3 This provides an overview of GPIO access conventions on Linux.
5 These calls use the gpio_* naming prefix. No other calls should use that
6 prefix, or the related __gpio_* prefix.
11 A "General Purpose Input/Output" (GPIO) is a flexible software-controlled
12 digital signal. They are provided from many kinds of chip, and are familiar
13 to Linux developers working with embedded and custom hardware. Each GPIO
14 represents a bit connected to a particular pin, or "ball" on Ball Grid Array
15 (BGA) packages. Board schematics show which external hardware connects to
16 which GPIOs. Drivers can be written generically, so that board setup code
17 passes such pin configuration data to drivers.
19 System-on-Chip (SOC) processors heavily rely on GPIOs. In some cases, every
20 non-dedicated pin can be configured as a GPIO; and most chips have at least
21 several dozen of them. Programmable logic devices (like FPGAs) can easily
22 provide GPIOs; multifunction chips like power managers, and audio codecs
23 often have a few such pins to help with pin scarcity on SOCs; and there are
24 also "GPIO Expander" chips that connect using the I2C or SPI serial busses.
25 Most PC southbridges have a few dozen GPIO-capable pins (with only the BIOS
26 firmware knowing how they're used).
28 The exact capabilities of GPIOs vary between systems. Common options:
30 - Output values are writable (high=1, low=0). Some chips also have
31 options about how that value is driven, so that for example only one
32 value might be driven ... supporting "wire-OR" and similar schemes
33 for the other value (notably, "open drain" signaling).
35 - Input values are likewise readable (1, 0). Some chips support readback
36 of pins configured as "output", which is very useful in such "wire-OR"
37 cases (to support bidirectional signaling). GPIO controllers may have
38 input de-glitch/debounce logic, sometimes with software controls.
40 - Inputs can often be used as IRQ signals, often edge triggered but
41 sometimes level triggered. Such IRQs may be configurable as system
42 wakeup events, to wake the system from a low power state.
44 - Usually a GPIO will be configurable as either input or output, as needed
45 by different product boards; single direction ones exist too.
47 - Most GPIOs can be accessed while holding spinlocks, but those accessed
48 through a serial bus normally can't. Some systems support both types.
50 On a given board each GPIO is used for one specific purpose like monitoring
51 MMC/SD card insertion/removal, detecting card writeprotect status, driving
52 a LED, configuring a transceiver, bitbanging a serial bus, poking a hardware
53 watchdog, sensing a switch, and so on.
58 Note that this is called a "convention" because you don't need to do it this
59 way, and it's no crime if you don't. There **are** cases where portability
60 is not the main issue; GPIOs are often used for the kind of board-specific
61 glue logic that may even change between board revisions, and can't ever be
62 used on a board that's wired differently. Only least-common-denominator
63 functionality can be very portable. Other features are platform-specific,
64 and that can be critical for glue logic.
66 Plus, this doesn't require any implementation framework, just an interface.
67 One platform might implement it as simple inline functions accessing chip
68 registers; another might implement it by delegating through abstractions
69 used for several very different kinds of GPIO controller. (There is some
70 optional code supporting such an implementation strategy, described later
71 in this document, but drivers acting as clients to the GPIO interface must
72 not care how it's implemented.)
74 That said, if the convention is supported on their platform, drivers should
75 use it when possible. Platforms must declare GENERIC_GPIO support in their
76 Kconfig (boolean true), and provide an <asm/gpio.h> file. Drivers that can't
77 work without standard GPIO calls should have Kconfig entries which depend
78 on GENERIC_GPIO. The GPIO calls are available, either as "real code" or as
79 optimized-away stubs, when drivers use the include file:
81 #include <linux/gpio.h>
83 If you stick to this convention then it'll be easier for other developers to
84 see what your code is doing, and help maintain it.
86 Note that these operations include I/O barriers on platforms which need to
87 use them; drivers don't need to add them explicitly.
92 GPIOs are identified by unsigned integers in the range 0..MAX_INT. That
93 reserves "negative" numbers for other purposes like marking signals as
94 "not available on this board", or indicating faults. Code that doesn't
95 touch the underlying hardware treats these integers as opaque cookies.
97 Platforms define how they use those integers, and usually #define symbols
98 for the GPIO lines so that board-specific setup code directly corresponds
99 to the relevant schematics. In contrast, drivers should only use GPIO
100 numbers passed to them from that setup code, using platform_data to hold
101 board-specific pin configuration data (along with other board specific
102 data they need). That avoids portability problems.
104 So for example one platform uses numbers 32-159 for GPIOs; while another
105 uses numbers 0..63 with one set of GPIO controllers, 64-79 with another
106 type of GPIO controller, and on one particular board 80-95 with an FPGA.
107 The numbers need not be contiguous; either of those platforms could also
108 use numbers 2000-2063 to identify GPIOs in a bank of I2C GPIO expanders.
110 If you want to initialize a structure with an invalid GPIO number, use
111 some negative number (perhaps "-EINVAL"); that will never be valid. To
112 test if a number could reference a GPIO, you may use this predicate:
114 int gpio_is_valid(int number);
116 A number that's not valid will be rejected by calls which may request
117 or free GPIOs (see below). Other numbers may also be rejected; for
118 example, a number might be valid but unused on a given board.
120 Whether a platform supports multiple GPIO controllers is currently a
121 platform-specific implementation issue.
126 One of the first things to do with a GPIO, often in board setup code when
127 setting up a platform_device using the GPIO, is mark its direction:
129 /* set as input or output, returning 0 or negative errno */
130 int gpio_direction_input(unsigned gpio);
131 int gpio_direction_output(unsigned gpio, int value);
133 The return value is zero for success, else a negative errno. It should
134 be checked, since the get/set calls don't have error returns and since
135 misconfiguration is possible. You should normally issue these calls from
136 a task context. However, for spinlock-safe GPIOs it's OK to use them
137 before tasking is enabled, as part of early board setup.
139 For output GPIOs, the value provided becomes the initial output value.
140 This helps avoid signal glitching during system startup.
142 For compatibility with legacy interfaces to GPIOs, setting the direction
143 of a GPIO implicitly requests that GPIO (see below) if it has not been
144 requested already. That compatibility may be removed in the future;
145 explicitly requesting GPIOs is strongly preferred.
147 Setting the direction can fail if the GPIO number is invalid, or when
148 that particular GPIO can't be used in that mode. It's generally a bad
149 idea to rely on boot firmware to have set the direction correctly, since
150 it probably wasn't validated to do more than boot Linux. (Similarly,
151 that board setup code probably needs to multiplex that pin as a GPIO,
152 and configure pullups/pulldowns appropriately.)
155 Spinlock-Safe GPIO access
156 -------------------------
157 Most GPIO controllers can be accessed with memory read/write instructions.
158 That doesn't need to sleep, and can safely be done from inside IRQ handlers.
159 (That includes hardirq contexts on RT kernels.)
161 Use these calls to access such GPIOs:
163 /* GPIO INPUT: return zero or nonzero */
164 int gpio_get_value(unsigned gpio);
167 void gpio_set_value(unsigned gpio, int value);
169 The values are boolean, zero for low, nonzero for high. When reading the
170 value of an output pin, the value returned should be what's seen on the
171 pin ... that won't always match the specified output value, because of
172 issues including open-drain signaling and output latencies.
174 The get/set calls have no error returns because "invalid GPIO" should have
175 been reported earlier from gpio_direction_*(). However, note that not all
176 platforms can read the value of output pins; those that can't should always
177 return zero. Also, using these calls for GPIOs that can't safely be accessed
178 without sleeping (see below) is an error.
180 Platform-specific implementations are encouraged to optimize the two
181 calls to access the GPIO value in cases where the GPIO number (and for
182 output, value) are constant. It's normal for them to need only a couple
183 of instructions in such cases (reading or writing a hardware register),
184 and not to need spinlocks. Such optimized calls can make bitbanging
185 applications a lot more efficient (in both space and time) than spending
186 dozens of instructions on subroutine calls.
189 GPIO access that may sleep
190 --------------------------
191 Some GPIO controllers must be accessed using message based busses like I2C
192 or SPI. Commands to read or write those GPIO values require waiting to
193 get to the head of a queue to transmit a command and get its response.
194 This requires sleeping, which can't be done from inside IRQ handlers.
196 Platforms that support this type of GPIO distinguish them from other GPIOs
197 by returning nonzero from this call (which requires a valid GPIO number,
198 either explicitly or implicitly requested):
200 int gpio_cansleep(unsigned gpio);
202 To access such GPIOs, a different set of accessors is defined:
204 /* GPIO INPUT: return zero or nonzero, might sleep */
205 int gpio_get_value_cansleep(unsigned gpio);
207 /* GPIO OUTPUT, might sleep */
208 void gpio_set_value_cansleep(unsigned gpio, int value);
210 Other than the fact that these calls might sleep, and will not be ignored
211 for GPIOs that can't be accessed from IRQ handlers, these calls act the
212 same as the spinlock-safe calls.
215 Claiming and Releasing GPIOs (OPTIONAL)
216 ---------------------------------------
217 To help catch system configuration errors, two calls are defined.
218 However, many platforms don't currently support this mechanism.
220 /* request GPIO, returning 0 or negative errno.
221 * non-null labels may be useful for diagnostics.
223 int gpio_request(unsigned gpio, const char *label);
225 /* release previously-claimed GPIO */
226 void gpio_free(unsigned gpio);
228 Passing invalid GPIO numbers to gpio_request() will fail, as will requesting
229 GPIOs that have already been claimed with that call. The return value of
230 gpio_request() must be checked. You should normally issue these calls from
231 a task context. However, for spinlock-safe GPIOs it's OK to request GPIOs
232 before tasking is enabled, as part of early board setup.
234 These calls serve two basic purposes. One is marking the signals which
235 are actually in use as GPIOs, for better diagnostics; systems may have
236 several hundred potential GPIOs, but often only a dozen are used on any
237 given board. Another is to catch conflicts, identifying errors when
238 (a) two or more drivers wrongly think they have exclusive use of that
239 signal, or (b) something wrongly believes it's safe to remove drivers
240 needed to manage a signal that's in active use. That is, requesting a
241 GPIO can serve as a kind of lock.
243 These two calls are optional because not not all current Linux platforms
244 offer such functionality in their GPIO support; a valid implementation
245 could return success for all gpio_request() calls. Unlike the other calls,
246 the state they represent doesn't normally match anything from a hardware
247 register; it's just a software bitmap which clearly is not necessary for
248 correct operation of hardware or (bug free) drivers.
250 Note that requesting a GPIO does NOT cause it to be configured in any
251 way; it just marks that GPIO as in use. Separate code must handle any
252 pin setup (e.g. controlling which pin the GPIO uses, pullup/pulldown).
254 Also note that it's your responsibility to have stopped using a GPIO
260 GPIO numbers are unsigned integers; so are IRQ numbers. These make up
261 two logically distinct namespaces (GPIO 0 need not use IRQ 0). You can
262 map between them using calls like:
264 /* map GPIO numbers to IRQ numbers */
265 int gpio_to_irq(unsigned gpio);
267 /* map IRQ numbers to GPIO numbers */
268 int irq_to_gpio(unsigned irq);
270 Those return either the corresponding number in the other namespace, or
271 else a negative errno code if the mapping can't be done. (For example,
272 some GPIOs can't be used as IRQs.) It is an unchecked error to use a GPIO
273 number that wasn't set up as an input using gpio_direction_input(), or
274 to use an IRQ number that didn't originally come from gpio_to_irq().
276 These two mapping calls are expected to cost on the order of a single
277 addition or subtraction. They're not allowed to sleep.
279 Non-error values returned from gpio_to_irq() can be passed to request_irq()
280 or free_irq(). They will often be stored into IRQ resources for platform
281 devices, by the board-specific initialization code. Note that IRQ trigger
282 options are part of the IRQ interface, e.g. IRQF_TRIGGER_FALLING, as are
283 system wakeup capabilities.
285 Non-error values returned from irq_to_gpio() would most commonly be used
286 with gpio_get_value(), for example to initialize or update driver state
287 when the IRQ is edge-triggered.
290 Emulating Open Drain Signals
291 ----------------------------
292 Sometimes shared signals need to use "open drain" signaling, where only the
293 low signal level is actually driven. (That term applies to CMOS transistors;
294 "open collector" is used for TTL.) A pullup resistor causes the high signal
295 level. This is sometimes called a "wire-AND"; or more practically, from the
296 negative logic (low=true) perspective this is a "wire-OR".
298 One common example of an open drain signal is a shared active-low IRQ line.
299 Also, bidirectional data bus signals sometimes use open drain signals.
301 Some GPIO controllers directly support open drain outputs; many don't. When
302 you need open drain signaling but your hardware doesn't directly support it,
303 there's a common idiom you can use to emulate it with any GPIO pin that can
304 be used as either an input or an output:
306 LOW: gpio_direction_output(gpio, 0) ... this drives the signal
307 and overrides the pullup.
309 HIGH: gpio_direction_input(gpio) ... this turns off the output,
310 so the pullup (or some other device) controls the signal.
312 If you are "driving" the signal high but gpio_get_value(gpio) reports a low
313 value (after the appropriate rise time passes), you know some other component
314 is driving the shared signal low. That's not necessarily an error. As one
315 common example, that's how I2C clocks are stretched: a slave that needs a
316 slower clock delays the rising edge of SCK, and the I2C master adjusts its
317 signaling rate accordingly.
320 What do these conventions omit?
321 ===============================
322 One of the biggest things these conventions omit is pin multiplexing, since
323 this is highly chip-specific and nonportable. One platform might not need
324 explicit multiplexing; another might have just two options for use of any
325 given pin; another might have eight options per pin; another might be able
326 to route a given GPIO to any one of several pins. (Yes, those examples all
327 come from systems that run Linux today.)
329 Related to multiplexing is configuration and enabling of the pullups or
330 pulldowns integrated on some platforms. Not all platforms support them,
331 or support them in the same way; and any given board might use external
332 pullups (or pulldowns) so that the on-chip ones should not be used.
333 (When a circuit needs 5 kOhm, on-chip 100 kOhm resistors won't do.)
334 Likewise drive strength (2 mA vs 20 mA) and voltage (1.8V vs 3.3V) is a
335 platform-specific issue, as are models like (not) having a one-to-one
336 correspondence between configurable pins and GPIOs.
338 There are other system-specific mechanisms that are not specified here,
339 like the aforementioned options for input de-glitching and wire-OR output.
340 Hardware may support reading or writing GPIOs in gangs, but that's usually
341 configuration dependent: for GPIOs sharing the same bank. (GPIOs are
342 commonly grouped in banks of 16 or 32, with a given SOC having several such
343 banks.) Some systems can trigger IRQs from output GPIOs, or read values
344 from pins not managed as GPIOs. Code relying on such mechanisms will
345 necessarily be nonportable.
347 Dynamic definition of GPIOs is not currently standard; for example, as
348 a side effect of configuring an add-on board with some GPIO expanders.
350 These calls are purely for kernel space, but a userspace API could be built
354 GPIO implementor's framework (OPTIONAL)
355 =======================================
356 As noted earlier, there is an optional implementation framework making it
357 easier for platforms to support different kinds of GPIO controller using
358 the same programming interface.
360 As a debugging aid, if debugfs is available a /sys/kernel/debug/gpio file
361 will be found there. That will list all the controllers registered through
362 this framework, and the state of the GPIOs currently in use.
365 Controller Drivers: gpio_chip
366 -----------------------------
367 In this framework each GPIO controller is packaged as a "struct gpio_chip"
368 with information common to each controller of that type:
370 - methods to establish GPIO direction
371 - methods used to access GPIO values
372 - flag saying whether calls to its methods may sleep
373 - optional debugfs dump method (showing extra state like pullup config)
374 - label for diagnostics
376 There is also per-instance data, which may come from device.platform_data:
377 the number of its first GPIO, and how many GPIOs it exposes.
379 The code implementing a gpio_chip should support multiple instances of the
380 controller, possibly using the driver model. That code will configure each
381 gpio_chip and issue gpiochip_add(). Removing a GPIO controller should be
382 rare; use gpiochip_remove() when it is unavoidable.
384 Most often a gpio_chip is part of an instance-specific structure with state
385 not exposed by the GPIO interfaces, such as addressing, power management,
386 and more. Chips such as codecs will have complex non-GPIO state,
388 Any debugfs dump method should normally ignore signals which haven't been
389 requested as GPIOs. They can use gpiochip_is_requested(), which returns
390 either NULL or the label associated with that GPIO when it was requested.
395 To support this framework, a platform's Kconfig will "select HAVE_GPIO_LIB"
396 and arrange that its <asm/gpio.h> includes <asm-generic/gpio.h> and defines
397 three functions: gpio_get_value(), gpio_set_value(), and gpio_cansleep().
398 They may also want to provide a custom value for ARCH_NR_GPIOS.
400 Trivial implementations of those functions can directly use framework
401 code, which always dispatches through the gpio_chip:
403 #define gpio_get_value __gpio_get_value
404 #define gpio_set_value __gpio_set_value
405 #define gpio_cansleep __gpio_cansleep
407 Fancier implementations could instead define those as inline functions with
408 logic optimizing access to specific SOC-based GPIOs. For example, if the
409 referenced GPIO is the constant "12", getting or setting its value could
410 cost as little as two or three instructions, never sleeping. When such an
411 optimization is not possible those calls must delegate to the framework
412 code, costing at least a few dozen instructions. For bitbanged I/O, such
413 instruction savings can be significant.
415 For SOCs, platform-specific code defines and registers gpio_chip instances
416 for each bank of on-chip GPIOs. Those GPIOs should be numbered/labeled to
417 match chip vendor documentation, and directly match board schematics. They
418 may well start at zero and go up to a platform-specific limit. Such GPIOs
419 are normally integrated into platform initialization to make them always be
420 available, from arch_initcall() or earlier; they can often serve as IRQs.
425 For external GPIO controllers -- such as I2C or SPI expanders, ASICs, multi
426 function devices, FPGAs or CPLDs -- most often board-specific code handles
427 registering controller devices and ensures that their drivers know what GPIO
428 numbers to use with gpiochip_add(). Their numbers often start right after
429 platform-specific GPIOs.
431 For example, board setup code could create structures identifying the range
432 of GPIOs that chip will expose, and passes them to each GPIO expander chip
433 using platform_data. Then the chip driver's probe() routine could pass that
434 data to gpiochip_add().
436 Initialization order can be important. For example, when a device relies on
437 an I2C-based GPIO, its probe() routine should only be called after that GPIO
438 becomes available. That may mean the device should not be registered until
439 calls for that GPIO can work. One way to address such dependencies is for
440 such gpio_chip controllers to provide setup() and teardown() callbacks to
441 board specific code; those board specific callbacks would register devices
442 once all the necessary resources are available.