specified GPIOs. * * \note Multiple raw handlers should not be added for the same GPIOs, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * if (gpio_get_irq_event_mask(my_gpio_num2) & my_gpio_event_mask2) { * gpio_acknowledge_irq(my_gpio_num2, my_gpio_event_mask2); * // handle the IRQ * } * } * \endcode * * @param gpio_mask a bit mask of the GPIO numbers that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core * @param order_priority the priority order to determine the relative position of the handler in the list of GPIO IRQ handlers for this core. */ void gpio_add_raw_irq_handler_with_order_priority_masked(uint32_t gpio_mask, irq_handler_t handler, uint8_t order_priority); /*! \brief Adds a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default callback. The order * relative to the default callback can be controlled via the order_priority parameter (the default callback has the priority * \ref GPIO_IRQ_CALLBACK_ORDER_PRIORITY which defaults to the lowest priority with the intention of it running last). * * This method adds such an explicit GPIO IRQ handler, and disables the "default" callback for the specified GPIOs. * * \note Multiple raw handlers should not be added for the same GPIOs, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * if (gpio_get_irq_event_mask(my_gpio_num2) & my_gpio_event_mask2) { * gpio_acknowledge_irq(my_gpio_num2, my_gpio_event_mask2); * // handle the IRQ * } * } * \endcode * * @param gpio_mask a bit mask of the GPIO numbers that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core * @param order_priority the priority order to determine the relative position of the handler in the list of GPIO IRQ handlers for this core. */ void gpio_add_raw_irq_handler_with_order_priority_masked64(uint64_t gpio_mask, irq_handler_t handler, uint8_t order_priority); /*! \brief Adds a raw GPIO IRQ handler for a specific GPIO on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default callback. The order * relative to the default callback can be controlled via the order_priority parameter(the default callback has the priority * \ref GPIO_IRQ_CALLBACK_ORDER_PRIORITY which defaults to the lowest priority with the intention of it running last). * * This method adds such a callback, and disables the "default" callback for the specified GPIO. * * \note Multiple raw handlers should not be added for the same GPIO, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * } * \endcode * * @param gpio the GPIO number that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core * @param order_priority the priority order to determine the relative position of the handler in the list of GPIO IRQ handlers for this core. */ static inline void gpio_add_raw_irq_handler_with_order_priority(uint gpio, irq_handler_t handler, uint8_t order_priority) { check_gpio_param(gpio); #if NUM_BANK0_GPIOS > 32 gpio_add_raw_irq_handler_with_order_priority_masked64(1ull << gpio, handler, order_priority); #else gpio_add_raw_irq_handler_with_order_priority_masked(1u << gpio, handler, order_priority); #endif } /*! \brief Adds a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method adds such a callback, and disables the "default" callback for the specified GPIOs. * * \note Multiple raw handlers should not be added for the same GPIOs, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * if (gpio_get_irq_event_mask(my_gpio_num2) & my_gpio_event_mask2) { * gpio_acknowledge_irq(my_gpio_num2, my_gpio_event_mask2); * // handle the IRQ * } * } * \endcode * * @param gpio_mask a bit mask of the GPIO numbers that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core */ void gpio_add_raw_irq_handler_masked(uint32_t gpio_mask, irq_handler_t handler); /*! \brief Adds a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method adds such a callback, and disables the "default" callback for the specified GPIOs. * * \note Multiple raw handlers should not be added for the same GPIOs, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * if (gpio_get_irq_event_mask(my_gpio_num2) & my_gpio_event_mask2) { * gpio_acknowledge_irq(my_gpio_num2, my_gpio_event_mask2); * // handle the IRQ * } * } * \endcode * * @param gpio_mask a 64 bit mask of the GPIO numbers that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core */ void gpio_add_raw_irq_handler_masked64(uint64_t gpio_mask, irq_handler_t handler); /*! \brief Adds a raw GPIO IRQ handler for a specific GPIO on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method adds such a callback, and disables the "default" callback for the specified GPIO. * * \note Multiple raw handlers should not be added for the same GPIO, and this method will assert if you attempt to. * Internally, this function calls \ref irq_add_shared_handler, which will assert if the maximum number of shared handlers * (configurable via PICO_MAX_IRQ_SHARED_HANDLERS) would be exceeded. * * A raw handler should check for whichever GPIOs and events it handles, and acknowledge them itself; it might look something like: * * \code{.c} * void my_irq_handler(void) { * if (gpio_get_irq_event_mask(my_gpio_num) & my_gpio_event_mask) { * gpio_acknowledge_irq(my_gpio_num, my_gpio_event_mask); * // handle the IRQ * } * } * \endcode * * @param gpio the GPIO number that will no longer be passed to the default callback for this core * @param handler the handler to add to the list of GPIO IRQ handlers for this core */ static inline void gpio_add_raw_irq_handler(uint gpio, irq_handler_t handler) { check_gpio_param(gpio); #if NUM_BANK0_GPIOS > 32 gpio_add_raw_irq_handler_masked64(1ull << gpio, handler); #else gpio_add_raw_irq_handler_masked(1u << gpio, handler); #endif } /*! \brief Removes a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method removes such a callback, and enables the "default" callback for the specified GPIOs. * * @param gpio_mask a bit mask of the GPIO numbers that will now be passed to the default callback for this core * @param handler the handler to remove from the list of GPIO IRQ handlers for this core */ void gpio_remove_raw_irq_handler_masked(uint32_t gpio_mask, irq_handler_t handler); /*! \brief Removes a raw GPIO IRQ handler for the specified GPIOs on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method removes such a callback, and enables the "default" callback for the specified GPIOs. * * @param gpio_mask a bit mask of the GPIO numbers that will now be passed to the default callback for this core * @param handler the handler to remove from the list of GPIO IRQ handlers for this core */ void gpio_remove_raw_irq_handler_masked64(uint64_t gpio_mask, irq_handler_t handler); /*! \brief Removes a raw GPIO IRQ handler for the specified GPIO on the current core * \ingroup hardware_gpio * * In addition to the default mechanism of a single GPIO IRQ event callback per core (see \ref gpio_set_irq_callback), * it is possible to add explicit GPIO IRQ handlers which are called independent of the default event callback. * * This method removes such a callback, and enables the "default" callback for the specified GPIO. * * @param gpio the GPIO number that will now be passed to the default callback for this core * @param handler the handler to remove from the list of GPIO IRQ handlers for this core */ static inline void gpio_remove_raw_irq_handler(uint gpio, irq_handler_t handler) { check_gpio_param(gpio); #if NUM_BANK0_GPIOS > 32 gpio_remove_raw_irq_handler_masked64(1ull << gpio, handler); #else gpio_remove_raw_irq_handler_masked(1u << gpio, handler); #endif } /*! \brief Initialise a GPIO for (enabled I/O and set func to GPIO_FUNC_SIO) * \ingroup hardware_gpio * * Clear the output enable (i.e. set to input). * Clear any output value. * * \param gpio GPIO number */ void gpio_init(uint gpio); /*! \brief Resets a GPIO back to the NULL function, i.e. disables it. * \ingroup hardware_gpio * * \param gpio GPIO number */ void gpio_deinit(uint gpio); /*! \brief Initialise multiple GPIOs (enabled I/O and set func to GPIO_FUNC_SIO) * \ingroup hardware_gpio * * Clear the output enable (i.e. set to input). * Clear any output value. * * \param gpio_mask Mask with 1 bit per GPIO number to initialize */ void gpio_init_mask(uint gpio_mask); // ---------------------------------------------------------------------------- // Input // ---------------------------------------------------------------------------- /*! \brief Get state of a single specified GPIO * \ingroup hardware_gpio * * \param gpio GPIO number * \return Current state of the GPIO. 0 for low, non-zero for high */ static inline bool gpio_get(uint gpio) { #if NUM_BANK0_GPIOS <= 32 return sio_hw->gpio_in & (1u << gpio); #else if (gpio < 32) { return sio_hw->gpio_in & (1u << gpio); } else { return sio_hw->gpio_hi_in & (1u << (gpio - 32)); } #endif } /*! \brief Get raw value of all GPIOs * \ingroup hardware_gpio * * \return Bitmask of raw GPIO values */ static inline uint32_t gpio_get_all(void) { #if PICO_USE_GPIO_COPROCESSOR return gpioc_lo_in_get(); #else return sio_hw->gpio_in; #endif } /*! \brief Get raw value of all GPIOs * \ingroup hardware_gpio * * \return Bitmask of raw GPIO values */ static inline uint64_t gpio_get_all64(void) { #if PICO_USE_GPIO_COPROCESSOR return gpioc_hilo_in_get(); #elif NUM_BANK0_GPIOS <= 32 return sio_hw->gpio_in; #else return sio_hw->gpio_in | (((uint64_t)sio_hw->gpio_hi_in) << 32u); #endif } // ---------------------------------------------------------------------------- // Output // ---------------------------------------------------------------------------- /*! \brief Drive high every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to set */ static inline void gpio_set_mask(uint32_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_out_set(mask); #else sio_hw->gpio_set = mask; #endif } /*! \brief Drive high every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to set */ static inline void gpio_set_mask64(uint64_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_out_set(mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_set = (uint32_t)mask; #else sio_hw->gpio_set = (uint32_t)mask; sio_hw->gpio_hi_set = (uint32_t)(mask >> 32u); #endif } /*! \brief Drive high every GPIO appearing in mask * \ingroup hardware_gpio * * \param n the base GPIO index of the mask to update. n == 0 means 0->31, n == 1 mean 32->63 etc. * \param mask Bitmask of 32 GPIO values to set */ static inline void gpio_set_mask_n(uint n, uint32_t mask) { if (!n) { gpio_set_mask(mask); } else if (n == 1) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hi_out_set(mask); #elif NUM_BANK0_GPIOS >= 32 sio_hw->gpio_hi_set = mask; #endif } } /*! \brief Drive low every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to clear */ static inline void gpio_clr_mask(uint32_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_out_clr(mask); #else sio_hw->gpio_clr = mask; #endif } /*! \brief Drive low every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to clear */ static inline void gpio_clr_mask64(uint64_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_out_clr(mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_clr = (uint32_t)mask; #else sio_hw->gpio_clr = (uint32_t)mask; sio_hw->gpio_hi_clr = (uint32_t)(mask >> 32u); #endif } /*! \brief Drive low every GPIO appearing in mask * \ingroup hardware_gpio * * \param n the base GPIO index of the mask to update. n == 0 means 0->31, n == 1 mean 32->63 etc. * \param mask Bitmask of 32 GPIO values to clear */ static inline void gpio_clr_mask_n(uint n, uint32_t mask) { if (!n) { gpio_clr_mask(mask); } else if (n == 1) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hi_out_clr(mask); #elif NUM_BANK0_GPIOS >= 32 sio_hw->gpio_hi_clr = mask; #endif } } /*! \brief Toggle every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to toggle */ static inline void gpio_xor_mask(uint32_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_out_xor(mask); #else sio_hw->gpio_togl = mask; #endif } /*! \brief Toggle every GPIO appearing in mask * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to toggle */ static inline void gpio_xor_mask64(uint64_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_out_xor(mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_togl = (uint32_t)mask; #else sio_hw->gpio_togl = (uint32_t)mask; sio_hw->gpio_hi_togl = (uint32_t)(mask >> 32u); #endif } /*! \brief Toggle every GPIO appearing in mask * \ingroup hardware_gpio * * \param n the base GPIO index of the mask to update. n == 0 means 0->31, n == 1 mean 32->63 etc. * \param mask Bitmask of 32 GPIO values to toggle */ static inline void gpio_xor_mask_n(uint n, uint32_t mask) { if (!n) { gpio_xor_mask(mask); } else if (n == 1) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hi_out_xor(mask); #elif NUM_BANK0_GPIOS >= 32 sio_hw->gpio_hi_togl = mask; #endif } } /*! \brief Drive GPIOs high/low depending on parameters * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to change * \param value Value to set * * For each 1 bit in \p mask, drive that pin to the value given by * corresponding bit in \p value, leaving other pins unchanged. * Since this uses the TOGL alias, it is concurrency-safe with e.g. an IRQ * bashing different pins from the same core. */ static inline void gpio_put_masked(uint32_t mask, uint32_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_out_xor((gpioc_lo_out_get() ^ value) & mask); #else sio_hw->gpio_togl = (sio_hw->gpio_out ^ value) & mask; #endif } /*! \brief Drive GPIOs high/low depending on parameters * \ingroup hardware_gpio * * \param mask Bitmask of GPIO values to change * \param value Value to set * * For each 1 bit in \p mask, drive that pin to the value given by * corresponding bit in \p value, leaving other pins unchanged. * Since this uses the TOGL alias, it is concurrency-safe with e.g. an IRQ * bashing different pins from the same core. */ static inline void gpio_put_masked64(uint64_t mask, uint64_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_out_xor((gpioc_hilo_out_get() ^ value) & mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_togl = (sio_hw->gpio_out ^ (uint32_t)value) & (uint32_t)mask; #else sio_hw->gpio_togl = (sio_hw->gpio_out ^ (uint32_t)value) & (uint32_t)mask; sio_hw->gpio_hi_togl = (sio_hw->gpio_hi_out ^ (uint32_t)(value>>32u)) & (uint32_t)(mask>>32u); #endif } /*! \brief Drive GPIOs high/low depending on parameters * \ingroup hardware_gpio * * \param n the base GPIO index of the mask to update. n == 0 means 0->31, n == 1 mean 32->63 etc. * \param mask Bitmask of GPIO values to change * \param value Value to set * * For each 1 bit in \p mask, drive that pin to the value given by * corresponding bit in \p value, leaving other pins unchanged. * Since this uses the TOGL alias, it is concurrency-safe with e.g. an IRQ * bashing different pins from the same core. */ static inline void gpio_put_masked_n(uint n, uint32_t mask, uint32_t value) { if (!n) { gpio_put_masked(mask, value); } else if (n == 1) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hi_out_xor((gpioc_hi_out_get() ^ value) & mask); #else sio_hw->gpio_hi_togl = (sio_hw->gpio_hi_out ^ value) & mask; #endif } } /*! \brief Drive all pins simultaneously * \ingroup hardware_gpio * * \param value Bitmask of GPIO values to change */ static inline void gpio_put_all(uint32_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_out_put(value); #else sio_hw->gpio_out = value; #endif } /*! \brief Drive all pins simultaneously * \ingroup hardware_gpio * * \param value Bitmask of GPIO values to change */ static inline void gpio_put_all64(uint64_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_out_put(value); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_out = (uint32_t)value; #else sio_hw->gpio_out = (uint32_t)value; sio_hw->gpio_hi_out = (uint32_t)(value >> 32u); #endif } /*! \brief Drive a single GPIO high/low * \ingroup hardware_gpio * * \param gpio GPIO number * \param value If false clear the GPIO, otherwise set it. */ static inline void gpio_put(uint gpio, bool value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_bit_out_put(gpio, value); #elif NUM_BANK0_GPIOS <= 32 uint32_t mask = 1ul << gpio; if (value) gpio_set_mask(mask); else gpio_clr_mask(mask); #else uint32_t mask = 1ul << (gpio & 0x1fu); if (gpio < 32) { if (value) { sio_hw->gpio_set = mask; } else { sio_hw->gpio_clr = mask; } } else { if (value) { sio_hw->gpio_hi_set = mask; } else { sio_hw->gpio_hi_clr = mask; } } #endif } /*! \brief Determine whether a GPIO is currently driven high or low * \ingroup hardware_gpio * * This function returns the high/low output level most recently assigned to a * GPIO via gpio_put() or similar. This is the value that is presented outward * to the IO muxing, *not* the input level back from the pad (which can be * read using gpio_get()). * * To avoid races, this function must not be used for read-modify-write * sequences when driving GPIOs -- instead functions like gpio_put() should be * used to atomically update GPIOs. This accessor is intended for debug use * only. * * \param gpio GPIO number * \return true if the GPIO output level is high, false if low. */ static inline bool gpio_get_out_level(uint gpio) { #if NUM_BANK0_GPIOS <= 32 return sio_hw->gpio_out & (1u << gpio); #else uint32_t bits = gpio < 32 ? sio_hw->gpio_out : sio_hw->gpio_hi_out; return bits & (1u << (gpio & 0x1fu)); #endif } // ---------------------------------------------------------------------------- // Direction // ---------------------------------------------------------------------------- /*! \brief Set a number of GPIOs to output * \ingroup hardware_gpio * * Switch all GPIOs in "mask" to output * * \param mask Bitmask of GPIO to set to output */ static inline void gpio_set_dir_out_masked(uint32_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_oe_set(mask); #else sio_hw->gpio_oe_set = mask; #endif } /*! \brief Set a number of GPIOs to output * \ingroup hardware_gpio * * Switch all GPIOs in "mask" to output * * \param mask Bitmask of GPIO to set to output */ static inline void gpio_set_dir_out_masked64(uint64_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_oe_set(mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_oe_set = mask; #else sio_hw->gpio_oe_set = (uint32_t)mask; sio_hw->gpio_hi_oe_set = (uint32_t)(mask >> 32u); #endif } /*! \brief Set a number of GPIOs to input * \ingroup hardware_gpio * * \param mask Bitmask of GPIO to set to input */ static inline void gpio_set_dir_in_masked(uint32_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_oe_clr(mask); #else sio_hw->gpio_oe_clr = mask; #endif } /*! \brief Set a number of GPIOs to input * \ingroup hardware_gpio * * \param mask Bitmask of GPIO to set to input */ static inline void gpio_set_dir_in_masked64(uint64_t mask) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_oe_clr(mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_oe_clr = mask; #else sio_hw->gpio_oe_clr = (uint32_t)mask; sio_hw->gpio_hi_oe_clr = (uint32_t)(mask >> 32u); #endif } /*! \brief Set multiple GPIO directions * \ingroup hardware_gpio * * \param mask Bitmask of GPIO to set to input, as bits 0-29 * \param value Values to set * * For each 1 bit in "mask", switch that pin to the direction given by * corresponding bit in "value", leaving other pins unchanged. * E.g. gpio_set_dir_masked(0x3, 0x2); -> set pin 0 to input, pin 1 to output, * simultaneously. */ static inline void gpio_set_dir_masked(uint32_t mask, uint32_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_oe_xor((gpioc_lo_oe_get() ^ value) & mask); #else sio_hw->gpio_oe_togl = (sio_hw->gpio_oe ^ value) & mask; #endif } /*! \brief Set multiple GPIO directions * \ingroup hardware_gpio * * \param mask Bitmask of GPIO to set to input, as bits 0-29 * \param value Values to set * * For each 1 bit in "mask", switch that pin to the direction given by * corresponding bit in "value", leaving other pins unchanged. * E.g. gpio_set_dir_masked(0x3, 0x2); -> set pin 0 to input, pin 1 to output, * simultaneously. */ static inline void gpio_set_dir_masked64(uint64_t mask, uint64_t value) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_oe_xor((gpioc_hilo_oe_get() ^ value) & mask); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_oe_togl = (sio_hw->gpio_oe ^ (uint32_t)value) & (uint32_t)mask; #else sio_hw->gpio_oe_togl = (sio_hw->gpio_oe ^ (uint32_t)value) & (uint32_t)mask; sio_hw->gpio_hi_oe_togl = (sio_hw->gpio_hi_oe ^ (uint32_t)(value >> 32u)) & (uint32_t)(mask >> 32u); #endif } /*! \brief Set direction of all pins simultaneously. * \ingroup hardware_gpio * * \param values individual settings for each gpio; for GPIO N, bit N is 1 for out, 0 for in */ static inline void gpio_set_dir_all_bits(uint32_t values) { #if PICO_USE_GPIO_COPROCESSOR gpioc_lo_oe_put(values); #else sio_hw->gpio_oe = values; #endif } /*! \brief Set direction of all pins simultaneously. * \ingroup hardware_gpio * * \param values individual settings for each gpio; for GPIO N, bit N is 1 for out, 0 for in */ static inline void gpio_set_dir_all_bits64(uint64_t values) { #if PICO_USE_GPIO_COPROCESSOR gpioc_hilo_oe_put(values); #elif NUM_BANK0_GPIOS <= 32 sio_hw->gpio_oe = (uint32_t)values; #else sio_hw->gpio_oe = (uint32_t)values; sio_hw->gpio_hi_oe = (uint32_t)(values >> 32u); #endif } /*! \brief Set a single GPIO direction * \ingroup hardware_gpio * * \param gpio GPIO number * \param out true for out, false for in */ static inline void gpio_set_dir(uint gpio, bool out) { #if PICO_USE_GPIO_COPROCESSOR gpioc_bit_oe_put(gpio, out); #elif PICO_RP2040 || NUM_BANK0_GPIOS <= 32 uint32_t mask = 1ul << gpio; if (out) gpio_set_dir_out_masked(mask); else gpio_set_dir_in_masked(mask); #else uint32_t mask = 1u << (gpio & 0x1fu); if (gpio < 32) { if (out) { sio_hw->gpio_oe_set = mask; } else { sio_hw->gpio_oe_clr = mask; } } else { if (out) { sio_hw->gpio_hi_oe_set = mask; } else { sio_hw->gpio_hi_oe_clr = mask; } } #endif } /*! \brief Check if a specific GPIO direction is OUT * \ingroup hardware_gpio * * \param gpio GPIO number * \return true if the direction for the pin is OUT */ static inline bool gpio_is_dir_out(uint gpio) { #if NUM_BANK0_GPIOS <= 32 return sio_hw->gpio_oe & (1u << (gpio)); #else uint32_t bits = gpio < 32 ? sio_hw->gpio_oe : sio_hw->gpio_hi_oe; return bits & (1u << (gpio & 0x1fu)); #endif } /*! \brief Get a specific GPIO direction * \ingroup hardware_gpio * * \param gpio GPIO number * \return 1 for out, 0 for in */ static inline uint gpio_get_dir(uint gpio) { return gpio_is_dir_out(gpio); // note GPIO_OUT is 1/true and GPIO_IN is 0/false anyway } #if PICO_SECURE static inline void gpio_assign_to_ns(uint gpio, bool ns) { check_gpio_param(gpio); if (ns) hw_set_bits(&accessctrl_hw->gpio_nsmask[gpio/32], 1u << (gpio & 0x1fu)); else hw_clear_bits(&accessctrl_hw->gpio_nsmask[gpio/32], 1u << (gpio & 0x1fu)); } #endif extern void gpio_debug_pins_init(void); #ifdef __cplusplus } #endif // PICO_CONFIG: PICO_DEBUG_PIN_BASE, First pin to use for debug output (if enabled), min=0, max=31 on RP2350B, 29 otherwise, default=19, group=hardware_gpio #ifndef PICO_DEBUG_PIN_BASE #define PICO_DEBUG_PIN_BASE 19u #endif // PICO_CONFIG: PICO_DEBUG_PIN_COUNT, Number of pins to use for debug output (if enabled), min=1, max=32 on RP2350B, 30 otherwise, default=3, group=hardware_gpio #ifndef PICO_DEBUG_PIN_COUNT #define PICO_DEBUG_PIN_COUNT 3u #endif #ifndef __cplusplus // note these two macros may only be used once per and only apply per compilation unit (hence the CU_) #define CU_REGISTER_DEBUG_PINS(...) enum __unused DEBUG_PIN_TYPE { _none = 0, __VA_ARGS__ }; static enum DEBUG_PIN_TYPE __selected_debug_pins; #define CU_SELECT_DEBUG_PINS(x) static enum DEBUG_PIN_TYPE __selected_debug_pins = (x); #define DEBUG_PINS_ENABLED(p) (__selected_debug_pins == (p)) #else #define CU_REGISTER_DEBUG_PINS(p...) \ enum DEBUG_PIN_TYPE { _none = 0, p }; \ template class __debug_pin_settings { \ public: \ static inline bool enabled() { return false; } \ }; #define CU_SELECT_DEBUG_PINS(x) template<> inline bool __debug_pin_settings::enabled() { return true; }; #define DEBUG_PINS_ENABLED(p) (__debug_pin_settings

::enabled()) #endif #define DEBUG_PINS_SET(p, v) if (DEBUG_PINS_ENABLED(p)) gpio_set_mask((unsigned)(v)<