1 Overview of Linux kernel SPI support
2 ====================================
8 The "Serial Peripheral Interface" (SPI) is a synchronous four wire serial
9 link used to connect microcontrollers to sensors, memory, and peripherals.
10 It's a simple "de facto" standard, not complicated enough to acquire a
11 standardization body. SPI uses a master/slave configuration.
13 The three signal wires hold a clock (SCK, often on the order of 10 MHz),
14 and parallel data lines with "Master Out, Slave In" (MOSI) or "Master In,
15 Slave Out" (MISO) signals. (Other names are also used.) There are four
16 clocking modes through which data is exchanged; mode-0 and mode-3 are most
17 commonly used. Each clock cycle shifts data out and data in; the clock
18 doesn't cycle except when there is a data bit to shift. Not all data bits
19 are used though; not every protocol uses those full duplex capabilities.
21 SPI masters use a fourth "chip select" line to activate a given SPI slave
22 device, so those three signal wires may be connected to several chips
23 in parallel. All SPI slaves support chipselects; they are usually active
24 low signals, labeled nCSx for slave 'x' (e.g. nCS0). Some devices have
25 other signals, often including an interrupt to the master.
27 Unlike serial busses like USB or SMBus, even low level protocols for
28 SPI slave functions are usually not interoperable between vendors
29 (except for commodities like SPI memory chips).
31 - SPI may be used for request/response style device protocols, as with
32 touchscreen sensors and memory chips.
34 - It may also be used to stream data in either direction (half duplex),
35 or both of them at the same time (full duplex).
37 - Some devices may use eight bit words. Others may use different word
38 lengths, such as streams of 12-bit or 20-bit digital samples.
40 - Words are usually sent with their most significant bit (MSB) first,
41 but sometimes the least significant bit (LSB) goes first instead.
43 - Sometimes SPI is used to daisy-chain devices, like shift registers.
45 In the same way, SPI slaves will only rarely support any kind of automatic
46 discovery/enumeration protocol. The tree of slave devices accessible from
47 a given SPI master will normally be set up manually, with configuration
50 SPI is only one of the names used by such four-wire protocols, and
51 most controllers have no problem handling "MicroWire" (think of it as
52 half-duplex SPI, for request/response protocols), SSP ("Synchronous
53 Serial Protocol"), PSP ("Programmable Serial Protocol"), and other
56 Some chips eliminate a signal line by combining MOSI and MISO, and
57 limiting themselves to half-duplex at the hardware level. In fact
58 some SPI chips have this signal mode as a strapping option. These
59 can be accessed using the same programming interface as SPI, but of
60 course they won't handle full duplex transfers. You may find such
61 chips described as using "three wire" signaling: SCK, data, nCSx.
62 (That data line is sometimes called MOMI or SISO.)
64 Microcontrollers often support both master and slave sides of the SPI
65 protocol. This document (and Linux) supports both the master and slave
66 sides of SPI interactions.
69 Who uses it? On what kinds of systems?
70 ---------------------------------------
71 Linux developers using SPI are probably writing device drivers for embedded
72 systems boards. SPI is used to control external chips, and it is also a
73 protocol supported by every MMC or SD memory card. (The older "DataFlash"
74 cards, predating MMC cards but using the same connectors and card shape,
75 support only SPI.) Some PC hardware uses SPI flash for BIOS code.
77 SPI slave chips range from digital/analog converters used for analog
78 sensors and codecs, to memory, to peripherals like USB controllers
79 or Ethernet adapters; and more.
81 Most systems using SPI will integrate a few devices on a mainboard.
82 Some provide SPI links on expansion connectors; in cases where no
83 dedicated SPI controller exists, GPIO pins can be used to create a
84 low speed "bitbanging" adapter. Very few systems will "hotplug" an SPI
85 controller; the reasons to use SPI focus on low cost and simple operation,
86 and if dynamic reconfiguration is important, USB will often be a more
87 appropriate low-pincount peripheral bus.
89 Many microcontrollers that can run Linux integrate one or more I/O
90 interfaces with SPI modes. Given SPI support, they could use MMC or SD
91 cards without needing a special purpose MMC/SD/SDIO controller.
94 I'm confused. What are these four SPI "clock modes"?
95 -----------------------------------------------------
96 It's easy to be confused here, and the vendor documentation you'll
97 find isn't necessarily helpful. The four modes combine two mode bits:
99 - CPOL indicates the initial clock polarity. CPOL=0 means the
100 clock starts low, so the first (leading) edge is rising, and
101 the second (trailing) edge is falling. CPOL=1 means the clock
102 starts high, so the first (leading) edge is falling.
104 - CPHA indicates the clock phase used to sample data; CPHA=0 says
105 sample on the leading edge, CPHA=1 means the trailing edge.
107 Since the signal needs to stablize before it's sampled, CPHA=0
108 implies that its data is written half a clock before the first
109 clock edge. The chipselect may have made it become available.
111 Chip specs won't always say "uses SPI mode X" in as many words,
112 but their timing diagrams will make the CPOL and CPHA modes clear.
114 In the SPI mode number, CPOL is the high order bit and CPHA is the
115 low order bit. So when a chip's timing diagram shows the clock
116 starting low (CPOL=0) and data stabilized for sampling during the
117 trailing clock edge (CPHA=1), that's SPI mode 1.
119 Note that the clock mode is relevant as soon as the chipselect goes
120 active. So the master must set the clock to inactive before selecting
121 a slave, and the slave can tell the chosen polarity by sampling the
122 clock level when its select line goes active. That's why many devices
123 support for example both modes 0 and 3: they don't care about polarity,
124 and always clock data in/out on rising clock edges.
127 How do these driver programming interfaces work?
128 ------------------------------------------------
129 The <linux/spi/spi.h> header file includes kerneldoc, as does the
130 main source code, and you should certainly read that chapter of the
131 kernel API document. This is just an overview, so you get the big
132 picture before those details.
134 SPI requests always go into I/O queues. Requests for a given SPI device
135 are always executed in FIFO order, and complete asynchronously through
136 completion callbacks. There are also some simple synchronous wrappers
137 for those calls, including ones for common transaction types like writing
138 a command and then reading its response.
140 There are two types of SPI driver, here called:
142 Controller drivers ... controllers may be built into System-On-Chip
143 processors, and often support both Master and Slave roles.
144 These drivers touch hardware registers and may use DMA.
145 Or they can be PIO bitbangers, needing just GPIO pins.
147 Protocol drivers ... these pass messages through the controller
148 driver to communicate with a Slave or Master device on the
149 other side of an SPI link.
151 So for example one protocol driver might talk to the MTD layer to export
152 data to filesystems stored on SPI flash like DataFlash; and others might
153 control audio interfaces, present touchscreen sensors as input interfaces,
154 or monitor temperature and voltage levels during industrial processing.
155 And those might all be sharing the same controller driver.
157 A "struct spi_device" encapsulates the controller-side interface between
158 those two types of drivers.
160 There is a minimal core of SPI programming interfaces, focussing on
161 using the driver model to connect controller and protocol drivers using
162 device tables provided by board specific initialization code. SPI
163 shows up in sysfs in several locations:
165 /sys/devices/.../CTLR ... physical node for a given SPI controller
167 /sys/devices/.../CTLR/spiB.C ... spi_device on bus "B",
168 chipselect C, accessed through CTLR.
170 /sys/bus/spi/devices/spiB.C ... symlink to that physical
171 .../CTLR/spiB.C device
173 /sys/devices/.../CTLR/spiB.C/modalias ... identifies the driver
174 that should be used with this device (for hotplug/coldplug)
176 /sys/bus/spi/drivers/D ... driver for one or more spi*.* devices
178 /sys/class/spi_master/spiB ... symlink (or actual device node) to
179 a logical node which could hold class related state for the SPI
180 master controller managing bus "B". All spiB.* devices share one
181 physical SPI bus segment, with SCLK, MOSI, and MISO.
183 /sys/devices/.../CTLR/slave ... virtual file for (un)registering the
184 slave device for an SPI slave controller.
185 Writing the driver name of an SPI slave handler to this file
186 registers the slave device; writing "(null)" unregisters the slave
188 Reading from this file shows the name of the slave device ("(null)"
191 /sys/class/spi_slave/spiB ... symlink (or actual device node) to
192 a logical node which could hold class related state for the SPI
193 slave controller on bus "B". When registered, a single spiB.*
194 device is present here, possible sharing the physical SPI bus
195 segment with other SPI slave devices.
197 Note that the actual location of the controller's class state depends
198 on whether you enabled CONFIG_SYSFS_DEPRECATED or not. At this time,
199 the only class-specific state is the bus number ("B" in "spiB"), so
200 those /sys/class entries are only useful to quickly identify busses.
203 How does board-specific init code declare SPI devices?
204 ------------------------------------------------------
205 Linux needs several kinds of information to properly configure SPI devices.
206 That information is normally provided by board-specific code, even for
207 chips that do support some of automated discovery/enumeration.
211 The first kind of information is a list of what SPI controllers exist.
212 For System-on-Chip (SOC) based boards, these will usually be platform
213 devices, and the controller may need some platform_data in order to
214 operate properly. The "struct platform_device" will include resources
215 like the physical address of the controller's first register and its IRQ.
217 Platforms will often abstract the "register SPI controller" operation,
218 maybe coupling it with code to initialize pin configurations, so that
219 the arch/.../mach-*/board-*.c files for several boards can all share the
220 same basic controller setup code. This is because most SOCs have several
221 SPI-capable controllers, and only the ones actually usable on a given
222 board should normally be set up and registered.
224 So for example arch/.../mach-*/board-*.c files might have code like:
226 #include <mach/spi.h> /* for mysoc_spi_data */
228 /* if your mach-* infrastructure doesn't support kernels that can
229 * run on multiple boards, pdata wouldn't benefit from "__init".
231 static struct mysoc_spi_data pdata __initdata = { ... };
233 static __init board_init(void)
236 /* this board only uses SPI controller #2 */
237 mysoc_register_spi(2, &pdata);
241 And SOC-specific utility code might look something like:
243 #include <mach/spi.h>
245 static struct platform_device spi2 = { ... };
247 void mysoc_register_spi(unsigned n, struct mysoc_spi_data *pdata)
249 struct mysoc_spi_data *pdata2;
251 pdata2 = kmalloc(sizeof *pdata2, GFP_KERNEL);
255 spi2->dev.platform_data = pdata2;
256 register_platform_device(&spi2);
258 /* also: set up pin modes so the spi2 signals are
259 * visible on the relevant pins ... bootloaders on
260 * production boards may already have done this, but
261 * developer boards will often need Linux to do it.
267 Notice how the platform_data for boards may be different, even if the
268 same SOC controller is used. For example, on one board SPI might use
269 an external clock, where another derives the SPI clock from current
270 settings of some master clock.
273 DECLARE SLAVE DEVICES
275 The second kind of information is a list of what SPI slave devices exist
276 on the target board, often with some board-specific data needed for the
277 driver to work correctly.
279 Normally your arch/.../mach-*/board-*.c files would provide a small table
280 listing the SPI devices on each board. (This would typically be only a
281 small handful.) That might look like:
283 static struct ads7846_platform_data ads_info = {
284 .vref_delay_usecs = 100,
289 static struct spi_board_info spi_board_info[] __initdata = {
291 .modalias = "ads7846",
292 .platform_data = &ads_info,
295 .max_speed_hz = 120000 /* max sample rate at 3V */ * 16,
301 Again, notice how board-specific information is provided; each chip may need
302 several types. This example shows generic constraints like the fastest SPI
303 clock to allow (a function of board voltage in this case) or how an IRQ pin
304 is wired, plus chip-specific constraints like an important delay that's
305 changed by the capacitance at one pin.
307 (There's also "controller_data", information that may be useful to the
308 controller driver. An example would be peripheral-specific DMA tuning
309 data or chipselect callbacks. This is stored in spi_device later.)
311 The board_info should provide enough information to let the system work
312 without the chip's driver being loaded. The most troublesome aspect of
313 that is likely the SPI_CS_HIGH bit in the spi_device.mode field, since
314 sharing a bus with a device that interprets chipselect "backwards" is
315 not possible until the infrastructure knows how to deselect it.
317 Then your board initialization code would register that table with the SPI
318 infrastructure, so that it's available later when the SPI master controller
319 driver is registered:
321 spi_register_board_info(spi_board_info, ARRAY_SIZE(spi_board_info));
323 Like with other static board-specific setup, you won't unregister those.
325 The widely used "card" style computers bundle memory, cpu, and little else
326 onto a card that's maybe just thirty square centimeters. On such systems,
327 your arch/.../mach-.../board-*.c file would primarily provide information
328 about the devices on the mainboard into which such a card is plugged. That
329 certainly includes SPI devices hooked up through the card connectors!
332 NON-STATIC CONFIGURATIONS
334 Developer boards often play by different rules than product boards, and one
335 example is the potential need to hotplug SPI devices and/or controllers.
337 For those cases you might need to use spi_busnum_to_master() to look
338 up the spi bus master, and will likely need spi_new_device() to provide the
339 board info based on the board that was hotplugged. Of course, you'd later
340 call at least spi_unregister_device() when that board is removed.
342 When Linux includes support for MMC/SD/SDIO/DataFlash cards through SPI, those
343 configurations will also be dynamic. Fortunately, such devices all support
344 basic device identification probes, so they should hotplug normally.
347 How do I write an "SPI Protocol Driver"?
348 ----------------------------------------
349 Most SPI drivers are currently kernel drivers, but there's also support
350 for userspace drivers. Here we talk only about kernel drivers.
352 SPI protocol drivers somewhat resemble platform device drivers:
354 static struct spi_driver CHIP_driver = {
357 .owner = THIS_MODULE,
362 .remove = CHIP_remove,
365 The driver core will automatically attempt to bind this driver to any SPI
366 device whose board_info gave a modalias of "CHIP". Your probe() code
367 might look like this unless you're creating a device which is managing
368 a bus (appearing under /sys/class/spi_master).
370 static int CHIP_probe(struct spi_device *spi)
373 struct CHIP_platform_data *pdata;
375 /* assuming the driver requires board-specific data: */
376 pdata = &spi->dev.platform_data;
380 /* get memory for driver's per-chip state */
381 chip = kzalloc(sizeof *chip, GFP_KERNEL);
384 spi_set_drvdata(spi, chip);
390 As soon as it enters probe(), the driver may issue I/O requests to
391 the SPI device using "struct spi_message". When remove() returns,
392 or after probe() fails, the driver guarantees that it won't submit
393 any more such messages.
395 - An spi_message is a sequence of protocol operations, executed
396 as one atomic sequence. SPI driver controls include:
398 + when bidirectional reads and writes start ... by how its
399 sequence of spi_transfer requests is arranged;
401 + which I/O buffers are used ... each spi_transfer wraps a
402 buffer for each transfer direction, supporting full duplex
403 (two pointers, maybe the same one in both cases) and half
404 duplex (one pointer is NULL) transfers;
406 + optionally defining short delays after transfers ... using
407 the spi_transfer.delay_usecs setting (this delay can be the
408 only protocol effect, if the buffer length is zero);
410 + whether the chipselect becomes inactive after a transfer and
411 any delay ... by using the spi_transfer.cs_change flag;
413 + hinting whether the next message is likely to go to this same
414 device ... using the spi_transfer.cs_change flag on the last
415 transfer in that atomic group, and potentially saving costs
416 for chip deselect and select operations.
418 - Follow standard kernel rules, and provide DMA-safe buffers in
419 your messages. That way controller drivers using DMA aren't forced
420 to make extra copies unless the hardware requires it (e.g. working
421 around hardware errata that force the use of bounce buffering).
423 If standard dma_map_single() handling of these buffers is inappropriate,
424 you can use spi_message.is_dma_mapped to tell the controller driver
425 that you've already provided the relevant DMA addresses.
427 - The basic I/O primitive is spi_async(). Async requests may be
428 issued in any context (irq handler, task, etc) and completion
429 is reported using a callback provided with the message.
430 After any detected error, the chip is deselected and processing
431 of that spi_message is aborted.
433 - There are also synchronous wrappers like spi_sync(), and wrappers
434 like spi_read(), spi_write(), and spi_write_then_read(). These
435 may be issued only in contexts that may sleep, and they're all
436 clean (and small, and "optional") layers over spi_async().
438 - The spi_write_then_read() call, and convenience wrappers around
439 it, should only be used with small amounts of data where the
440 cost of an extra copy may be ignored. It's designed to support
441 common RPC-style requests, such as writing an eight bit command
442 and reading a sixteen bit response -- spi_w8r16() being one its
443 wrappers, doing exactly that.
445 Some drivers may need to modify spi_device characteristics like the
446 transfer mode, wordsize, or clock rate. This is done with spi_setup(),
447 which would normally be called from probe() before the first I/O is
448 done to the device. However, that can also be called at any time
449 that no message is pending for that device.
451 While "spi_device" would be the bottom boundary of the driver, the
452 upper boundaries might include sysfs (especially for sensor readings),
453 the input layer, ALSA, networking, MTD, the character device framework,
454 or other Linux subsystems.
456 Note that there are two types of memory your driver must manage as part
457 of interacting with SPI devices.
459 - I/O buffers use the usual Linux rules, and must be DMA-safe.
460 You'd normally allocate them from the heap or free page pool.
461 Don't use the stack, or anything that's declared "static".
463 - The spi_message and spi_transfer metadata used to glue those
464 I/O buffers into a group of protocol transactions. These can
465 be allocated anywhere it's convenient, including as part of
466 other allocate-once driver data structures. Zero-init these.
468 If you like, spi_message_alloc() and spi_message_free() convenience
469 routines are available to allocate and zero-initialize an spi_message
470 with several transfers.
473 How do I write an "SPI Master Controller Driver"?
474 -------------------------------------------------
475 An SPI controller will probably be registered on the platform_bus; write
476 a driver to bind to the device, whichever bus is involved.
478 The main task of this type of driver is to provide an "spi_master".
479 Use spi_alloc_master() to allocate the master, and spi_master_get_devdata()
480 to get the driver-private data allocated for that device.
482 struct spi_master *master;
483 struct CONTROLLER *c;
485 master = spi_alloc_master(dev, sizeof *c);
489 c = spi_master_get_devdata(master);
491 The driver will initialize the fields of that spi_master, including the
492 bus number (maybe the same as the platform device ID) and three methods
493 used to interact with the SPI core and SPI protocol drivers. It will
494 also initialize its own internal state. (See below about bus numbering
497 After you initialize the spi_master, then use spi_register_master() to
498 publish it to the rest of the system. At that time, device nodes for the
499 controller and any predeclared spi devices will be made available, and
500 the driver model core will take care of binding them to drivers.
502 If you need to remove your SPI controller driver, spi_unregister_master()
503 will reverse the effect of spi_register_master().
508 Bus numbering is important, since that's how Linux identifies a given
509 SPI bus (shared SCK, MOSI, MISO). Valid bus numbers start at zero. On
510 SOC systems, the bus numbers should match the numbers defined by the chip
511 manufacturer. For example, hardware controller SPI2 would be bus number 2,
512 and spi_board_info for devices connected to it would use that number.
514 If you don't have such hardware-assigned bus number, and for some reason
515 you can't just assign them, then provide a negative bus number. That will
516 then be replaced by a dynamically assigned number. You'd then need to treat
517 this as a non-static configuration (see above).
522 master->setup(struct spi_device *spi)
523 This sets up the device clock rate, SPI mode, and word sizes.
524 Drivers may change the defaults provided by board_info, and then
525 call spi_setup(spi) to invoke this routine. It may sleep.
527 Unless each SPI slave has its own configuration registers, don't
528 change them right away ... otherwise drivers could corrupt I/O
529 that's in progress for other SPI devices.
531 ** BUG ALERT: for some reason the first version of
532 ** many spi_master drivers seems to get this wrong.
533 ** When you code setup(), ASSUME that the controller
534 ** is actively processing transfers for another device.
536 master->cleanup(struct spi_device *spi)
537 Your controller driver may use spi_device.controller_state to hold
538 state it dynamically associates with that device. If you do that,
539 be sure to provide the cleanup() method to free that state.
541 master->prepare_transfer_hardware(struct spi_master *master)
542 This will be called by the queue mechanism to signal to the driver
543 that a message is coming in soon, so the subsystem requests the
544 driver to prepare the transfer hardware by issuing this call.
547 master->unprepare_transfer_hardware(struct spi_master *master)
548 This will be called by the queue mechanism to signal to the driver
549 that there are no more messages pending in the queue and it may
550 relax the hardware (e.g. by power management calls). This may sleep.
552 master->transfer_one_message(struct spi_master *master,
553 struct spi_message *mesg)
554 The subsystem calls the driver to transfer a single message while
555 queuing transfers that arrive in the meantime. When the driver is
556 finished with this message, it must call
557 spi_finalize_current_message() so the subsystem can issue the next
558 message. This may sleep.
560 master->transfer_one(struct spi_master *master, struct spi_device *spi,
561 struct spi_transfer *transfer)
562 The subsystem calls the driver to transfer a single transfer while
563 queuing transfers that arrive in the meantime. When the driver is
564 finished with this transfer, it must call
565 spi_finalize_current_transfer() so the subsystem can issue the next
566 transfer. This may sleep. Note: transfer_one and transfer_one_message
567 are mutually exclusive; when both are set, the generic subsystem does
568 not call your transfer_one callback.
571 negative errno: error
572 0: transfer is finished
573 1: transfer is still in progress
577 master->transfer(struct spi_device *spi, struct spi_message *message)
578 This must not sleep. Its responsibility is to arrange that the
579 transfer happens and its complete() callback is issued. The two
580 will normally happen later, after other transfers complete, and
581 if the controller is idle it will need to be kickstarted. This
582 method is not used on queued controllers and must be NULL if
583 transfer_one_message() and (un)prepare_transfer_hardware() are
589 If you are happy with the standard queueing mechanism provided by the
590 SPI subsystem, just implement the queued methods specified above. Using
591 the message queue has the upside of centralizing a lot of code and
592 providing pure process-context execution of methods. The message queue
593 can also be elevated to realtime priority on high-priority SPI traffic.
595 Unless the queueing mechanism in the SPI subsystem is selected, the bulk
596 of the driver will be managing the I/O queue fed by the now deprecated
599 That queue could be purely conceptual. For example, a driver used only
600 for low-frequency sensor access might be fine using synchronous PIO.
602 But the queue will probably be very real, using message->queue, PIO,
603 often DMA (especially if the root filesystem is in SPI flash), and
604 execution contexts like IRQ handlers, tasklets, or workqueues (such
605 as keventd). Your driver can be as fancy, or as simple, as you need.
606 Such a transfer() method would normally just add the message to a
607 queue, and then start some asynchronous transfer engine (unless it's
613 Contributors to Linux-SPI discussions include (in alphabetical order,