1 Linux and the Device Tree
2 -------------------------
3 The Linux usage model for device tree data
5 Author: Grant Likely <grant.likely@secretlab.ca>
7 This article describes how Linux uses the device tree. An overview of
8 the device tree data format can be found on the device tree usage page
11 [1] http://devicetree.org/Device_Tree_Usage
13 The "Open Firmware Device Tree", or simply Device Tree (DT), is a data
14 structure and language for describing hardware. More specifically, it
15 is a description of hardware that is readable by an operating system
16 so that the operating system doesn't need to hard code details of the
19 Structurally, the DT is a tree, or acyclic graph with named nodes, and
20 nodes may have an arbitrary number of named properties encapsulating
21 arbitrary data. A mechanism also exists to create arbitrary
22 links from one node to another outside of the natural tree structure.
24 Conceptually, a common set of usage conventions, called 'bindings',
25 is defined for how data should appear in the tree to describe typical
26 hardware characteristics including data busses, interrupt lines, GPIO
27 connections, and peripheral devices.
29 As much as possible, hardware is described using existing bindings to
30 maximize use of existing support code, but since property and node
31 names are simply text strings, it is easy to extend existing bindings
32 or create new ones by defining new nodes and properties. Be wary,
33 however, of creating a new binding without first doing some homework
34 about what already exists. There are currently two different,
35 incompatible, bindings for i2c busses that came about because the new
36 binding was created without first investigating how i2c devices were
37 already being enumerated in existing systems.
41 The DT was originally created by Open Firmware as part of the
42 communication method for passing data from Open Firmware to a client
43 program (like to an operating system). An operating system used the
44 Device Tree to discover the topology of the hardware at runtime, and
45 thereby support a majority of available hardware without hard coded
46 information (assuming drivers were available for all devices).
48 Since Open Firmware is commonly used on PowerPC and SPARC platforms,
49 the Linux support for those architectures has for a long time used the
52 In 2005, when PowerPC Linux began a major cleanup and to merge 32-bit
53 and 64-bit support, the decision was made to require DT support on all
54 powerpc platforms, regardless of whether or not they used Open
55 Firmware. To do this, a DT representation called the Flattened Device
56 Tree (FDT) was created which could be passed to the kernel as a binary
57 blob without requiring a real Open Firmware implementation. U-Boot,
58 kexec, and other bootloaders were modified to support both passing a
59 Device Tree Binary (dtb) and to modify a dtb at boot time. DT was
60 also added to the PowerPC boot wrapper (arch/powerpc/boot/*) so that
61 a dtb could be wrapped up with the kernel image to support booting
62 existing non-DT aware firmware.
64 Some time later, FDT infrastructure was generalized to be usable by
65 all architectures. At the time of this writing, 6 mainlined
66 architectures (arm, microblaze, mips, powerpc, sparc, and x86) and 1
67 out of mainline (nios) have some level of DT support.
71 If you haven't already read the Device Tree Usage[1] page,
72 then go read it now. It's okay, I'll wait....
76 The most important thing to understand is that the DT is simply a data
77 structure that describes the hardware. There is nothing magical about
78 it, and it doesn't magically make all hardware configuration problems
79 go away. What it does do is provide a language for decoupling the
80 hardware configuration from the board and device driver support in the
81 Linux kernel (or any other operating system for that matter). Using
82 it allows board and device support to become data driven; to make
83 setup decisions based on data passed into the kernel instead of on
84 per-machine hard coded selections.
86 Ideally, data driven platform setup should result in less code
87 duplication and make it easier to support a wide range of hardware
88 with a single kernel image.
90 Linux uses DT data for three major purposes:
91 1) platform identification,
92 2) runtime configuration, and
95 2.2 Platform Identification
96 ---------------------------
97 First and foremost, the kernel will use data in the DT to identify the
98 specific machine. In a perfect world, the specific platform shouldn't
99 matter to the kernel because all platform details would be described
100 perfectly by the device tree in a consistent and reliable manner.
101 Hardware is not perfect though, and so the kernel must identify the
102 machine during early boot so that it has the opportunity to run
103 machine-specific fixups.
105 In the majority of cases, the machine identity is irrelevant, and the
106 kernel will instead select setup code based on the machine's core
107 CPU or SoC. On ARM for example, setup_arch() in
108 arch/arm/kernel/setup.c will call setup_machine_fdt() in
109 arch/arm/kernel/devtree.c which searches through the machine_desc
110 table and selects the machine_desc which best matches the device tree
111 data. It determines the best match by looking at the 'compatible'
112 property in the root device tree node, and comparing it with the
113 dt_compat list in struct machine_desc (which is defined in
114 arch/arm/include/asm/mach/arch.h if you're curious).
116 The 'compatible' property contains a sorted list of strings starting
117 with the exact name of the machine, followed by an optional list of
118 boards it is compatible with sorted from most compatible to least. For
119 example, the root compatible properties for the TI BeagleBoard and its
120 successor, the BeagleBoard xM board might look like, respectively:
122 compatible = "ti,omap3-beagleboard", "ti,omap3450", "ti,omap3";
123 compatible = "ti,omap3-beagleboard-xm", "ti,omap3450", "ti,omap3";
125 Where "ti,omap3-beagleboard-xm" specifies the exact model, it also
126 claims that it compatible with the OMAP 3450 SoC, and the omap3 family
127 of SoCs in general. You'll notice that the list is sorted from most
128 specific (exact board) to least specific (SoC family).
130 Astute readers might point out that the Beagle xM could also claim
131 compatibility with the original Beagle board. However, one should be
132 cautioned about doing so at the board level since there is typically a
133 high level of change from one board to another, even within the same
134 product line, and it is hard to nail down exactly what is meant when one
135 board claims to be compatible with another. For the top level, it is
136 better to err on the side of caution and not claim one board is
137 compatible with another. The notable exception would be when one
138 board is a carrier for another, such as a CPU module attached to a
141 One more note on compatible values. Any string used in a compatible
142 property must be documented as to what it indicates. Add
143 documentation for compatible strings in Documentation/devicetree/bindings.
145 Again on ARM, for each machine_desc, the kernel looks to see if
146 any of the dt_compat list entries appear in the compatible property.
147 If one does, then that machine_desc is a candidate for driving the
148 machine. After searching the entire table of machine_descs,
149 setup_machine_fdt() returns the 'most compatible' machine_desc based
150 on which entry in the compatible property each machine_desc matches
151 against. If no matching machine_desc is found, then it returns NULL.
153 The reasoning behind this scheme is the observation that in the majority
154 of cases, a single machine_desc can support a large number of boards
155 if they all use the same SoC, or same family of SoCs. However,
156 invariably there will be some exceptions where a specific board will
157 require special setup code that is not useful in the generic case.
158 Special cases could be handled by explicitly checking for the
159 troublesome board(s) in generic setup code, but doing so very quickly
160 becomes ugly and/or unmaintainable if it is more than just a couple of
163 Instead, the compatible list allows a generic machine_desc to provide
164 support for a wide common set of boards by specifying "less
165 compatible" values in the dt_compat list. In the example above,
166 generic board support can claim compatibility with "ti,omap3" or
167 "ti,omap3450". If a bug was discovered on the original beagleboard
168 that required special workaround code during early boot, then a new
169 machine_desc could be added which implements the workarounds and only
170 matches on "ti,omap3-beagleboard".
172 PowerPC uses a slightly different scheme where it calls the .probe()
173 hook from each machine_desc, and the first one returning TRUE is used.
174 However, this approach does not take into account the priority of the
175 compatible list, and probably should be avoided for new architecture
178 2.3 Runtime configuration
179 -------------------------
180 In most cases, a DT will be the sole method of communicating data from
181 firmware to the kernel, so also gets used to pass in runtime and
182 configuration data like the kernel parameters string and the location
185 Most of this data is contained in the /chosen node, and when booting
186 Linux it will look something like this:
189 bootargs = "console=ttyS0,115200 loglevel=8";
190 initrd-start = <0xc8000000>;
191 initrd-end = <0xc8200000>;
194 The bootargs property contains the kernel arguments, and the initrd-*
195 properties define the address and size of an initrd blob. Note that
196 initrd-end is the first address after the initrd image, so this doesn't
197 match the usual semantic of struct resource. The chosen node may also
198 optionally contain an arbitrary number of additional properties for
199 platform-specific configuration data.
201 During early boot, the architecture setup code calls of_scan_flat_dt()
202 several times with different helper callbacks to parse device tree
203 data before paging is setup. The of_scan_flat_dt() code scans through
204 the device tree and uses the helpers to extract information required
205 during early boot. Typically the early_init_dt_scan_chosen() helper
206 is used to parse the chosen node including kernel parameters,
207 early_init_dt_scan_root() to initialize the DT address space model,
208 and early_init_dt_scan_memory() to determine the size and
209 location of usable RAM.
211 On ARM, the function setup_machine_fdt() is responsible for early
212 scanning of the device tree after selecting the correct machine_desc
213 that supports the board.
215 2.4 Device population
216 ---------------------
217 After the board has been identified, and after the early configuration data
218 has been parsed, then kernel initialization can proceed in the normal
219 way. At some point in this process, unflatten_device_tree() is called
220 to convert the data into a more efficient runtime representation.
221 This is also when machine-specific setup hooks will get called, like
222 the machine_desc .init_early(), .init_irq() and .init_machine() hooks
223 on ARM. The remainder of this section uses examples from the ARM
224 implementation, but all architectures will do pretty much the same
225 thing when using a DT.
227 As can be guessed by the names, .init_early() is used for any machine-
228 specific setup that needs to be executed early in the boot process,
229 and .init_irq() is used to set up interrupt handling. Using a DT
230 doesn't materially change the behaviour of either of these functions.
231 If a DT is provided, then both .init_early() and .init_irq() are able
232 to call any of the DT query functions (of_* in include/linux/of*.h) to
233 get additional data about the platform.
235 The most interesting hook in the DT context is .init_machine() which
236 is primarily responsible for populating the Linux device model with
237 data about the platform. Historically this has been implemented on
238 embedded platforms by defining a set of static clock structures,
239 platform_devices, and other data in the board support .c file, and
240 registering it en-masse in .init_machine(). When DT is used, then
241 instead of hard coding static devices for each platform, the list of
242 devices can be obtained by parsing the DT, and allocating device
243 structures dynamically.
245 The simplest case is when .init_machine() is only responsible for
246 registering a block of platform_devices. A platform_device is a concept
247 used by Linux for memory or I/O mapped devices which cannot be detected
248 by hardware, and for 'composite' or 'virtual' devices (more on those
249 later). While there is no 'platform device' terminology for the DT,
250 platform devices roughly correspond to device nodes at the root of the
251 tree and children of simple memory mapped bus nodes.
253 About now is a good time to lay out an example. Here is part of the
254 device tree for the NVIDIA Tegra board.
257 compatible = "nvidia,harmony", "nvidia,tegra20";
258 #address-cells = <1>;
260 interrupt-parent = <&intc>;
266 device_type = "memory";
267 reg = <0x00000000 0x40000000>;
271 compatible = "nvidia,tegra20-soc", "simple-bus";
272 #address-cells = <1>;
276 intc: interrupt-controller@50041000 {
277 compatible = "nvidia,tegra20-gic";
278 interrupt-controller;
279 #interrupt-cells = <1>;
280 reg = <0x50041000 0x1000>, < 0x50040100 0x0100 >;
284 compatible = "nvidia,tegra20-uart";
285 reg = <0x70006300 0x100>;
290 compatible = "nvidia,tegra20-i2s";
291 reg = <0x70002800 0x100>;
297 compatible = "nvidia,tegra20-i2c";
298 #address-cells = <1>;
300 reg = <0x7000c000 0x100>;
304 compatible = "wlf,wm8903";
312 compatible = "nvidia,harmony-sound";
313 i2s-controller = <&i2s1>;
314 i2s-codec = <&wm8903>;
318 At .init_machine() time, Tegra board support code will need to look at
319 this DT and decide which nodes to create platform_devices for.
320 However, looking at the tree, it is not immediately obvious what kind
321 of device each node represents, or even if a node represents a device
322 at all. The /chosen, /aliases, and /memory nodes are informational
323 nodes that don't describe devices (although arguably memory could be
324 considered a device). The children of the /soc node are memory mapped
325 devices, but the codec@1a is an i2c device, and the sound node
326 represents not a device, but rather how other devices are connected
327 together to create the audio subsystem. I know what each device is
328 because I'm familiar with the board design, but how does the kernel
329 know what to do with each node?
331 The trick is that the kernel starts at the root of the tree and looks
332 for nodes that have a 'compatible' property. First, it is generally
333 assumed that any node with a 'compatible' property represents a device
334 of some kind, and second, it can be assumed that any node at the root
335 of the tree is either directly attached to the processor bus, or is a
336 miscellaneous system device that cannot be described any other way.
337 For each of these nodes, Linux allocates and registers a
338 platform_device, which in turn may get bound to a platform_driver.
340 Why is using a platform_device for these nodes a safe assumption?
341 Well, for the way that Linux models devices, just about all bus_types
342 assume that its devices are children of a bus controller. For
343 example, each i2c_client is a child of an i2c_master. Each spi_device
344 is a child of an SPI bus. Similarly for USB, PCI, MDIO, etc. The
345 same hierarchy is also found in the DT, where I2C device nodes only
346 ever appear as children of an I2C bus node. Ditto for SPI, MDIO, USB,
347 etc. The only devices which do not require a specific type of parent
348 device are platform_devices (and amba_devices, but more on that
349 later), which will happily live at the base of the Linux /sys/devices
350 tree. Therefore, if a DT node is at the root of the tree, then it
351 really probably is best registered as a platform_device.
353 Linux board support code calls of_platform_populate(NULL, NULL, NULL, NULL)
354 to kick off discovery of devices at the root of the tree. The
355 parameters are all NULL because when starting from the root of the
356 tree, there is no need to provide a starting node (the first NULL), a
357 parent struct device (the last NULL), and we're not using a match
358 table (yet). For a board that only needs to register devices,
359 .init_machine() can be completely empty except for the
360 of_platform_populate() call.
362 In the Tegra example, this accounts for the /soc and /sound nodes, but
363 what about the children of the SoC node? Shouldn't they be registered
364 as platform devices too? For Linux DT support, the generic behaviour
365 is for child devices to be registered by the parent's device driver at
366 driver .probe() time. So, an i2c bus device driver will register a
367 i2c_client for each child node, an SPI bus driver will register
368 its spi_device children, and similarly for other bus_types.
369 According to that model, a driver could be written that binds to the
370 SoC node and simply registers platform_devices for each of its
371 children. The board support code would allocate and register an SoC
372 device, a (theoretical) SoC device driver could bind to the SoC device,
373 and register platform_devices for /soc/interrupt-controller, /soc/serial,
374 /soc/i2s, and /soc/i2c in its .probe() hook. Easy, right?
376 Actually, it turns out that registering children of some
377 platform_devices as more platform_devices is a common pattern, and the
378 device tree support code reflects that and makes the above example
379 simpler. The second argument to of_platform_populate() is an
380 of_device_id table, and any node that matches an entry in that table
381 will also get its child nodes registered. In the Tegra case, the code
382 can look something like this:
384 static void __init harmony_init_machine(void)
387 of_platform_populate(NULL, of_default_bus_match_table, NULL, NULL);
390 "simple-bus" is defined in the Devicetree Specification as a property
391 meaning a simple memory mapped bus, so the of_platform_populate() code
392 could be written to just assume simple-bus compatible nodes will
393 always be traversed. However, we pass it in as an argument so that
394 board support code can always override the default behaviour.
396 [Need to add discussion of adding i2c/spi/etc child devices]
398 Appendix A: AMBA devices
399 ------------------------
401 ARM Primecells are a certain kind of device attached to the ARM AMBA
402 bus which include some support for hardware detection and power
403 management. In Linux, struct amba_device and the amba_bus_type is
404 used to represent Primecell devices. However, the fiddly bit is that
405 not all devices on an AMBA bus are Primecells, and for Linux it is
406 typical for both amba_device and platform_device instances to be
407 siblings of the same bus segment.
409 When using the DT, this creates problems for of_platform_populate()
410 because it must decide whether to register each node as either a
411 platform_device or an amba_device. This unfortunately complicates the
412 device creation model a little bit, but the solution turns out not to
413 be too invasive. If a node is compatible with "arm,amba-primecell", then
414 of_platform_populate() will register it as an amba_device instead of a