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.. SPDX-License-Identifier: GPL-2.0-only
GPIO Testing Driver
===================
.. note::
This module has been obsoleted by the more flexible gpio-sim.rst.
New developments should use that API and existing developments are
encouraged to migrate as soon as possible.
This module will continue to be maintained but no new features will be
added.
The GPIO Testing Driver (gpio-mockup) provides a way to create simulated GPIO
chips for testing purposes. The lines exposed by these chips can be accessed
using the standard GPIO character device interface as well as manipulated
using the dedicated debugfs directory structure.
Creating simulated chips using module params
--------------------------------------------
When loading the gpio-mockup driver a number of parameters can be passed to the
module.
gpio_mockup_ranges
This parameter takes an argument in the form of an array of integer
pairs. Each pair defines the base GPIO number (non-negative integer)
and the first number after the last of this chip. If the base GPIO
is -1, the gpiolib will assign it automatically. while the following
parameter is the number of lines exposed by the chip.
Example: gpio_mockup_ranges=-1,8,-1,16,405,409
The line above creates three chips. The first one will expose 8 lines,
the second 16 and the third 4. The base GPIO for the third chip is set
to 405 while for two first chips it will be assigned automatically.
gpio_mockup_named_lines
This parameter doesn't take any arguments. It lets the driver know that
GPIO lines exposed by it should be named.
The name format is: gpio-mockup-X-Y where X is mockup chip's ID
and Y is the line offset.
Manipulating simulated lines
----------------------------
Each mockup chip creates its own subdirectory in /sys/kernel/debug/gpio-mockup/.
The directory is named after the chip's label. A symlink is also created, named
after the chip's name, which points to the label directory.
Inside each subdirectory, there's a separate attribute for each GPIO line. The
name of the attribute represents the line's offset in the chip.
Reading from a line attribute returns the current value. Writing to it (0 or 1)
changes the configuration of the simulated pull-up/pull-down resistor
(1 - pull-up, 0 - pull-down).
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