451 строка
20 KiB
ReStructuredText
451 строка
20 KiB
ReStructuredText
================================
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GPIO Descriptor Driver Interface
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================================
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This document serves as a guide for GPIO chip drivers writers. Note that it
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describes the new descriptor-based interface. For a description of the
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deprecated integer-based GPIO interface please refer to gpio-legacy.txt.
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Each GPIO controller driver needs to include the following header, which defines
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the structures used to define a GPIO driver:
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#include <linux/gpio/driver.h>
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Internal Representation of GPIOs
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================================
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Inside a GPIO driver, individual GPIOs are identified by their hardware number,
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which is a unique number between 0 and n, n being the number of GPIOs managed by
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the chip. This number is purely internal: the hardware number of a particular
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GPIO descriptor is never made visible outside of the driver.
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On top of this internal number, each GPIO also need to have a global number in
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the integer GPIO namespace so that it can be used with the legacy GPIO
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interface. Each chip must thus have a "base" number (which can be automatically
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assigned), and for each GPIO the global number will be (base + hardware number).
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Although the integer representation is considered deprecated, it still has many
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users and thus needs to be maintained.
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So for example one platform could use numbers 32-159 for GPIOs, with a
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controller defining 128 GPIOs at a "base" of 32 ; while another platform uses
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numbers 0..63 with one set of GPIO controllers, 64-79 with another type of GPIO
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controller, and on one particular board 80-95 with an FPGA. The numbers need not
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be contiguous; either of those platforms could also use numbers 2000-2063 to
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identify GPIOs in a bank of I2C GPIO expanders.
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Controller Drivers: gpio_chip
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=============================
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In the gpiolib framework each GPIO controller is packaged as a "struct
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gpio_chip" (see linux/gpio/driver.h for its complete definition) with members
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common to each controller of that type:
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- methods to establish GPIO line direction
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- methods used to access GPIO line values
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- method to set electrical configuration for a given GPIO line
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- method to return the IRQ number associated to a given GPIO line
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- flag saying whether calls to its methods may sleep
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- optional line names array to identify lines
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- optional debugfs dump method (showing extra state like pullup config)
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- optional base number (will be automatically assigned if omitted)
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- optional label for diagnostics and GPIO chip mapping using platform data
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The code implementing a gpio_chip should support multiple instances of the
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controller, possibly using the driver model. That code will configure each
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gpio_chip and issue ``gpiochip_add[_data]()`` or ``devm_gpiochip_add_data()``.
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Removing a GPIO controller should be rare; use ``[devm_]gpiochip_remove()``
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when it is unavoidable.
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Often a gpio_chip is part of an instance-specific structure with states not
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exposed by the GPIO interfaces, such as addressing, power management, and more.
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Chips such as audio codecs will have complex non-GPIO states.
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Any debugfs dump method should normally ignore signals which haven't been
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requested as GPIOs. They can use gpiochip_is_requested(), which returns either
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NULL or the label associated with that GPIO when it was requested.
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RT_FULL: the GPIO driver should not use spinlock_t or any sleepable APIs
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(like PM runtime) in its gpio_chip implementation (.get/.set and direction
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control callbacks) if it is expected to call GPIO APIs from atomic context
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on -RT (inside hard IRQ handlers and similar contexts). Normally this should
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not be required.
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GPIO electrical configuration
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-----------------------------
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GPIOs can be configured for several electrical modes of operation by using the
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.set_config() callback. Currently this API supports setting debouncing and
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single-ended modes (open drain/open source). These settings are described
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below.
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The .set_config() callback uses the same enumerators and configuration
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semantics as the generic pin control drivers. This is not a coincidence: it is
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possible to assign the .set_config() to the function gpiochip_generic_config()
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which will result in pinctrl_gpio_set_config() being called and eventually
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ending up in the pin control back-end "behind" the GPIO controller, usually
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closer to the actual pins. This way the pin controller can manage the below
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listed GPIO configurations.
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If a pin controller back-end is used, the GPIO controller or hardware
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description needs to provide "GPIO ranges" mapping the GPIO line offsets to pin
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numbers on the pin controller so they can properly cross-reference each other.
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GPIOs with debounce support
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---------------------------
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Debouncing is a configuration set to a pin indicating that it is connected to
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a mechanical switch or button, or similar that may bounce. Bouncing means the
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line is pulled high/low quickly at very short intervals for mechanical
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reasons. This can result in the value being unstable or irqs fireing repeatedly
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unless the line is debounced.
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Debouncing in practice involves setting up a timer when something happens on
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the line, wait a little while and then sample the line again, so see if it
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still has the same value (low or high). This could also be repeated by a clever
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state machine, waiting for a line to become stable. In either case, it sets
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a certain number of milliseconds for debouncing, or just "on/off" if that time
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is not configurable.
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GPIOs with open drain/source support
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------------------------------------
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Open drain (CMOS) or open collector (TTL) means the line is not actively driven
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high: instead you provide the drain/collector as output, so when the transistor
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is not open, it will present a high-impedance (tristate) to the external rail::
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CMOS CONFIGURATION TTL CONFIGURATION
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||--- out +--- out
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in ----|| |/
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||--+ in ----|
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GND GND
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This configuration is normally used as a way to achieve one of two things:
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- Level-shifting: to reach a logical level higher than that of the silicon
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where the output resides.
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- inverse wire-OR on an I/O line, for example a GPIO line, making it possible
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for any driving stage on the line to drive it low even if any other output
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to the same line is simultaneously driving it high. A special case of this
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is driving the SCL and SCA lines of an I2C bus, which is by definition a
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wire-OR bus.
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Both usecases require that the line be equipped with a pull-up resistor. This
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resistor will make the line tend to high level unless one of the transistors on
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the rail actively pulls it down.
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The level on the line will go as high as the VDD on the pull-up resistor, which
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may be higher than the level supported by the transistor, achieving a
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level-shift to the higher VDD.
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Integrated electronics often have an output driver stage in the form of a CMOS
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"totem-pole" with one N-MOS and one P-MOS transistor where one of them drives
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the line high and one of them drives the line low. This is called a push-pull
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output. The "totem-pole" looks like so::
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VDD
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OD ||--+
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+--/ ---o|| P-MOS-FET
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IN --+ +----- out
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+--/ ----|| N-MOS-FET
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OS ||--+
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GND
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The desired output signal (e.g. coming directly from some GPIO output register)
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arrives at IN. The switches named "OD" and "OS" are normally closed, creating
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a push-pull circuit.
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Consider the little "switches" named "OD" and "OS" that enable/disable the
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P-MOS or N-MOS transistor right after the split of the input. As you can see,
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either transistor will go totally numb if this switch is open. The totem-pole
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is then halved and give high impedance instead of actively driving the line
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high or low respectively. That is usually how software-controlled open
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drain/source works.
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Some GPIO hardware come in open drain / open source configuration. Some are
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hard-wired lines that will only support open drain or open source no matter
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what: there is only one transistor there. Some are software-configurable:
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by flipping a bit in a register the output can be configured as open drain
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or open source, in practice by flicking open the switches labeled "OD" and "OS"
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in the drawing above.
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By disabling the P-MOS transistor, the output can be driven between GND and
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high impedance (open drain), and by disabling the N-MOS transistor, the output
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can be driven between VDD and high impedance (open source). In the first case,
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a pull-up resistor is needed on the outgoing rail to complete the circuit, and
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in the second case, a pull-down resistor is needed on the rail.
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Hardware that supports open drain or open source or both, can implement a
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special callback in the gpio_chip: .set_config() that takes a generic
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pinconf packed value telling whether to configure the line as open drain,
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open source or push-pull. This will happen in response to the
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GPIO_OPEN_DRAIN or GPIO_OPEN_SOURCE flag set in the machine file, or coming
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from other hardware descriptions.
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If this state can not be configured in hardware, i.e. if the GPIO hardware does
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not support open drain/open source in hardware, the GPIO library will instead
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use a trick: when a line is set as output, if the line is flagged as open
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drain, and the IN output value is low, it will be driven low as usual. But
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if the IN output value is set to high, it will instead *NOT* be driven high,
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instead it will be switched to input, as input mode is high impedance, thus
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achieveing an "open drain emulation" of sorts: electrically the behaviour will
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be identical, with the exception of possible hardware glitches when switching
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the mode of the line.
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For open source configuration the same principle is used, just that instead
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of actively driving the line low, it is set to input.
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GPIO drivers providing IRQs
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---------------------------
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It is custom that GPIO drivers (GPIO chips) are also providing interrupts,
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most often cascaded off a parent interrupt controller, and in some special
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cases the GPIO logic is melded with a SoC's primary interrupt controller.
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The IRQ portions of the GPIO block are implemented using an irqchip, using
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the header <linux/irq.h>. So basically such a driver is utilizing two sub-
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systems simultaneously: gpio and irq.
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RT_FULL: a realtime compliant GPIO driver should not use spinlock_t or any
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sleepable APIs (like PM runtime) as part of its irq_chip implementation.
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* spinlock_t should be replaced with raw_spinlock_t [1].
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* If sleepable APIs have to be used, these can be done from the .irq_bus_lock()
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and .irq_bus_unlock() callbacks, as these are the only slowpath callbacks
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on an irqchip. Create the callbacks if needed [2].
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GPIO irqchips usually fall in one of two categories:
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* CHAINED GPIO irqchips: these are usually the type that is embedded on
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an SoC. This means that there is a fast IRQ flow handler for the GPIOs that
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gets called in a chain from the parent IRQ handler, most typically the
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system interrupt controller. This means that the GPIO irqchip handler will
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be called immediately from the parent irqchip, while holding the IRQs
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disabled. The GPIO irqchip will then end up calling something like this
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sequence in its interrupt handler::
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static irqreturn_t foo_gpio_irq(int irq, void *data)
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chained_irq_enter(...);
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generic_handle_irq(...);
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chained_irq_exit(...);
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Chained GPIO irqchips typically can NOT set the .can_sleep flag on
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struct gpio_chip, as everything happens directly in the callbacks: no
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slow bus traffic like I2C can be used.
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RT_FULL: Note, chained IRQ handlers will not be forced threaded on -RT.
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As result, spinlock_t or any sleepable APIs (like PM runtime) can't be used
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in chained IRQ handler.
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If required (and if it can't be converted to the nested threaded GPIO irqchip)
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a chained IRQ handler can be converted to generic irq handler and this way
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it will be a threaded IRQ handler on -RT and a hard IRQ handler on non-RT
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(for example, see [3]).
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Know W/A: The generic_handle_irq() is expected to be called with IRQ disabled,
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so the IRQ core will complain if it is called from an IRQ handler which is
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forced to a thread. The "fake?" raw lock can be used to W/A this problem::
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raw_spinlock_t wa_lock;
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static irqreturn_t omap_gpio_irq_handler(int irq, void *gpiobank)
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unsigned long wa_lock_flags;
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raw_spin_lock_irqsave(&bank->wa_lock, wa_lock_flags);
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generic_handle_irq(irq_find_mapping(bank->chip.irq.domain, bit));
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raw_spin_unlock_irqrestore(&bank->wa_lock, wa_lock_flags);
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* GENERIC CHAINED GPIO irqchips: these are the same as "CHAINED GPIO irqchips",
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but chained IRQ handlers are not used. Instead GPIO IRQs dispatching is
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performed by generic IRQ handler which is configured using request_irq().
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The GPIO irqchip will then end up calling something like this sequence in
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its interrupt handler::
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static irqreturn_t gpio_rcar_irq_handler(int irq, void *dev_id)
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for each detected GPIO IRQ
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generic_handle_irq(...);
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RT_FULL: Such kind of handlers will be forced threaded on -RT, as result IRQ
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core will complain that generic_handle_irq() is called with IRQ enabled and
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the same W/A as for "CHAINED GPIO irqchips" can be applied.
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* NESTED THREADED GPIO irqchips: these are off-chip GPIO expanders and any
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other GPIO irqchip residing on the other side of a sleeping bus. Of course
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such drivers that need slow bus traffic to read out IRQ status and similar,
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traffic which may in turn incur other IRQs to happen, cannot be handled
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in a quick IRQ handler with IRQs disabled. Instead they need to spawn a
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thread and then mask the parent IRQ line until the interrupt is handled
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by the driver. The hallmark of this driver is to call something like
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this in its interrupt handler::
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static irqreturn_t foo_gpio_irq(int irq, void *data)
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...
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handle_nested_irq(irq);
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The hallmark of threaded GPIO irqchips is that they set the .can_sleep
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flag on struct gpio_chip to true, indicating that this chip may sleep
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when accessing the GPIOs.
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To help out in handling the set-up and management of GPIO irqchips and the
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associated irqdomain and resource allocation callbacks, the gpiolib has
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some helpers that can be enabled by selecting the GPIOLIB_IRQCHIP Kconfig
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symbol:
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* gpiochip_irqchip_add(): adds a chained irqchip to a gpiochip. It will pass
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the struct gpio_chip* for the chip to all IRQ callbacks, so the callbacks
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need to embed the gpio_chip in its state container and obtain a pointer
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to the container using container_of().
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(See Documentation/driver-model/design-patterns.txt)
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* gpiochip_irqchip_add_nested(): adds a nested irqchip to a gpiochip.
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Apart from that it works exactly like the chained irqchip.
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* gpiochip_set_chained_irqchip(): sets up a chained irq handler for a
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gpio_chip from a parent IRQ and passes the struct gpio_chip* as handler
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data. (Notice handler data, since the irqchip data is likely used by the
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parent irqchip!).
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* gpiochip_set_nested_irqchip(): sets up a nested irq handler for a
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gpio_chip from a parent IRQ. As the parent IRQ has usually been
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explicitly requested by the driver, this does very little more than
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mark all the child IRQs as having the other IRQ as parent.
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If there is a need to exclude certain GPIOs from the IRQ domain, you can
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set .irq.need_valid_mask of the gpiochip before gpiochip_add_data() is
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called. This allocates an .irq.valid_mask with as many bits set as there
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are GPIOs in the chip. Drivers can exclude GPIOs by clearing bits from this
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mask. The mask must be filled in before gpiochip_irqchip_add() or
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gpiochip_irqchip_add_nested() is called.
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To use the helpers please keep the following in mind:
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- Make sure to assign all relevant members of the struct gpio_chip so that
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the irqchip can initialize. E.g. .dev and .can_sleep shall be set up
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properly.
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- Nominally set all handlers to handle_bad_irq() in the setup call and pass
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handle_bad_irq() as flow handler parameter in gpiochip_irqchip_add() if it is
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expected for GPIO driver that irqchip .set_type() callback have to be called
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before using/enabling GPIO IRQ. Then set the handler to handle_level_irq()
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and/or handle_edge_irq() in the irqchip .set_type() callback depending on
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what your controller supports.
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It is legal for any IRQ consumer to request an IRQ from any irqchip no matter
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if that is a combined GPIO+IRQ driver. The basic premise is that gpio_chip and
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irq_chip are orthogonal, and offering their services independent of each
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other.
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gpiod_to_irq() is just a convenience function to figure out the IRQ for a
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certain GPIO line and should not be relied upon to have been called before
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the IRQ is used.
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So always prepare the hardware and make it ready for action in respective
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callbacks from the GPIO and irqchip APIs. Do not rely on gpiod_to_irq() having
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been called first.
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This orthogonality leads to ambiguities that we need to solve: if there is
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competition inside the subsystem which side is using the resource (a certain
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GPIO line and register for example) it needs to deny certain operations and
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keep track of usage inside of the gpiolib subsystem. This is why the API
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below exists.
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Locking IRQ usage
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-----------------
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Input GPIOs can be used as IRQ signals. When this happens, a driver is requested
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to mark the GPIO as being used as an IRQ::
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int gpiochip_lock_as_irq(struct gpio_chip *chip, unsigned int offset)
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This will prevent the use of non-irq related GPIO APIs until the GPIO IRQ lock
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is released::
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void gpiochip_unlock_as_irq(struct gpio_chip *chip, unsigned int offset)
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When implementing an irqchip inside a GPIO driver, these two functions should
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typically be called in the .startup() and .shutdown() callbacks from the
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irqchip.
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When using the gpiolib irqchip helpers, these callbacks are automatically
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assigned.
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Disabling and enabling IRQs
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---------------------------
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When a GPIO is used as an IRQ signal, then gpiolib also needs to know if
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the IRQ is enabled or disabled. In order to inform gpiolib about this,
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a driver should call::
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void gpiochip_disable_irq(struct gpio_chip *chip, unsigned int offset)
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This allows drivers to drive the GPIO as an output while the IRQ is
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disabled. When the IRQ is enabled again, a driver should call::
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void gpiochip_enable_irq(struct gpio_chip *chip, unsigned int offset)
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When implementing an irqchip inside a GPIO driver, these two functions should
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typically be called in the .irq_disable() and .irq_enable() callbacks from the
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irqchip.
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When using the gpiolib irqchip helpers, these callbacks are automatically
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assigned.
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Real-Time compliance for GPIO IRQ chips
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---------------------------------------
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Any provider of irqchips needs to be carefully tailored to support Real Time
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preemption. It is desirable that all irqchips in the GPIO subsystem keep this
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in mind and do the proper testing to assure they are real time-enabled.
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So, pay attention on above " RT_FULL:" notes, please.
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The following is a checklist to follow when preparing a driver for real
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time-compliance:
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- ensure spinlock_t is not used as part irq_chip implementation;
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- ensure that sleepable APIs are not used as part irq_chip implementation.
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If sleepable APIs have to be used, these can be done from the .irq_bus_lock()
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and .irq_bus_unlock() callbacks;
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- Chained GPIO irqchips: ensure spinlock_t or any sleepable APIs are not used
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from chained IRQ handler;
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- Generic chained GPIO irqchips: take care about generic_handle_irq() calls and
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apply corresponding W/A;
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- Chained GPIO irqchips: get rid of chained IRQ handler and use generic irq
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handler if possible :)
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- regmap_mmio: Sry, but you are in trouble :( if MMIO regmap is used as for
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GPIO IRQ chip implementation;
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- Test your driver with the appropriate in-kernel real time test cases for both
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level and edge IRQs.
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Requesting self-owned GPIO pins
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-------------------------------
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Sometimes it is useful to allow a GPIO chip driver to request its own GPIO
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descriptors through the gpiolib API. Using gpio_request() for this purpose
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does not help since it pins the module to the kernel forever (it calls
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try_module_get()). A GPIO driver can use the following functions instead
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to request and free descriptors without being pinned to the kernel forever::
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struct gpio_desc *gpiochip_request_own_desc(struct gpio_desc *desc,
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const char *label)
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void gpiochip_free_own_desc(struct gpio_desc *desc)
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Descriptors requested with gpiochip_request_own_desc() must be released with
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gpiochip_free_own_desc().
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These functions must be used with care since they do not affect module use
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count. Do not use the functions to request gpio descriptors not owned by the
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calling driver.
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* [1] http://www.spinics.net/lists/linux-omap/msg120425.html
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* [2] https://lkml.org/lkml/2015/9/25/494
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* [3] https://lkml.org/lkml/2015/9/25/495
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