upstream u-boot with additional patches for our devices/boards: https://lists.denx.de/pipermail/u-boot/2017-March/282789.html (AXP crashes) ; Gbit ethernet patch for some LIME2 revisions ; with SPI flash support
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u-boot/doc/driver-model/UDM-gpio.txt

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The U-Boot Driver Model Project
===============================
GPIO analysis
=============
Viktor Krivak <viktor.krivak@gmail.com>
2012-02-24
I) Overview
-----------
At this moment U-Boot provides standard API that consists of 7 functions.
int gpio_request(unsigned gpio, const char *label)
int gpio_free(unsigned gpio)
int gpio_direction_input(unsigned gpio)
int gpio_direction_output(unsigned gpio, int value)
int gpio_get_value(unsigned gpio)
void gpio_set_value(unsigned gpio, int value)
Methods "gpio_request()" and "gpio_free()" are used for claiming and releasing
GPIOs. First one should check if the desired pin exists and if the pin wasn't
requested already elsewhere. The method also has a label argument that can be
used for debug purposes. The label argument should be copied into the internal
memory, but only if the DEBUG macro is set. The "gpio_free()" is the exact
opposite. It releases the particular pin. Other methods are used for setting
input or output direction and obtaining or setting values of the pins.
II) Approach
------------
1) Request and free GPIO
------------------------
The "gpio_request()" implementation is basically the same for all boards.
The function checks if the particular GPIO is correct and checks if the
GPIO pin is still free. If the conditions are met, the method marks the
GPIO claimed in it's internal structure. If macro DEBUG is defined, the
function also copies the label argument to the structure. If the pin is
already locked, the function returns -1 and if DEBUG is defined, certain
debug output is generated, including the contents of the label argument.
The "gpio_free()" function releases the lock and eventually deallocates
data used by the copied label argument.
2) Internal data
----------------
Internal data are driver specific. They have to contain some mechanism to
realise the locking though. This can be done for example using a bit field.
3) Operations provided by the driver
------------------------------------
The driver operations basically meet API that is already defined and used.
Except for "gpio_request()" and "gpio_free()", all methods can be converted in
a simple manner. The driver provides the following structure:
struct gpio_driver_ops {
int (*gpio_request)(struct instance *i, unsigned gpio,
const char *label);
int (*gpio_free)(struct instance *i, unsigned gpio);
int (*gpio_direction_input)(struct instance *i, unsigned gpio);
int (*gpio_direction_output)(struct instance *i, unsigned gpio,
int value);
int (*gpio_get_value)(struct instance *i, unsigned gpio);
void (*gpio_set_value)(struct instance *i, unsigned gpio, int value);
}
III) Analysis of in-tree drivers
--------------------------------
1) altera_pio.c
---------------
Meets standard API. Implements gpio_request() properly. Simple conversion
possible.
2) at91_gpio.c
--------------
Don't meet standard API. Need some other methods to implement.
3) da8xx_gpio.c
---------------
Meets standard API. Implements gpio_request() properly. Simple conversion
possible.
4) kw_gpio.c
------------
Doesn't meet standard API. Needs some other methods to implement and move some
methods to another file.
5) mpc83xx_gpio.c
-----------------
Meets standard API. Doesn't implement gpio_request() properly (only checks
if the pin is valid). Simple conversion possible.
6) mvgpio.c
-----------
Meets standard API. Doesn't implement gpio_request() properly (only checks
if the pin is valid). Simple conversion possible.
7) mvgpio.h
-----------
Wrong placement. Will be moved to another location.
8) mvmfp.c
----------
Wrong placement. Will be moved to another location.