1 .. SPDX-License-Identifier: GPL-2.0+
2 .. Copyright (c) 2016 Google, Inc
7 Firmware often consists of several components which must be packaged together.
8 For example, we may have SPL, U-Boot, a device tree and an environment area
9 grouped together and placed in MMC flash. When the system starts, it must be
10 able to find these pieces.
12 Building firmware should be separate from packaging it. Many of the complexities
13 of modern firmware build systems come from trying to do both at once. With
14 binman, you build all the pieces that are needed, using whatever assortment of
15 projects and build systems are needed, then use binman to stitch everything
22 Binman reads your board's device tree and finds a node which describes the
23 required image layout. It uses this to work out what to place where.
25 Binman provides a mechanism for building images, from simple SPL + U-Boot
26 combinations, to more complex arrangements with many parts. It also allows
27 users to inspect images, extract and replace binaries within them, repacking if
34 Apart from basic padding, alignment and positioning features, Binman supports
35 hierarchical images, compression, hashing and dealing with the binary blobs
36 which are a sad trend in open-source firmware at present.
38 Executable binaries can access the location of other binaries in an image by
39 using special linker symbols (zero-overhead but somewhat limited) or by reading
40 the devicetree description of the image.
42 Binman is designed primarily for use with U-Boot and associated binaries such
43 as ARM Trusted Firmware, but it is suitable for use with other projects, such
44 as Zephyr. Binman also provides facilities useful in Chromium OS, such as CBFS,
45 vblocks and and the like.
47 Binman provides a way to process binaries before they are included, by adding a
50 Binman is intended for use with U-Boot but is designed to be general enough
51 to be useful in other image-packaging situations.
57 As mentioned above, packaging of firmware is quite a different task from
58 building the various parts. In many cases the various binaries which go into
59 the image come from separate build systems. For example, ARM Trusted Firmware
60 is used on ARMv8 devices but is not built in the U-Boot tree. If a Linux kernel
61 is included in the firmware image, it is built elsewhere.
63 It is of course possible to add more and more build rules to the U-Boot
64 build system to cover these cases. It can shell out to other Makefiles and
65 build scripts. But it seems better to create a clear divide between building
66 software and packaging it.
68 At present this is handled by manual instructions, different for each board,
69 on how to create images that will boot. By turning these instructions into a
70 standard format, we can support making valid images for any board without
71 manual effort, lots of READMEs, etc.
75 - Each binary can have its own build system and tool chain without creating
76 any dependencies between them
77 - Avoids the need for a single-shot build: individual parts can be updated
78 and brought in as needed
79 - Provides for a standard image description available in the build and at
81 - SoC-specific image-signing tools can be accommodated
82 - Avoids cluttering the U-Boot build system with image-building code
83 - The image description is automatically available at run-time in U-Boot,
84 SPL. It can be made available to other software also
85 - The image description is easily readable (it's a text file in device-tree
86 format) and permits flexible packing of binaries
92 Binman uses the following terms:
94 - image - an output file containing a firmware image
95 - binary - an input binary that goes into the image
101 FIT is U-Boot's official image format. It supports multiple binaries with
102 load / execution addresses, compression. It also supports verification
103 through hashing and RSA signatures.
105 FIT was originally designed to support booting a Linux kernel (with an
106 optional ramdisk) and device tree chosen from various options in the FIT.
107 Now that U-Boot supports configuration via device tree, it is possible to
108 load U-Boot from a FIT, with the device tree chosen by SPL.
110 Binman considers FIT to be one of the binaries it can place in the image.
112 Where possible it is best to put as much as possible in the FIT, with binman
113 used to deal with cases not covered by FIT. Examples include initial
114 execution (since FIT itself does not have an executable header) and dealing
115 with device boundaries, such as the read-only/read-write separation in SPI
118 For U-Boot, binman should not be used to create ad-hoc images in place of
122 Relationship to mkimage
123 -----------------------
125 The mkimage tool provides a means to create a FIT. Traditionally it has
126 needed an image description file: a device tree, like binman, but in a
127 different format. More recently it has started to support a '-f auto' mode
128 which can generate that automatically.
130 More relevant to binman, mkimage also permits creation of many SoC-specific
131 image types. These can be listed by running 'mkimage -T list'. Examples
132 include 'rksd', the Rockchip SD/MMC boot format. The mkimage tool is often
133 called from the U-Boot build system for this reason.
135 Binman considers the output files created by mkimage to be binary blobs
136 which it can place in an image. Binman does not replace the mkimage tool or
137 this purpose. It would be possible in some situations to create a new entry
138 type for the images in mkimage, but this would not add functionality. It
139 seems better to use the mkimage tool to generate binaries and avoid blurring
140 the boundaries between building input files (mkimage) and packaging then
141 into a final image (binman).
147 Example use of binman in U-Boot
148 -------------------------------
150 Binman aims to replace some of the ad-hoc image creation in the U-Boot
153 Consider sunxi. It has the following steps:
155 #. It uses a custom mksunxiboot tool to build an SPL image called
156 sunxi-spl.bin. This should probably move into mkimage.
158 #. It uses mkimage to package U-Boot into a legacy image file (so that it can
159 hold the load and execution address) called u-boot.img.
161 #. It builds a final output image called u-boot-sunxi-with-spl.bin which
162 consists of sunxi-spl.bin, some padding and u-boot.img.
164 Binman is intended to replace the last step. The U-Boot build system builds
165 u-boot.bin and sunxi-spl.bin. Binman can then take over creation of
166 sunxi-spl.bin (by calling mksunxiboot, or hopefully one day mkimage). In any
167 case, it would then create the image from the component parts.
169 This simplifies the U-Boot Makefile somewhat, since various pieces of logic
170 can be replaced by a call to binman.
173 Example use of binman for x86
174 -----------------------------
176 In most cases x86 images have a lot of binary blobs, 'black-box' code
177 provided by Intel which must be run for the platform to work. Typically
178 these blobs are not relocatable and must be placed at fixed areas in the
181 Currently this is handled by ifdtool, which places microcode, FSP, MRC, VGA
182 BIOS, reference code and Intel ME binaries into a u-boot.rom file.
184 Binman is intended to replace all of this, with ifdtool left to handle only
185 the configuration of the Intel-format descriptor.
191 First install prerequisites, e.g::
193 sudo apt-get install python-pyelftools python3-pyelftools lzma-alone \
198 binman build -b <board_name>
200 to build an image for a board. The board name is the same name used when
201 configuring U-Boot (e.g. for sandbox_defconfig the board name is 'sandbox').
202 Binman assumes that the input files for the build are in ../b/<board_name>.
204 Or you can specify this explicitly::
206 binman build -I <build_path>
208 where <build_path> is the build directory containing the output of the U-Boot
211 (Future work will make this more configurable)
213 In either case, binman picks up the device tree file (u-boot.dtb) and looks
214 for its instructions in the 'binman' node.
216 Binman has a few other options which you can see by running 'binman -h'.
219 Enabling binman for a board
220 ---------------------------
222 At present binman is invoked from a rule in the main Makefile. You should be
223 able to enable CONFIG_BINMAN to enable this rule.
225 The output file is typically named image.bin and is located in the output
226 directory. If input files are needed to you add these to INPUTS-y either in the
227 main Makefile or in a config.mk file in your arch subdirectory.
229 Once binman is executed it will pick up its instructions from a device-tree
230 file, typically <soc>-u-boot.dtsi, where <soc> is your CONFIG_SYS_SOC value.
231 You can use other, more specific CONFIG options - see 'Automatic .dtsi
235 Using binman with OF_BOARD
236 --------------------------------------------
238 Normally binman is used with a board configured with OF_SEPARATE or OF_EMBED.
239 This is a typical scenario where a device tree source that contains the binman
240 node is provided in the arch/<arch>/dts directory for a specific board.
242 However for a board configured with OF_BOARD, no device tree blob is provided
243 in the U-Boot build phase hence the binman node information is not available.
244 In order to support such use case, a new Kconfig option BINMAN_STANDALONE_FDT
245 is introduced, to tell the build system that a standalone device tree blob
246 containing binman node is explicitly required.
248 Note there is a Kconfig option BINMAN_FDT which enables U-Boot run time to
249 access information about binman entries, stored in the device tree in a binman
250 node. Generally speaking, this option makes sense for OF_SEPARATE or OF_EMBED.
251 For the other OF_CONTROL methods, it's quite possible binman node is not
252 available as binman is invoked during the build phase, thus this option is not
253 turned on by default for these OF_CONTROL methods.
255 Access to binman entry offsets at run time (symbols)
256 ----------------------------------------------------
258 Binman assembles images and determines where each entry is placed in the image.
259 This information may be useful to U-Boot at run time. For example, in SPL it
260 is useful to be able to find the location of U-Boot so that it can be executed
261 when SPL is finished.
263 Binman allows you to declare symbols in the SPL image which are filled in
264 with their correct values during the build. For example::
266 binman_sym_declare(ulong, u_boot_any, image_pos);
268 declares a ulong value which will be assigned to the image-pos of any U-Boot
269 image (u-boot.bin, u-boot.img, u-boot-nodtb.bin) that is present in the image.
270 You can access this value with something like::
272 ulong u_boot_offset = binman_sym(ulong, u_boot_any, image_pos);
274 Thus u_boot_offset will be set to the image-pos of U-Boot in memory, assuming
275 that the whole image has been loaded, or is available in flash. You can then
276 jump to that address to start U-Boot.
278 At present this feature is only supported in SPL and TPL. In principle it is
279 possible to fill in such symbols in U-Boot proper, as well, but a future C
280 library is planned for this instead, to read from the device tree.
282 As well as image-pos, it is possible to read the size of an entry and its
283 offset (which is the start position of the entry within its parent).
285 A small technical note: Binman automatically adds the base address of the image
286 (i.e. __image_copy_start) to the value of the image-pos symbol, so that when the
287 image is loaded to its linked address, the value will be correct and actually
288 point into the image.
290 For example, say SPL is at the start of the image and linked to start at address
291 80108000. If U-Boot's image-pos is 0x8000 then binman will write an image-pos
292 for U-Boot of 80110000 into the SPL binary, since it assumes the image is loaded
293 to 80108000, with SPL at 80108000 and U-Boot at 80110000.
295 For x86 devices (with the end-at-4gb property) this base address is not added
296 since it is assumed that images are XIP and the offsets already include the
300 Access to binman entry offsets at run time (fdt)
301 ------------------------------------------------
303 Binman can update the U-Boot FDT to include the final position and size of
304 each entry in the images it processes. The option to enable this is -u and it
305 causes binman to make sure that the 'offset', 'image-pos' and 'size' properties
306 are set correctly for every entry. Since it is not necessary to specify these in
307 the image definition, binman calculates the final values and writes these to
308 the device tree. These can be used by U-Boot at run-time to find the location
311 Alternatively, an FDT map entry can be used to add a special FDT containing
312 just the information about the image. This is preceded by a magic string so can
313 be located anywhere in the image. An image header (typically at the start or end
314 of the image) can be used to point to the FDT map. See fdtmap and image-header
315 entries for more information.
321 The -m option causes binman to output a .map file for each image that it
322 generates. This shows the offset and size of each entry. For example::
325 00000000 00000028 main-section
326 00000000 00000010 section@0
327 00000000 00000004 u-boot
328 00000010 00000010 section@1
329 00000000 00000004 u-boot
331 This shows a hierarchical image with two sections, each with a single entry. The
332 offsets of the sections are absolute hex byte offsets within the image. The
333 offsets of the entries are relative to their respective sections. The size of
334 each entry is also shown, in bytes (hex). The indentation shows the entries
335 nested inside their sections.
338 Passing command-line arguments to entries
339 -----------------------------------------
341 Sometimes it is useful to pass binman the value of an entry property from the
342 command line. For example some entries need access to files and it is not
343 always convenient to put these filenames in the image definition (device tree).
345 The -a option supports this::
351 <prop> is the property to set
352 <value> is the value to set it to
354 Not all properties can be provided this way. Only some entries support it,
355 typically for filenames.
358 Image description format
359 ========================
361 The binman node is called 'binman'. An example image description is shown
365 filename = "u-boot-sunxi-with-spl.bin";
368 filename = "spl/sunxi-spl.bin";
371 offset = <CONFIG_SPL_PAD_TO>;
376 This requests binman to create an image file called u-boot-sunxi-with-spl.bin
377 consisting of a specially formatted SPL (spl/sunxi-spl.bin, built by the
378 normal U-Boot Makefile), some 0xff padding, and a U-Boot legacy image. The
379 padding comes from the fact that the second binary is placed at
380 CONFIG_SPL_PAD_TO. If that line were omitted then the U-Boot binary would
381 immediately follow the SPL binary.
383 The binman node describes an image. The sub-nodes describe entries in the
384 image. Each entry represents a region within the overall image. The name of
385 the entry (blob, u-boot) tells binman what to put there. For 'blob' we must
386 provide a filename. For 'u-boot', binman knows that this means 'u-boot.bin'.
388 Entries are normally placed into the image sequentially, one after the other.
389 The image size is the total size of all entries. As you can see, you can
390 specify the start offset of an entry using the 'offset' property.
392 Note that due to a device tree requirement, all entries must have a unique
393 name. If you want to put the same binary in the image multiple times, you can
394 use any unique name, with the 'type' property providing the type.
396 The attributes supported for entries are described below.
399 This sets the offset of an entry within the image or section containing
400 it. The first byte of the image is normally at offset 0. If 'offset' is
401 not provided, binman sets it to the end of the previous region, or the
402 start of the image's entry area (normally 0) if there is no previous
406 This sets the alignment of the entry. The entry offset is adjusted
407 so that the entry starts on an aligned boundary within the containing
408 section or image. For example 'align = <16>' means that the entry will
409 start on a 16-byte boundary. This may mean that padding is added before
410 the entry. The padding is part of the containing section but is not
411 included in the entry, meaning that an empty space may be created before
412 the entry starts. Alignment should be a power of 2. If 'align' is not
413 provided, no alignment is performed.
416 This sets the size of the entry. The contents will be padded out to
417 this size. If this is not provided, it will be set to the size of the
421 Padding before the contents of the entry. Normally this is 0, meaning
422 that the contents start at the beginning of the entry. This can be used
423 to offset the entry contents a little. While this does not affect the
424 contents of the entry within binman itself (the padding is performed
425 only when its parent section is assembled), the end result will be that
426 the entry starts with the padding bytes, so may grow. Defaults to 0.
429 Padding after the contents of the entry. Normally this is 0, meaning
430 that the entry ends at the last byte of content (unless adjusted by
431 other properties). This allows room to be created in the image for
432 this entry to expand later. While this does not affect the contents of
433 the entry within binman itself (the padding is performed only when its
434 parent section is assembled), the end result will be that the entry ends
435 with the padding bytes, so may grow. Defaults to 0.
438 This sets the alignment of the entry size. For example, to ensure
439 that the size of an entry is a multiple of 64 bytes, set this to 64.
440 While this does not affect the contents of the entry within binman
441 itself (the padding is performed only when its parent section is
442 assembled), the end result is that the entry ends with the padding
443 bytes, so may grow. If 'align-size' is not provided, no alignment is
447 This sets the alignment of the end of an entry with respect to the
448 containing section. Some entries require that they end on an alignment
449 boundary, regardless of where they start. This does not move the start
450 of the entry, so the contents of the entry will still start at the
451 beginning. But there may be padding at the end. While this does not
452 affect the contents of the entry within binman itself (the padding is
453 performed only when its parent section is assembled), the end result
454 is that the entry ends with the padding bytes, so may grow.
455 If 'align-end' is not provided, no alignment is performed.
458 For 'blob' types this provides the filename containing the binary to
459 put into the entry. If binman knows about the entry type (like
460 u-boot-bin), then there is no need to specify this.
463 Sets the type of an entry. This defaults to the entry name, but it is
464 possible to use any name, and then add (for example) 'type = "u-boot"'
468 Indicates that the offset of this entry should not be set by placing
469 it immediately after the entry before. Instead, is set by another
470 entry which knows where this entry should go. When this boolean
471 property is present, binman will give an error if another entry does
472 not set the offset (with the GetOffsets() method).
475 This cannot be set on entry (or at least it is ignored if it is), but
476 with the -u option, binman will set it to the absolute image position
477 for each entry. This makes it easy to find out exactly where the entry
478 ended up in the image, regardless of parent sections, etc.
481 Expand the size of this entry to fit available space. This space is only
482 limited by the size of the image/section and the position of the next
486 Sets the compression algortihm to use (for blobs only). See the entry
487 documentation for details.
490 Sets the tag of the message to show if this entry is missing. This is
491 used for external blobs. When they are missing it is helpful to show
492 information about what needs to be fixed. See missing-blob-help for the
493 message for each tag.
496 By default binman substitutes entries with expanded versions if available,
497 so that a `u-boot` entry type turns into `u-boot-expanded`, for example. The
498 `--no-expanded` command-line option disables this globally. The
499 `no-expanded` property disables this just for a single entry. Put the
500 `no-expanded` boolean property in the node to select this behaviour.
502 The attributes supported for images and sections are described below. Several
503 are similar to those for entries.
506 Sets the image size in bytes, for example 'size = <0x100000>' for a
510 This is similar to 'offset' in entries, setting the offset of a section
511 within the image or section containing it. The first byte of the section
512 is normally at offset 0. If 'offset' is not provided, binman sets it to
513 the end of the previous region, or the start of the image's entry area
514 (normally 0) if there is no previous region.
517 This sets the alignment of the image size. For example, to ensure
518 that the image ends on a 512-byte boundary, use 'align-size = <512>'.
519 If 'align-size' is not provided, no alignment is performed.
522 This sets the padding before the image entries. The first entry will
523 be positioned after the padding. This defaults to 0.
526 This sets the padding after the image entries. The padding will be
527 placed after the last entry. This defaults to 0.
530 This specifies the pad byte to use when padding in the image. It
531 defaults to 0. To use 0xff, you would add 'pad-byte = <0xff>'.
534 This specifies the image filename. It defaults to 'image.bin'.
537 This causes binman to reorder the entries as needed to make sure they
538 are in increasing positional order. This can be used when your entry
539 order may not match the positional order. A common situation is where
540 the 'offset' properties are set by CONFIG options, so their ordering is
543 This is a boolean property so needs no value. To enable it, add a
544 line 'sort-by-offset;' to your description.
547 Normally only a single image is generated. To create more than one
548 image, put this property in the binman node. For example, this will
549 create image1.bin containing u-boot.bin, and image2.bin containing
550 both spl/u-boot-spl.bin and u-boot.bin::
568 For x86 machines the ROM offsets start just before 4GB and extend
569 up so that the image finished at the 4GB boundary. This boolean
570 option can be enabled to support this. The image size must be
571 provided so that binman knows when the image should start. For an
572 8MB ROM, the offset of the first entry would be 0xfff80000 with
573 this option, instead of 0 without this option.
576 This property specifies the entry offset of the first entry.
578 For PowerPC mpc85xx based CPU, CONFIG_SYS_TEXT_BASE is the entry
579 offset of the first entry. It can be 0xeff40000 or 0xfff40000 for
580 nor flash boot, 0x201000 for sd boot etc.
582 'end-at-4gb' property is not applicable where CONFIG_SYS_TEXT_BASE +
586 Specifies the default alignment for entries in this section, if they do
587 not specify an alignment. Note that this only applies to top-level entries
588 in the section (direct subentries), not any subentries of those entries.
589 This means that each section must specify its own default alignment, if
592 Examples of the above options can be found in the tests. See the
593 tools/binman/test directory.
595 It is possible to have the same binary appear multiple times in the image,
596 either by using a unit number suffix (u-boot@0, u-boot@1) or by using a
597 different name for each and specifying the type with the 'type' attribute.
600 Sections and hierachical images
601 -------------------------------
603 Sometimes it is convenient to split an image into several pieces, each of which
604 contains its own set of binaries. An example is a flash device where part of
605 the image is read-only and part is read-write. We can set up sections for each
606 of these, and place binaries in them independently. The image is still produced
607 as a single output file.
609 This feature provides a way of creating hierarchical images. For example here
610 is an example image with two copies of U-Boot. One is read-only (ro), intended
611 to be written only in the factory. Another is read-write (rw), so that it can be
612 upgraded in the field. The sizes are fixed so that the ro/rw boundary is known
613 and can be programmed::
631 This image could be placed into a SPI flash chip, with the protection boundary
634 A few special properties are provided for sections:
637 Indicates that this section is read-only. This has no impact on binman's
638 operation, but his property can be read at run time.
641 This string is prepended to all the names of the binaries in the
642 section. In the example above, the 'u-boot' binaries which actually be
643 renamed to 'ro-u-boot' and 'rw-u-boot'. This can be useful to
644 distinguish binaries with otherwise identical names.
650 Image nodes act like sections but also have a few extra properties:
653 Output filename for the image. This defaults to image.bin (or in the
654 case of multiple images <nodename>.bin where <nodename> is the name of
658 Create an image that can be repacked. With this option it is possible
659 to change anything in the image after it is created, including updating
660 the position and size of image components. By default this is not
661 permitted since it is not possibly to know whether this might violate a
662 constraint in the image description. For example, if a section has to
663 increase in size to hold a larger binary, that might cause the section
664 to fall out of its allow region (e.g. read-only portion of flash).
666 Adding this property causes the original offset and size values in the
667 image description to be stored in the FDT and fdtmap.
673 It is possible to ask binman to hash the contents of an entry and write that
674 value back to the device-tree node. For example::
684 Here, a new 'value' property will be written to the 'hash' node containing
685 the hash of the 'u-boot' entry. Only SHA256 is supported at present. Whole
686 sections can be hased if desired, by adding the 'hash' node to the section.
688 The has value can be chcked at runtime by hashing the data actually read and
689 comparing this has to the value in the device tree.
695 Binman automatically replaces 'u-boot' with an expanded version of that, i.e.
696 'u-boot-expanded'. This means that when you write::
704 type = "u-boot-expanded';
707 which in turn expands to::
719 U-Boot's various phase binaries actually comprise two or three pieces.
720 For example, u-boot.bin has the executable followed by a devicetree.
722 With binman we want to be able to update that devicetree with full image
723 information so that it is accessible to the executable. This is tricky
724 if it is not clear where the devicetree starts.
726 The above feature ensures that the devicetree is clearly separated from the
727 U-Boot executable and can be updated separately by binman as needed. It can be
728 disabled with the --no-expanded flag if required.
730 The same applies for u-boot-spl and u-boot-spl. In those cases, the expansion
731 includes the BSS padding, so for example::
740 type = "u-boot-expanded';
743 which in turn expands to::
758 Of course we should not expand SPL if it has no devicetree. Also if the BSS
759 padding is not needed (because BSS is in RAM as with CONFIG_SPL_SEPARATE_BSS),
760 the 'u-boot-spl-bss-pad' subnode should not be created. The use of the expaned
761 entry type is controlled by the UseExpanded() method. In the SPL case it checks
762 the 'spl-dtb' entry arg, which is 'y' or '1' if SPL has a devicetree.
764 For the BSS case, a 'spl-bss-pad' entry arg controls whether it is present. All
765 entry args are provided by the U-Boot Makefile.
771 Binman support compression for 'blob' entries (those of type 'blob' and
772 derivatives). To enable this for an entry, add a 'compress' property::
775 filename = "datafile";
779 The entry will then contain the compressed data, using the 'lz4' compression
780 algorithm. Currently this is the only one that is supported. The uncompressed
781 size is written to the node in an 'uncomp-size' property, if -u is used.
783 Compression is also supported for sections. In that case the entire section is
784 compressed in one block, including all its contents. This means that accessing
785 an entry from the section required decompressing the entire section. Also, the
786 size of a section indicates the space that it consumes in its parent section
787 (and typically the image). With compression, the section may contain more data,
788 and the uncomp-size property indicates that, as above. The contents of the
789 section is compressed first, before any padding is added. This ensures that the
790 padding itself is not compressed, which would be a waste of time.
793 Automatic .dtsi inclusion
794 -------------------------
796 It is sometimes inconvenient to add a 'binman' node to the .dts file for each
797 board. This can be done by using #include to bring in a common file. Another
798 approach supported by the U-Boot build system is to automatically include
799 a common header. You can then put the binman node (and anything else that is
800 specific to U-Boot, such as u-boot,dm-pre-reloc properies) in that header
803 Binman will search for the following files in arch/<arch>/dts::
805 <dts>-u-boot.dtsi where <dts> is the base name of the .dts file
806 <CONFIG_SYS_SOC>-u-boot.dtsi
807 <CONFIG_SYS_CPU>-u-boot.dtsi
808 <CONFIG_SYS_VENDOR>-u-boot.dtsi
811 U-Boot will only use the first one that it finds. If you need to include a
812 more general file you can do that from the more specific file using #include.
813 If you are having trouble figuring out what is going on, you can uncomment
814 the 'warning' line in scripts/Makefile.lib to see what it has found::
816 # Uncomment for debugging
817 # This shows all the files that were considered and the one that we chose.
818 # u_boot_dtsi_options_debug = $(u_boot_dtsi_options_raw)
824 For details on the various entry types supported by binman and how to use them,
825 see entries.rst which is generated from the source code using:
827 binman entry-docs >tools/binman/entries.rst
841 It is possible to list the entries in an existing firmware image created by
842 binman, provided that there is an 'fdtmap' entry in the image. For example::
844 $ binman ls -i image.bin
845 Name Image-pos Size Entry-type Offset Uncomp-size
846 ----------------------------------------------------------------------
847 main-section c00 section 0
849 section 5fc section 4
851 u-boot 138 4 u-boot 38
852 u-boot-dtb 180 108 u-boot-dtb 80 3b5
853 u-boot-dtb 500 1ff u-boot-dtb 400 3b5
854 fdtmap 6fc 381 fdtmap 6fc
855 image-header bf8 8 image-header bf8
857 This shows the hierarchy of the image, the position, size and type of each
858 entry, the offset of each entry within its parent and the uncompressed size if
859 the entry is compressed.
861 It is also possible to list just some files in an image, e.g.::
863 $ binman ls -i image.bin section/cbfs
864 Name Image-pos Size Entry-type Offset Uncomp-size
865 --------------------------------------------------------------------
867 u-boot 138 4 u-boot 38
868 u-boot-dtb 180 108 u-boot-dtb 80 3b5
872 $ binman ls -i image.bin "*cb*" "*head*"
873 Name Image-pos Size Entry-type Offset Uncomp-size
874 ----------------------------------------------------------------------
876 u-boot 138 4 u-boot 38
877 u-boot-dtb 180 108 u-boot-dtb 80 3b5
878 image-header bf8 8 image-header bf8
881 Extracting files from images
882 ----------------------------
884 You can extract files from an existing firmware image created by binman,
885 provided that there is an 'fdtmap' entry in the image. For example::
887 $ binman extract -i image.bin section/cbfs/u-boot
889 which will write the uncompressed contents of that entry to the file 'u-boot' in
890 the current directory. You can also extract to a particular file, in this case
893 $ binman extract -i image.bin section/cbfs/u-boot -f u-boot.bin
895 It is possible to extract all files into a destination directory, which will
896 put files in subdirectories matching the entry hierarchy::
898 $ binman extract -i image.bin -O outdir
900 or just a selection::
902 $ binman extract -i image.bin "*u-boot*" -O outdir
905 Replacing files in an image
906 ---------------------------
908 You can replace files in an existing firmware image created by binman, provided
909 that there is an 'fdtmap' entry in the image. For example:
911 $ binman replace -i image.bin section/cbfs/u-boot
913 which will write the contents of the file 'u-boot' from the current directory
914 to the that entry, compressing if necessary. If the entry size changes, you must
915 add the 'allow-repack' property to the original image before generating it (see
916 above), otherwise you will get an error.
918 You can also use a particular file, in this case u-boot.bin::
920 $ binman replace -i image.bin section/cbfs/u-boot -f u-boot.bin
922 It is possible to replace all files from a source directory which uses the same
923 hierarchy as the entries::
925 $ binman replace -i image.bin -I indir
927 Files that are missing will generate a warning.
929 You can also replace just a selection of entries::
931 $ binman replace -i image.bin "*u-boot*" -I indir
937 Binman normally operates silently unless there is an error, in which case it
938 just displays the error. The -D/--debug option can be used to create a full
939 backtrace when errors occur. You can use BINMAN_DEBUG=1 when building to select
942 Internally binman logs some output while it is running. This can be displayed
943 by increasing the -v/--verbosity from the default of 1:
947 2: notices (important messages)
948 3: info about major operations
949 4: detailed information about each operation
950 5: debug (all output)
952 You can use BINMAN_VERBOSE=5 (for example) when building to select this.
958 Order of image creation
959 -----------------------
961 Image creation proceeds in the following order, for each entry in the image.
963 1. AddMissingProperties() - binman can add calculated values to the device
964 tree as part of its processing, for example the offset and size of each
965 entry. This method adds any properties associated with this, expanding the
966 device tree as needed. These properties can have placeholder values which are
967 set later by SetCalculatedProperties(). By that stage the size of sections
968 cannot be changed (since it would cause the images to need to be repacked),
969 but the correct values can be inserted.
971 2. ProcessFdt() - process the device tree information as required by the
972 particular entry. This may involve adding or deleting properties. If the
973 processing is complete, this method should return True. If the processing
974 cannot complete because it needs the ProcessFdt() method of another entry to
975 run first, this method should return False, in which case it will be called
978 3. GetEntryContents() - the contents of each entry are obtained, normally by
979 reading from a file. This calls the Entry.ObtainContents() to read the
980 contents. The default version of Entry.ObtainContents() calls
981 Entry.GetDefaultFilename() and then reads that file. So a common mechanism
982 to select a file to read is to override that function in the subclass. The
983 functions must return True when they have read the contents. Binman will
984 retry calling the functions a few times if False is returned, allowing
985 dependencies between the contents of different entries.
987 4. GetEntryOffsets() - calls Entry.GetOffsets() for each entry. This can
988 return a dict containing entries that need updating. The key should be the
989 entry name and the value is a tuple (offset, size). This allows an entry to
990 provide the offset and size for other entries. The default implementation
991 of GetEntryOffsets() returns {}.
993 5. PackEntries() - calls Entry.Pack() which figures out the offset and
994 size of an entry. The 'current' image offset is passed in, and the function
995 returns the offset immediately after the entry being packed. The default
996 implementation of Pack() is usually sufficient.
998 Note: for sections, this also checks that the entries do not overlap, nor extend
999 outside the section. If the section does not have a defined size, the size is
1000 set large enough to hold all the entries.
1002 6. SetImagePos() - sets the image position of every entry. This is the absolute
1003 position 'image-pos', as opposed to 'offset' which is relative to the containing
1004 section. This must be done after all offsets are known, which is why it is quite
1005 late in the ordering.
1007 7. SetCalculatedProperties() - update any calculated properties in the device
1008 tree. This sets the correct 'offset' and 'size' vaues, for example.
1010 8. ProcessEntryContents() - this calls Entry.ProcessContents() on each entry.
1011 The default implementatoin does nothing. This can be overriden to adjust the
1012 contents of an entry in some way. For example, it would be possible to create
1013 an entry containing a hash of the contents of some other entries. At this
1014 stage the offset and size of entries should not be adjusted unless absolutely
1015 necessary, since it requires a repack (going back to PackEntries()).
1017 9. ResetForPack() - if the ProcessEntryContents() step failed, in that an entry
1018 has changed its size, then there is no alternative but to go back to step 5 and
1019 try again, repacking the entries with the updated size. ResetForPack() removes
1020 the fixed offset/size values added by binman, so that the packing can start from
1023 10. WriteSymbols() - write the value of symbols into the U-Boot SPL binary.
1024 See 'Access to binman entry offsets at run time' below for a description of
1025 what happens in this stage.
1027 11. BuildImage() - builds the image and writes it to a file
1029 12. WriteMap() - writes a text file containing a map of the image. This is the
1036 Binman can make use of external command-line tools to handle processing of
1037 entry contents or to generate entry contents. These tools are executed using
1038 the 'tools' module's Run() method. The tools generally must exist on the PATH,
1039 but the --toolpath option can be used to specify additional search paths to
1040 use. This option can be specified multiple times to add more than one path.
1042 For some compile tools binman will use the versions specified by commonly-used
1043 environment variables like CC and HOSTCC for the C compiler, based on whether
1044 the tool's output will be used for the target or for the host machine. If those
1045 aren't given, it will also try to derive target-specific versions from the
1046 CROSS_COMPILE environment variable during a cross-compilation.
1052 Binman is a critical tool and is designed to be very testable. Entry
1053 implementations target 100% test coverage. Run 'binman test -T' to check this.
1055 To enable Python test coverage on Debian-type distributions (e.g. Ubuntu)::
1057 $ sudo apt-get install python-coverage python3-coverage python-pytest
1063 Binman tries to run tests concurrently. This means that the tests make use of
1064 all available CPUs to run.
1068 $ sudo apt-get install python-subunit python3-subunit
1070 Use '-P 1' to disable this. It is automatically disabled when code coverage is
1071 being used (-T) since they are incompatible.
1077 Sometimes when debugging tests it is useful to keep the input and output
1078 directories so they can be examined later. Use -X or --test-preserve-dirs for
1082 Running tests on non-x86 architectures
1083 --------------------------------------
1085 Binman's tests have been written under the assumption that they'll be run on a
1086 x86-like host and there hasn't been an attempt to make them portable yet.
1087 However, it's possible to run the tests by cross-compiling to x86.
1089 To install an x86 cross-compiler on Debian-type distributions (e.g. Ubuntu)::
1091 $ sudo apt-get install gcc-x86-64-linux-gnu
1093 Then, you can run the tests under cross-compilation::
1095 $ CROSS_COMPILE=x86_64-linux-gnu- binman test -T
1097 You can also use gcc-i686-linux-gnu similar to the above.
1100 Writing new entries and debugging
1101 ---------------------------------
1103 The behaviour of entries is defined by the Entry class. All other entries are
1104 a subclass of this. An important subclass is Entry_blob which takes binary
1105 data from a file and places it in the entry. In fact most entry types are
1106 subclasses of Entry_blob.
1108 Each entry type is a separate file in the tools/binman/etype directory. Each
1109 file contains a class called Entry_<type> where <type> is the entry type.
1110 New entry types can be supported by adding new files in that directory.
1111 These will automatically be detected by binman when needed.
1113 Entry properties are documented in entry.py. The entry subclasses are free
1114 to change the values of properties to support special behaviour. For example,
1115 when Entry_blob loads a file, it sets content_size to the size of the file.
1116 Entry classes can adjust other entries. For example, an entry that knows
1117 where other entries should be positioned can set up those entries' offsets
1118 so they don't need to be set in the binman decription. It can also adjust
1121 Most of the time such essoteric behaviour is not needed, but it can be
1122 essential for complex images.
1124 If you need to specify a particular device-tree compiler to use, you can define
1125 the DTC environment variable. This can be useful when the system dtc is too
1128 To enable a full backtrace and other debugging features in binman, pass
1129 BINMAN_DEBUG=1 to your build::
1131 make qemu-x86_defconfig
1134 To enable verbose logging from binman, base BINMAN_VERBOSE to your build, which
1135 adds a -v<level> option to the call to binman::
1137 make qemu-x86_defconfig
1138 make BINMAN_VERBOSE=5
1141 Building sections in parallel
1142 -----------------------------
1144 By default binman uses multiprocessing to speed up compilation of large images.
1145 This works at a section level, with one thread for each entry in the section.
1146 This can speed things up if the entries are large and use compression.
1148 This feature can be disabled with the '-T' flag, which defaults to a suitable
1149 value for your machine. This depends on the Python version, e.g on v3.8 it uses
1150 12 threads on an 8-core machine. See ConcurrentFutures_ for more details.
1152 The special value -T0 selects single-threaded mode, useful for debugging during
1153 development, since dealing with exceptions and problems in threads is more
1154 difficult. This avoids any use of ThreadPoolExecutor.
1160 Binman takes a lot of inspiration from a Chrome OS tool called
1161 'cros_bundle_firmware', which I wrote some years ago. That tool was based on
1162 a reasonably simple and sound design but has expanded greatly over the
1163 years. In particular its handling of x86 images is convoluted.
1165 Quite a few lessons have been learned which are hopefully applied here.
1171 On the face of it, a tool to create firmware images should be fairly simple:
1172 just find all the input binaries and place them at the right place in the
1173 image. The difficulty comes from the wide variety of input types (simple
1174 flat binaries containing code, packaged data with various headers), packing
1175 requirments (alignment, spacing, device boundaries) and other required
1176 features such as hierarchical images.
1178 The design challenge is to make it easy to create simple images, while
1179 allowing the more complex cases to be supported. For example, for most
1180 images we don't much care exactly where each binary ends up, so we should
1181 not have to specify that unnecessarily.
1183 New entry types should aim to provide simple usage where possible. If new
1184 core features are needed, they can be added in the Entry base class.
1192 - Use of-platdata to make the information available to code that is unable
1193 to use device tree (such as a very small SPL image). For now, limited info is
1194 available via linker symbols
1195 - Allow easy building of images by specifying just the board name
1196 - Support building an image for a board (-b) more completely, with a
1197 configurable build directory
1198 - Detect invalid properties in nodes
1199 - Sort the fdtmap by offset
1200 - Output temporary files to a different directory
1203 Simon Glass <sjg@chromium.org>
1206 .. _ConcurrentFutures: https://docs.python.org/3/library/concurrent.futures.html#concurrent.futures.ThreadPoolExecutor