| Binman Entry Documentation |
| =========================== |
| |
| This file describes the entry types supported by binman. These entry types can |
| be placed in an image one by one to build up a final firmware image. It is |
| fairly easy to create new entry types. Just add a new file to the 'etype' |
| directory. You can use the existing entries as examples. |
| |
| Note that some entries are subclasses of others, using and extending their |
| features to produce new behaviours. |
| |
| |
| |
| .. _etype_atf_bl31: |
| |
| Entry: atf-bl31: ARM Trusted Firmware (ATF) BL31 blob |
| ----------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - atf-bl31-path: Filename of file to read into entry. This is typically |
| called bl31.bin or bl31.elf |
| |
| This entry holds the run-time firmware, typically started by U-Boot SPL. |
| See the U-Boot README for your architecture or board for how to use it. See |
| https://github.com/ARM-software/arm-trusted-firmware for more information |
| about ATF. |
| |
| |
| |
| .. _etype_atf_fip: |
| |
| Entry: atf-fip: ARM Trusted Firmware's Firmware Image Package (FIP) |
| ------------------------------------------------------------------- |
| |
| A FIP_ provides a way to group binaries in a firmware image, used by ARM's |
| Trusted Firmware A (TF-A) code. It is a simple format consisting of a |
| table of contents with information about the type, offset and size of the |
| binaries in the FIP. It is quite similar to FMAP, with the major difference |
| that it uses UUIDs to indicate the type of each entry. |
| |
| Note: It is recommended to always add an fdtmap to every image, as well as |
| any FIPs so that binman and other tools can access the entire image |
| correctly. |
| |
| The UUIDs correspond to useful names in `fiptool`, provided by ATF to |
| operate on FIPs. Binman uses these names to make it easier to understand |
| what is going on, although it is possible to provide a UUID if needed. |
| |
| The contents of the FIP are defined by subnodes of the atf-fip entry, e.g.:: |
| |
| atf-fip { |
| soc-fw { |
| filename = "bl31.bin"; |
| }; |
| |
| scp-fwu-cfg { |
| filename = "bl2u.bin"; |
| }; |
| |
| u-boot { |
| fip-type = "nt-fw"; |
| }; |
| }; |
| |
| This describes a FIP with three entries: soc-fw, scp-fwu-cfg and nt-fw. |
| You can use normal (non-external) binaries like U-Boot simply by adding a |
| FIP type, with the `fip-type` property, as above. |
| |
| Since FIP exists to bring blobs together, Binman assumes that all FIP |
| entries are external binaries. If a binary may not exist, you can use the |
| `--allow-missing` flag to Binman, in which case the image is still created, |
| even though it will not actually work. |
| |
| The size of the FIP depends on the size of the binaries. There is currently |
| no way to specify a fixed size. If the `atf-fip` node has a `size` entry, |
| this affects the space taken up by the `atf-fip` entry, but the FIP itself |
| does not expand to use that space. |
| |
| Some other FIP features are available with Binman. The header and the |
| entries have 64-bit flag works. The flag flags do not seem to be defined |
| anywhere, but you can use `fip-hdr-flags` and fip-flags` to set the values |
| of the header and entries respectively. |
| |
| FIP entries can be aligned to a particular power-of-two boundary. Use |
| fip-align for this. |
| |
| Binman only understands the entry types that are included in its |
| implementation. It is possible to specify a 16-byte UUID instead, using the |
| fip-uuid property. In this case Binman doesn't know what its type is, so |
| just uses the UUID. See the `u-boot` node in this example:: |
| |
| binman { |
| atf-fip { |
| fip-hdr-flags = /bits/ 64 <0x123>; |
| fip-align = <16>; |
| soc-fw { |
| fip-flags = /bits/ 64 <0x456>; |
| filename = "bl31.bin"; |
| }; |
| |
| scp-fwu-cfg { |
| filename = "bl2u.bin"; |
| }; |
| |
| u-boot { |
| fip-uuid = [fc 65 13 92 4a 5b 11 ec |
| 94 35 ff 2d 1c fc 79 9c]; |
| }; |
| }; |
| fdtmap { |
| }; |
| }; |
| |
| Binman allows reading and updating FIP entries after the image is created, |
| provided that an FDPMAP is present too. Updates which change the size of a |
| FIP entry will cause it to be expanded or contracted as needed. |
| |
| Properties for top-level atf-fip node |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| fip-hdr-flags (64 bits) |
| Sets the flags for the FIP header. |
| |
| Properties for subnodes |
| ~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| fip-type (str) |
| FIP type to use for this entry. This is needed if the entry |
| name is not a valid type. Value types are defined in `fip_util.py`. |
| The FIP type defines the UUID that is used (they map 1:1). |
| |
| fip-uuid (16 bytes) |
| If there is no FIP-type name defined, or it is not supported by Binman, |
| this property sets the UUID. It should be a 16-byte value, following the |
| hex digits of the UUID. |
| |
| fip-flags (64 bits) |
| Set the flags for a FIP entry. Use in one of the subnodes of the |
| 7atf-fip entry. |
| |
| fip-align |
| Set the alignment for a FIP entry, FIP entries can be aligned to a |
| particular power-of-two boundary. The default is 1. |
| |
| Adding new FIP-entry types |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| When new FIP entries are defined by TF-A they appear in the |
| `TF-A source tree`_. You can use `fip_util.py` to update Binman to support |
| new types, then `send a patch`_ to the U-Boot mailing list. There are two |
| source files that the tool examples: |
| |
| - `include/tools_share/firmware_image_package.h` has the UUIDs |
| - `tools/fiptool/tbbr_config.c` has the name and descripion for each UUID |
| |
| To run the tool:: |
| |
| $ tools/binman/fip_util.py -s /path/to/arm-trusted-firmware |
| Warning: UUID 'UUID_NON_TRUSTED_WORLD_KEY_CERT' is not mentioned in tbbr_config.c file |
| Existing code in 'tools/binman/fip_util.py' is up-to-date |
| |
| If it shows there is an update, it writes a new version of `fip_util.py` |
| to `fip_util.py.out`. You can change the output file using the `-i` flag. |
| If you have a problem, use `-D` to enable traceback debugging. |
| |
| FIP commentary |
| ~~~~~~~~~~~~~~ |
| |
| As a side effect of use of UUIDs, FIP does not support multiple |
| entries of the same type, such as might be used to store fonts or graphics |
| icons, for example. For verified boot it could be used for each part of the |
| image (e.g. separate FIPs for A and B) but cannot describe the whole |
| firmware image. As with FMAP there is no hierarchy defined, although FMAP |
| works around this by having 'section' areas which encompass others. A |
| similar workaround would be possible with FIP but is not currently defined. |
| |
| It is recommended to always add an fdtmap to every image, as well as any |
| FIPs so that binman and other tools can access the entire image correctly. |
| |
| .. _FIP: https://trustedfirmware-a.readthedocs.io/en/latest/design/firmware-design.html#firmware-image-package-fip |
| .. _`TF-A source tree`: https://git.trustedfirmware.org/TF-A/trusted-firmware-a.git |
| .. _`send a patch`: https://www.denx.de/wiki/U-Boot/Patches |
| |
| |
| |
| .. _etype_blob: |
| |
| Entry: blob: Arbitrary binary blob |
| ---------------------------------- |
| |
| Note: This should not be used by itself. It is normally used as a parent |
| class by other entry types. |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| - compress: Compression algorithm to use: |
| none: No compression |
| lz4: Use lz4 compression (via 'lz4' command-line utility) |
| |
| This entry reads data from a file and places it in the entry. The |
| default filename is often specified specified by the subclass. See for |
| example the 'u-boot' entry which provides the filename 'u-boot.bin'. |
| |
| If compression is enabled, an extra 'uncomp-size' property is written to |
| the node (if enabled with -u) which provides the uncompressed size of the |
| data. |
| |
| |
| |
| .. _etype_blob_dtb: |
| |
| Entry: blob-dtb: A blob that holds a device tree |
| ------------------------------------------------ |
| |
| This is a blob containing a device tree. The contents of the blob are |
| obtained from the list of available device-tree files, managed by the |
| 'state' module. |
| |
| Additional attributes: |
| prepend: Header used (e.g. 'length') |
| |
| |
| |
| .. _etype_blob_ext: |
| |
| Entry: blob-ext: Externally built binary blob |
| --------------------------------------------- |
| |
| Note: This should not be used by itself. It is normally used as a parent |
| class by other entry types. |
| |
| If the file providing this blob is missing, binman can optionally ignore it |
| and produce a broken image with a warning. |
| |
| See 'blob' for Properties / Entry arguments. |
| |
| |
| |
| .. _etype_blob_ext_list: |
| |
| Entry: blob-ext-list: List of externally built binary blobs |
| ----------------------------------------------------------- |
| |
| This is like blob-ext except that a number of blobs can be provided, |
| typically with some sort of relationship, e.g. all are DDC parameters. |
| |
| If any of the external files needed by this llist is missing, binman can |
| optionally ignore it and produce a broken image with a warning. |
| |
| Args: |
| filenames: List of filenames to read and include |
| |
| |
| |
| .. _etype_blob_named_by_arg: |
| |
| Entry: blob-named-by-arg: A blob entry which gets its filename property from its subclass |
| ----------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - <xxx>-path: Filename containing the contents of this entry (optional, |
| defaults to None) |
| |
| where <xxx> is the blob_fname argument to the constructor. |
| |
| This entry cannot be used directly. Instead, it is used as a parent class |
| for another entry, which defined blob_fname. This parameter is used to |
| set the entry-arg or property containing the filename. The entry-arg or |
| property is in turn used to set the actual filename. |
| |
| See cros_ec_rw for an example of this. |
| |
| |
| |
| .. _etype_blob_phase: |
| |
| Entry: blob-phase: Section that holds a phase binary |
| ---------------------------------------------------- |
| |
| This is a base class that should not normally be used directly. It is used |
| when converting a 'u-boot' entry automatically into a 'u-boot-expanded' |
| entry; similarly for SPL. |
| |
| |
| |
| .. _etype_cbfs: |
| |
| Entry: cbfs: Coreboot Filesystem (CBFS) |
| --------------------------------------- |
| |
| A CBFS provides a way to group files into a group. It has a simple directory |
| structure and allows the position of individual files to be set, since it is |
| designed to support execute-in-place in an x86 SPI-flash device. Where XIP |
| is not used, it supports compression and storing ELF files. |
| |
| CBFS is used by coreboot as its way of orgnanising SPI-flash contents. |
| |
| The contents of the CBFS are defined by subnodes of the cbfs entry, e.g.:: |
| |
| cbfs { |
| size = <0x100000>; |
| u-boot { |
| cbfs-type = "raw"; |
| }; |
| u-boot-dtb { |
| cbfs-type = "raw"; |
| }; |
| }; |
| |
| This creates a CBFS 1MB in size two files in it: u-boot.bin and u-boot.dtb. |
| Note that the size is required since binman does not support calculating it. |
| The contents of each entry is just what binman would normally provide if it |
| were not a CBFS node. A blob type can be used to import arbitrary files as |
| with the second subnode below:: |
| |
| cbfs { |
| size = <0x100000>; |
| u-boot { |
| cbfs-name = "BOOT"; |
| cbfs-type = "raw"; |
| }; |
| |
| dtb { |
| type = "blob"; |
| filename = "u-boot.dtb"; |
| cbfs-type = "raw"; |
| cbfs-compress = "lz4"; |
| cbfs-offset = <0x100000>; |
| }; |
| }; |
| |
| This creates a CBFS 1MB in size with u-boot.bin (named "BOOT") and |
| u-boot.dtb (named "dtb") and compressed with the lz4 algorithm. |
| |
| |
| Properties supported in the top-level CBFS node: |
| |
| cbfs-arch: |
| Defaults to "x86", but you can specify the architecture if needed. |
| |
| |
| Properties supported in the CBFS entry subnodes: |
| |
| cbfs-name: |
| This is the name of the file created in CBFS. It defaults to the entry |
| name (which is the node name), but you can override it with this |
| property. |
| |
| cbfs-type: |
| This is the CBFS file type. The following are supported: |
| |
| raw: |
| This is a 'raw' file, although compression is supported. It can be |
| used to store any file in CBFS. |
| |
| stage: |
| This is an ELF file that has been loaded (i.e. mapped to memory), so |
| appears in the CBFS as a flat binary. The input file must be an ELF |
| image, for example this puts "u-boot" (the ELF image) into a 'stage' |
| entry:: |
| |
| cbfs { |
| size = <0x100000>; |
| u-boot-elf { |
| cbfs-name = "BOOT"; |
| cbfs-type = "stage"; |
| }; |
| }; |
| |
| You can use your own ELF file with something like:: |
| |
| cbfs { |
| size = <0x100000>; |
| something { |
| type = "blob"; |
| filename = "cbfs-stage.elf"; |
| cbfs-type = "stage"; |
| }; |
| }; |
| |
| As mentioned, the file is converted to a flat binary, so it is |
| equivalent to adding "u-boot.bin", for example, but with the load and |
| start addresses specified by the ELF. At present there is no option |
| to add a flat binary with a load/start address, similar to the |
| 'add-flat-binary' option in cbfstool. |
| |
| cbfs-offset: |
| This is the offset of the file's data within the CBFS. It is used to |
| specify where the file should be placed in cases where a fixed position |
| is needed. Typical uses are for code which is not relocatable and must |
| execute in-place from a particular address. This works because SPI flash |
| is generally mapped into memory on x86 devices. The file header is |
| placed before this offset so that the data start lines up exactly with |
| the chosen offset. If this property is not provided, then the file is |
| placed in the next available spot. |
| |
| The current implementation supports only a subset of CBFS features. It does |
| not support other file types (e.g. payload), adding multiple files (like the |
| 'files' entry with a pattern supported by binman), putting files at a |
| particular offset in the CBFS and a few other things. |
| |
| Of course binman can create images containing multiple CBFSs, simply by |
| defining these in the binman config:: |
| |
| |
| binman { |
| size = <0x800000>; |
| cbfs { |
| offset = <0x100000>; |
| size = <0x100000>; |
| u-boot { |
| cbfs-type = "raw"; |
| }; |
| u-boot-dtb { |
| cbfs-type = "raw"; |
| }; |
| }; |
| |
| cbfs2 { |
| offset = <0x700000>; |
| size = <0x100000>; |
| u-boot { |
| cbfs-type = "raw"; |
| }; |
| u-boot-dtb { |
| cbfs-type = "raw"; |
| }; |
| image { |
| type = "blob"; |
| filename = "image.jpg"; |
| }; |
| }; |
| }; |
| |
| This creates an 8MB image with two CBFSs, one at offset 1MB, one at 7MB, |
| both of size 1MB. |
| |
| |
| |
| .. _etype_collection: |
| |
| Entry: collection: An entry which contains a collection of other entries |
| ------------------------------------------------------------------------ |
| |
| Properties / Entry arguments: |
| - content: List of phandles to entries to include |
| |
| This allows reusing the contents of other entries. The contents of the |
| listed entries are combined to form this entry. This serves as a useful |
| base class for entry types which need to process data from elsewhere in |
| the image, not necessarily child entries. |
| |
| The entries can generally be anywhere in the same image, even if they are in |
| a different section from this entry. |
| |
| |
| |
| .. _etype_cros_ec_rw: |
| |
| Entry: cros-ec-rw: A blob entry which contains a Chromium OS read-write EC image |
| -------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - cros-ec-rw-path: Filename containing the EC image |
| |
| This entry holds a Chromium OS EC (embedded controller) image, for use in |
| updating the EC on startup via software sync. |
| |
| |
| |
| .. _etype_encrypted: |
| |
| Entry: encrypted: Externally built encrypted binary blob |
| -------------------------------------------------------- |
| |
| This entry provides the functionality to include information about how to |
| decrypt an encrypted binary. This information is added to the |
| resulting device tree by adding a new cipher node in the entry's parent |
| node (i.e. the binary). |
| |
| The key that must be used to decrypt the binary is either directly embedded |
| in the device tree or indirectly by specifying a key source. The key source |
| can be used as an id of a key that is stored in an external device. |
| |
| Using an embedded key |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| This is an example using an embedded key:: |
| |
| blob-ext { |
| filename = "encrypted-blob.bin"; |
| }; |
| |
| encrypted { |
| algo = "aes256-gcm"; |
| iv-filename = "encrypted-blob.bin.iv"; |
| key-filename = "encrypted-blob.bin.key"; |
| }; |
| |
| This entry generates the following device tree structure form the example |
| above:: |
| |
| data = [...] |
| cipher { |
| algo = "aes256-gcm"; |
| key = <0x...>; |
| iv = <0x...>; |
| }; |
| |
| The data property is generated by the blob-ext etype, the cipher node and |
| its content is generated by this etype. |
| |
| Using an external key |
| ~~~~~~~~~~~~~~~~~~~~~ |
| |
| Instead of embedding the key itself into the device tree, it is also |
| possible to address an externally stored key by specifying a 'key-source' |
| instead of the 'key':: |
| |
| blob-ext { |
| filename = "encrypted-blob.bin"; |
| }; |
| |
| encrypted { |
| algo = "aes256-gcm"; |
| iv-filename = "encrypted-blob.bin.iv"; |
| key-source = "external-key-id"; |
| }; |
| |
| This entry generates the following device tree structure form the example |
| above:: |
| |
| data = [...] |
| cipher { |
| algo = "aes256-gcm"; |
| key-source = "external-key-id"; |
| iv = <0x...>; |
| }; |
| |
| Properties |
| ~~~~~~~~~~ |
| |
| Properties / Entry arguments: |
| - algo: The encryption algorithm. Currently no algorithm is supported |
| out-of-the-box. Certain algorithms will be added in future |
| patches. |
| - iv-filename: The name of the file containing the initialization |
| vector (in short iv). See |
| https://en.wikipedia.org/wiki/Initialization_vector |
| - key-filename: The name of the file containing the key. Either |
| key-filename or key-source must be provided. |
| - key-source: The key that should be used. Either key-filename or |
| key-source must be provided. |
| |
| |
| |
| .. _etype_fdtmap: |
| |
| Entry: fdtmap: An entry which contains an FDT map |
| ------------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| An FDT map is just a header followed by an FDT containing a list of all the |
| entries in the image. The root node corresponds to the image node in the |
| original FDT, and an image-name property indicates the image name in that |
| original tree. |
| |
| The header is the string _FDTMAP_ followed by 8 unused bytes. |
| |
| When used, this entry will be populated with an FDT map which reflects the |
| entries in the current image. Hierarchy is preserved, and all offsets and |
| sizes are included. |
| |
| Note that the -u option must be provided to ensure that binman updates the |
| FDT with the position of each entry. |
| |
| Example output for a simple image with U-Boot and an FDT map:: |
| |
| / { |
| image-name = "binman"; |
| size = <0x00000112>; |
| image-pos = <0x00000000>; |
| offset = <0x00000000>; |
| u-boot { |
| size = <0x00000004>; |
| image-pos = <0x00000000>; |
| offset = <0x00000000>; |
| }; |
| fdtmap { |
| size = <0x0000010e>; |
| image-pos = <0x00000004>; |
| offset = <0x00000004>; |
| }; |
| }; |
| |
| If allow-repack is used then 'orig-offset' and 'orig-size' properties are |
| added as necessary. See the binman README. |
| |
| When extracting files, an alternative 'fdt' format is available for fdtmaps. |
| Use `binman extract -F fdt ...` to use this. It will export a devicetree, |
| without the fdtmap header, so it can be viewed with `fdtdump`. |
| |
| |
| |
| .. _etype_files: |
| |
| Entry: files: A set of files arranged in a section |
| -------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - pattern: Filename pattern to match the files to include |
| - files-compress: Compression algorithm to use: |
| none: No compression |
| lz4: Use lz4 compression (via 'lz4' command-line utility) |
| - files-align: Align each file to the given alignment |
| |
| This entry reads a number of files and places each in a separate sub-entry |
| within this entry. To access these you need to enable device-tree updates |
| at run-time so you can obtain the file positions. |
| |
| |
| |
| .. _etype_fill: |
| |
| Entry: fill: An entry which is filled to a particular byte value |
| ---------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - fill-byte: Byte to use to fill the entry |
| |
| Note that the size property must be set since otherwise this entry does not |
| know how large it should be. |
| |
| You can often achieve the same effect using the pad-byte property of the |
| overall image, in that the space between entries will then be padded with |
| that byte. But this entry is sometimes useful for explicitly setting the |
| byte value of a region. |
| |
| |
| |
| .. _etype_fit: |
| |
| Entry: fit: Flat Image Tree (FIT) |
| --------------------------------- |
| |
| This calls mkimage to create a FIT (U-Boot Flat Image Tree) based on the |
| input provided. |
| |
| Nodes for the FIT should be written out in the binman configuration just as |
| they would be in a file passed to mkimage. |
| |
| For example, this creates an image containing a FIT with U-Boot SPL:: |
| |
| binman { |
| fit { |
| description = "Test FIT"; |
| fit,fdt-list = "of-list"; |
| |
| images { |
| kernel@1 { |
| description = "SPL"; |
| os = "u-boot"; |
| type = "rkspi"; |
| arch = "arm"; |
| compression = "none"; |
| load = <0>; |
| entry = <0>; |
| |
| u-boot-spl { |
| }; |
| }; |
| }; |
| }; |
| }; |
| |
| More complex setups can be created, with generated nodes, as described |
| below. |
| |
| Properties (in the 'fit' node itself) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| Special properties have a `fit,` prefix, indicating that they should be |
| processed but not included in the final FIT. |
| |
| The top-level 'fit' node supports the following special properties: |
| |
| fit,external-offset |
| Indicates that the contents of the FIT are external and provides the |
| external offset. This is passed to mkimage via the -E and -p flags. |
| |
| fit,align |
| Indicates what alignment to use for the FIT and its external data, |
| and provides the alignment to use. This is passed to mkimage via |
| the -B flag. |
| |
| fit,fdt-list |
| Indicates the entry argument which provides the list of device tree |
| files for the gen-fdt-nodes operation (as below). This is often |
| `of-list` meaning that `-a of-list="dtb1 dtb2..."` should be passed |
| to binman. |
| |
| fit,fdt-list-val |
| As an alternative to fit,fdt-list the list of device tree files |
| can be provided in this property as a string list, e.g.:: |
| |
| fit,fdt-list-val = "dtb1", "dtb2"; |
| |
| Substitutions |
| ~~~~~~~~~~~~~ |
| |
| Node names and property values support a basic string-substitution feature. |
| Available substitutions for '@' nodes (and property values) are: |
| |
| SEQ: |
| Sequence number of the generated fdt (1, 2, ...) |
| NAME |
| Name of the dtb as provided (i.e. without adding '.dtb') |
| |
| The `default` property, if present, will be automatically set to the name |
| if of configuration whose devicetree matches the `default-dt` entry |
| argument, e.g. with `-a default-dt=sun50i-a64-pine64-lts`. |
| |
| Available substitutions for property values in these nodes are: |
| |
| DEFAULT-SEQ: |
| Sequence number of the default fdt, as provided by the 'default-dt' |
| entry argument |
| |
| Available operations |
| ~~~~~~~~~~~~~~~~~~~~ |
| |
| You can add an operation to an '@' node to indicate which operation is |
| required:: |
| |
| @fdt-SEQ { |
| fit,operation = "gen-fdt-nodes"; |
| ... |
| }; |
| |
| Available operations are: |
| |
| gen-fdt-nodes |
| Generate FDT nodes as above. This is the default if there is no |
| `fit,operation` property. |
| |
| split-elf |
| Split an ELF file into a separate node for each segment. |
| |
| Generating nodes from an FDT list (gen-fdt-nodes) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| U-Boot supports creating fdt and config nodes automatically. To do this, |
| pass an `of-list` property (e.g. `-a of-list=file1 file2`). This tells |
| binman that you want to generates nodes for two files: `file1.dtb` and |
| `file2.dtb`. The `fit,fdt-list` property (see above) indicates that |
| `of-list` should be used. If the property is missing you will get an error. |
| |
| Then add a 'generator node', a node with a name starting with '@':: |
| |
| images { |
| @fdt-SEQ { |
| description = "fdt-NAME"; |
| type = "flat_dt"; |
| compression = "none"; |
| }; |
| }; |
| |
| This tells binman to create nodes `fdt-1` and `fdt-2` for each of your two |
| files. All the properties you specify will be included in the node. This |
| node acts like a template to generate the nodes. The generator node itself |
| does not appear in the output - it is replaced with what binman generates. |
| A 'data' property is created with the contents of the FDT file. |
| |
| You can create config nodes in a similar way:: |
| |
| configurations { |
| default = "@config-DEFAULT-SEQ"; |
| @config-SEQ { |
| description = "NAME"; |
| firmware = "atf"; |
| loadables = "uboot"; |
| fdt = "fdt-SEQ"; |
| }; |
| }; |
| |
| This tells binman to create nodes `config-1` and `config-2`, i.e. a config |
| for each of your two files. |
| |
| Note that if no devicetree files are provided (with '-a of-list' as above) |
| then no nodes will be generated. |
| |
| Generating nodes from an ELF file (split-elf) |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| This uses the node as a template to generate multiple nodes. The following |
| special properties are available: |
| |
| split-elf |
| Split an ELF file into a separate node for each segment. This uses the |
| node as a template to generate multiple nodes. The following special |
| properties are available: |
| |
| fit,load |
| Generates a `load = <...>` property with the load address of the |
| segment |
| |
| fit,entry |
| Generates a `entry = <...>` property with the entry address of the |
| ELF. This is only produced for the first entry |
| |
| fit,data |
| Generates a `data = <...>` property with the contents of the segment |
| |
| fit,firmware |
| Generates a `firmware = <...>` property. Provides a list of possible |
| nodes to be used as the `firmware` property value. The first valid |
| node is picked as the firmware. Any remaining valid nodes is |
| prepended to the `loadable` property generated by `fit,loadables` |
| |
| fit,loadables |
| Generates a `loadable = <...>` property with a list of the generated |
| nodes (including all nodes if this operation is used multiple times) |
| |
| |
| Here is an example showing ATF, TEE and a device tree all combined:: |
| |
| fit { |
| description = "test-desc"; |
| #address-cells = <1>; |
| fit,fdt-list = "of-list"; |
| |
| images { |
| u-boot { |
| description = "U-Boot (64-bit)"; |
| type = "standalone"; |
| os = "U-Boot"; |
| arch = "arm64"; |
| compression = "none"; |
| load = <CONFIG_TEXT_BASE>; |
| u-boot-nodtb { |
| }; |
| }; |
| @fdt-SEQ { |
| description = "fdt-NAME.dtb"; |
| type = "flat_dt"; |
| compression = "none"; |
| }; |
| @atf-SEQ { |
| fit,operation = "split-elf"; |
| description = "ARM Trusted Firmware"; |
| type = "firmware"; |
| arch = "arm64"; |
| os = "arm-trusted-firmware"; |
| compression = "none"; |
| fit,load; |
| fit,entry; |
| fit,data; |
| |
| atf-bl31 { |
| }; |
| hash { |
| algo = "sha256"; |
| }; |
| }; |
| |
| @tee-SEQ { |
| fit,operation = "split-elf"; |
| description = "TEE"; |
| type = "tee"; |
| arch = "arm64"; |
| os = "tee"; |
| compression = "none"; |
| fit,load; |
| fit,entry; |
| fit,data; |
| |
| tee-os { |
| }; |
| hash { |
| algo = "sha256"; |
| }; |
| }; |
| }; |
| |
| configurations { |
| default = "@config-DEFAULT-SEQ"; |
| @config-SEQ { |
| description = "conf-NAME.dtb"; |
| fdt = "fdt-SEQ"; |
| fit,firmware = "atf-1", "u-boot"; |
| fit,loadables; |
| }; |
| }; |
| }; |
| |
| If ATF-BL31 is available, this generates a node for each segment in the |
| ELF file, for example:: |
| |
| images { |
| atf-1 { |
| data = <...contents of first segment...>; |
| data-offset = <0x00000000>; |
| entry = <0x00040000>; |
| load = <0x00040000>; |
| compression = "none"; |
| os = "arm-trusted-firmware"; |
| arch = "arm64"; |
| type = "firmware"; |
| description = "ARM Trusted Firmware"; |
| hash { |
| algo = "sha256"; |
| value = <...hash of first segment...>; |
| }; |
| }; |
| atf-2 { |
| data = <...contents of second segment...>; |
| load = <0xff3b0000>; |
| compression = "none"; |
| os = "arm-trusted-firmware"; |
| arch = "arm64"; |
| type = "firmware"; |
| description = "ARM Trusted Firmware"; |
| hash { |
| algo = "sha256"; |
| value = <...hash of second segment...>; |
| }; |
| }; |
| }; |
| |
| The same applies for OP-TEE if that is available. |
| |
| If each binary is not available, the relevant template node (@atf-SEQ or |
| @tee-SEQ) is removed from the output. |
| |
| This also generates a `config-xxx` node for each device tree in `of-list`. |
| Note that the U-Boot build system uses `-a of-list=$(CONFIG_OF_LIST)` |
| so you can use `CONFIG_OF_LIST` to define that list. In this example it is |
| set up for `firefly-rk3399` with a single device tree and the default set |
| with `-a default-dt=$(CONFIG_DEFAULT_DEVICE_TREE)`, so the resulting output |
| is:: |
| |
| configurations { |
| default = "config-1"; |
| config-1 { |
| loadables = "u-boot", "atf-2", "atf-3", "tee-1", "tee-2"; |
| description = "rk3399-firefly.dtb"; |
| fdt = "fdt-1"; |
| firmware = "atf-1"; |
| }; |
| }; |
| |
| U-Boot SPL can then load the firmware (ATF) and all the loadables (U-Boot |
| proper, ATF and TEE), then proceed with the boot. |
| |
| |
| |
| .. _etype_fmap: |
| |
| Entry: fmap: An entry which contains an Fmap section |
| ---------------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| FMAP is a simple format used by flashrom, an open-source utility for |
| reading and writing the SPI flash, typically on x86 CPUs. The format |
| provides flashrom with a list of areas, so it knows what it in the flash. |
| It can then read or write just a single area, instead of the whole flash. |
| |
| The format is defined by the flashrom project, in the file lib/fmap.h - |
| see www.flashrom.org/Flashrom for more information. |
| |
| When used, this entry will be populated with an FMAP which reflects the |
| entries in the current image. Note that any hierarchy is squashed, since |
| FMAP does not support this. Sections are represented as an area appearing |
| before its contents, so that it is possible to reconstruct the hierarchy |
| from the FMAP by using the offset information. This convention does not |
| seem to be documented, but is used in Chromium OS. |
| |
| To mark an area as preserved, use the normal 'preserved' flag in the entry. |
| This will result in the corresponding FMAP area having the |
| FMAP_AREA_PRESERVE flag. This flag does not automatically propagate down to |
| child entries. |
| |
| CBFS entries appear as a single entry, i.e. the sub-entries are ignored. |
| |
| |
| |
| .. _etype_gbb: |
| |
| Entry: gbb: An entry which contains a Chromium OS Google Binary Block |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - hardware-id: Hardware ID to use for this build (a string) |
| - keydir: Directory containing the public keys to use |
| - bmpblk: Filename containing images used by recovery |
| |
| Chromium OS uses a GBB to store various pieces of information, in particular |
| the root and recovery keys that are used to verify the boot process. Some |
| more details are here: |
| |
| https://www.chromium.org/chromium-os/firmware-porting-guide/2-concepts |
| |
| but note that the page dates from 2013 so is quite out of date. See |
| README.chromium for how to obtain the required keys and tools. |
| |
| |
| |
| .. _etype_image_header: |
| |
| Entry: image-header: An entry which contains a pointer to the FDT map |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| location: Location of header ("start" or "end" of image). This is |
| optional. If omitted then the entry must have an offset property. |
| |
| This adds an 8-byte entry to the start or end of the image, pointing to the |
| location of the FDT map. The format is a magic number followed by an offset |
| from the start or end of the image, in twos-compliment format. |
| |
| This entry must be in the top-level part of the image. |
| |
| NOTE: If the location is at the start/end, you will probably need to specify |
| sort-by-offset for the image, unless you actually put the image header |
| first/last in the entry list. |
| |
| |
| |
| .. _etype_intel_cmc: |
| |
| Entry: intel-cmc: Intel Chipset Micro Code (CMC) file |
| ----------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains microcode for some devices in a special format. An |
| example filename is 'Microcode/C0_22211.BIN'. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_descriptor: |
| |
| Entry: intel-descriptor: Intel flash descriptor block (4KB) |
| ----------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| filename: Filename of file containing the descriptor. This is typically |
| a 4KB binary file, sometimes called 'descriptor.bin' |
| |
| This entry is placed at the start of flash and provides information about |
| the SPI flash regions. In particular it provides the base address and |
| size of the ME (Management Engine) region, allowing us to place the ME |
| binary in the right place. |
| |
| With this entry in your image, the position of the 'intel-me' entry will be |
| fixed in the image, which avoids you needed to specify an offset for that |
| region. This is useful, because it is not possible to change the position |
| of the ME region without updating the descriptor. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_fit: |
| |
| Entry: intel-fit: Intel Firmware Image Table (FIT) |
| -------------------------------------------------- |
| |
| This entry contains a dummy FIT as required by recent Intel CPUs. The FIT |
| contains information about the firmware and microcode available in the |
| image. |
| |
| At present binman only supports a basic FIT with no microcode. |
| |
| |
| |
| .. _etype_intel_fit_ptr: |
| |
| Entry: intel-fit-ptr: Intel Firmware Image Table (FIT) pointer |
| -------------------------------------------------------------- |
| |
| This entry contains a pointer to the FIT. It is required to be at address |
| 0xffffffc0 in the image. |
| |
| |
| |
| .. _etype_intel_fsp: |
| |
| Entry: intel-fsp: Intel Firmware Support Package (FSP) file |
| ----------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains binary blobs which are used on some devices to make the |
| platform work. U-Boot executes this code since it is not possible to set up |
| the hardware using U-Boot open-source code. Documentation is typically not |
| available in sufficient detail to allow this. |
| |
| An example filename is 'FSP/QUEENSBAY_FSP_GOLD_001_20-DECEMBER-2013.fd' |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_fsp_m: |
| |
| Entry: intel-fsp-m: Intel Firmware Support Package (FSP) memory init |
| -------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains a binary blob which is used on some devices to set up |
| SDRAM. U-Boot executes this code in SPL so that it can make full use of |
| memory. Documentation is typically not available in sufficient detail to |
| allow U-Boot do this this itself.. |
| |
| An example filename is 'fsp_m.bin' |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_fsp_s: |
| |
| Entry: intel-fsp-s: Intel Firmware Support Package (FSP) silicon init |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains a binary blob which is used on some devices to set up |
| the silicon. U-Boot executes this code in U-Boot proper after SDRAM is |
| running, so that it can make full use of memory. Documentation is typically |
| not available in sufficient detail to allow U-Boot do this this itself. |
| |
| An example filename is 'fsp_s.bin' |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_fsp_t: |
| |
| Entry: intel-fsp-t: Intel Firmware Support Package (FSP) temp ram init |
| ---------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains a binary blob which is used on some devices to set up |
| temporary memory (Cache-as-RAM or CAR). U-Boot executes this code in TPL so |
| that it has access to memory for its stack and initial storage. |
| |
| An example filename is 'fsp_t.bin' |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_ifwi: |
| |
| Entry: intel-ifwi: Intel Integrated Firmware Image (IFWI) file |
| -------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry. This is either the |
| IFWI file itself, or a file that can be converted into one using a |
| tool |
| - convert-fit: If present this indicates that the ifwitool should be |
| used to convert the provided file into a IFWI. |
| |
| This file contains code and data used by the SoC that is required to make |
| it work. It includes U-Boot TPL, microcode, things related to the CSE |
| (Converged Security Engine, the microcontroller that loads all the firmware) |
| and other items beyond the wit of man. |
| |
| A typical filename is 'ifwi.bin' for an IFWI file, or 'fitimage.bin' for a |
| file that will be converted to an IFWI. |
| |
| The position of this entry is generally set by the intel-descriptor entry. |
| |
| The contents of the IFWI are specified by the subnodes of the IFWI node. |
| Each subnode describes an entry which is placed into the IFWFI with a given |
| sub-partition (and optional entry name). |
| |
| Properties for subnodes: |
| - ifwi-subpart: sub-parition to put this entry into, e.g. "IBBP" |
| - ifwi-entry: entry name t use, e.g. "IBBL" |
| - ifwi-replace: if present, indicates that the item should be replaced |
| in the IFWI. Otherwise it is added. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_me: |
| |
| Entry: intel-me: Intel Management Engine (ME) file |
| -------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains code used by the SoC that is required to make it work. |
| The Management Engine is like a background task that runs things that are |
| not clearly documented, but may include keyboard, display and network |
| access. For platform that use ME it is not possible to disable it. U-Boot |
| does not directly execute code in the ME binary. |
| |
| A typical filename is 'me.bin'. |
| |
| The position of this entry is generally set by the intel-descriptor entry. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_mrc: |
| |
| Entry: intel-mrc: Intel Memory Reference Code (MRC) file |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains code for setting up the SDRAM on some Intel systems. This |
| is executed by U-Boot when needed early during startup. A typical filename |
| is 'mrc.bin'. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_refcode: |
| |
| Entry: intel-refcode: Intel Reference Code file |
| ----------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains code for setting up the platform on some Intel systems. |
| This is executed by U-Boot when needed early during startup. A typical |
| filename is 'refcode.bin'. |
| |
| See README.x86 for information about x86 binary blobs. |
| |
| |
| |
| .. _etype_intel_vbt: |
| |
| Entry: intel-vbt: Intel Video BIOS Table (VBT) file |
| --------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains code that sets up the integrated graphics subsystem on |
| some Intel SoCs. U-Boot executes this when the display is started up. |
| |
| See README.x86 for information about Intel binary blobs. |
| |
| |
| |
| .. _etype_intel_vga: |
| |
| Entry: intel-vga: Intel Video Graphics Adaptor (VGA) file |
| --------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of file to read into entry |
| |
| This file contains code that sets up the integrated graphics subsystem on |
| some Intel SoCs. U-Boot executes this when the display is started up. |
| |
| This is similar to the VBT file but in a different format. |
| |
| See README.x86 for information about Intel binary blobs. |
| |
| |
| |
| .. _etype_mkimage: |
| |
| Entry: mkimage: Binary produced by mkimage |
| ------------------------------------------ |
| |
| Properties / Entry arguments: |
| - args: Arguments to pass |
| - data-to-imagename: Indicates that the -d data should be passed in as |
| the image name also (-n) |
| - multiple-data-files: boolean to tell binman to pass all files as |
| datafiles to mkimage instead of creating a temporary file the result |
| of datafiles concatenation |
| - filename: filename of output binary generated by mkimage |
| |
| The data passed to mkimage via the -d flag is collected from subnodes of the |
| mkimage node, e.g.:: |
| |
| mkimage { |
| filename = "imximage.bin"; |
| args = "-n test -T imximage"; |
| |
| u-boot-spl { |
| }; |
| }; |
| |
| This calls mkimage to create an imximage with `u-boot-spl.bin` as the data |
| file, with mkimage being called like this:: |
| |
| mkimage -d <data_file> -n test -T imximage <output_file> |
| |
| The output from mkimage then becomes part of the image produced by |
| binman but also is written into `imximage.bin` file. If you need to put |
| multiple things in the data file, you can use a section, or just multiple |
| subnodes like this:: |
| |
| mkimage { |
| args = "-n test -T imximage"; |
| |
| u-boot-spl { |
| }; |
| |
| u-boot-tpl { |
| }; |
| }; |
| |
| Note that binman places the contents (here SPL and TPL) into a single file |
| and passes that to mkimage using the -d option. |
| |
| To pass all datafiles untouched to mkimage:: |
| |
| mkimage { |
| args = "-n rk3399 -T rkspi"; |
| multiple-data-files; |
| |
| u-boot-tpl { |
| }; |
| |
| u-boot-spl { |
| }; |
| }; |
| |
| This calls mkimage to create a Rockchip RK3399-specific first stage |
| bootloader, made of TPL+SPL. Since this first stage bootloader requires to |
| align the TPL and SPL but also some weird hacks that is handled by mkimage |
| directly, binman is told to not perform the concatenation of datafiles prior |
| to passing the data to mkimage. |
| |
| To use CONFIG options in the arguments, use a string list instead, as in |
| this example which also produces four arguments:: |
| |
| mkimage { |
| args = "-n", CONFIG_SYS_SOC, "-T imximage"; |
| |
| u-boot-spl { |
| }; |
| }; |
| |
| If you need to pass the input data in with the -n argument as well, then use |
| the 'data-to-imagename' property:: |
| |
| mkimage { |
| args = "-T imximage"; |
| data-to-imagename; |
| |
| u-boot-spl { |
| }; |
| }; |
| |
| That will pass the data to mkimage both as the data file (with -d) and as |
| the image name (with -n). In both cases, a filename is passed as the |
| argument, with the actual data being in that file. |
| |
| If need to pass different data in with -n, then use an `imagename` subnode:: |
| |
| mkimage { |
| args = "-T imximage"; |
| |
| imagename { |
| blob { |
| filename = "spl/u-boot-spl.cfgout" |
| }; |
| }; |
| |
| u-boot-spl { |
| }; |
| }; |
| |
| This will pass in u-boot-spl as the input data and the .cfgout file as the |
| -n data. |
| |
| |
| |
| .. _etype_null: |
| |
| Entry: null: An entry which has no contents of its own |
| ------------------------------------------------------ |
| |
| Note that the size property must be set since otherwise this entry does not |
| know how large it should be. |
| |
| The contents are set by the containing section, e.g. the section's pad |
| byte. |
| |
| |
| |
| .. _etype_opensbi: |
| |
| Entry: opensbi: RISC-V OpenSBI fw_dynamic blob |
| ---------------------------------------------- |
| |
| Properties / Entry arguments: |
| - opensbi-path: Filename of file to read into entry. This is typically |
| called fw_dynamic.bin |
| |
| This entry holds the run-time firmware, typically started by U-Boot SPL. |
| See the U-Boot README for your architecture or board for how to use it. See |
| https://github.com/riscv/opensbi for more information about OpenSBI. |
| |
| |
| |
| .. _etype_powerpc_mpc85xx_bootpg_resetvec: |
| |
| Entry: powerpc-mpc85xx-bootpg-resetvec: PowerPC mpc85xx bootpg + resetvec code for U-Boot |
| ----------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-br.bin (default 'u-boot-br.bin') |
| |
| This entry is valid for PowerPC mpc85xx cpus. This entry holds |
| 'bootpg + resetvec' code for PowerPC mpc85xx CPUs which needs to be |
| placed at offset 'RESET_VECTOR_ADDRESS - 0xffc'. |
| |
| |
| |
| .. _etype_pre_load: |
| |
| Entry: pre-load: Pre load image header |
| -------------------------------------- |
| |
| Properties / Entry arguments: |
| - pre-load-key-path: Path of the directory that store key (provided by |
| the environment variable PRE_LOAD_KEY_PATH) |
| - content: List of phandles to entries to sign |
| - algo-name: Hash and signature algo to use for the signature |
| - padding-name: Name of the padding (pkcs-1.5 or pss) |
| - key-name: Filename of the private key to sign |
| - header-size: Total size of the header |
| - version: Version of the header |
| |
| This entry creates a pre-load header that contains a global |
| image signature. |
| |
| For example, this creates an image with a pre-load header and a binary:: |
| |
| binman { |
| image2 { |
| filename = "sandbox.bin"; |
| |
| pre-load { |
| content = <&image>; |
| algo-name = "sha256,rsa2048"; |
| padding-name = "pss"; |
| key-name = "private.pem"; |
| header-size = <4096>; |
| version = <1>; |
| }; |
| |
| image: blob-ext { |
| filename = "sandbox.itb"; |
| }; |
| }; |
| }; |
| |
| |
| |
| .. _etype_rockchip_tpl: |
| |
| Entry: rockchip-tpl: Rockchip TPL binary |
| ---------------------------------------- |
| |
| Properties / Entry arguments: |
| - rockchip-tpl-path: Filename of file to read into the entry, |
| typically <soc>_ddr_<version>.bin |
| |
| This entry holds an external TPL binary used by some Rockchip SoCs |
| instead of normal U-Boot TPL, typically to initialize DRAM. |
| |
| |
| |
| .. _etype_scp: |
| |
| Entry: scp: System Control Processor (SCP) firmware blob |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - scp-path: Filename of file to read into the entry, typically scp.bin |
| |
| This entry holds firmware for an external platform-specific coprocessor. |
| |
| |
| |
| .. _etype_section: |
| |
| Entry: section: Entry that contains other entries |
| ------------------------------------------------- |
| |
| A section is an entry which can contain other entries, thus allowing |
| hierarchical images to be created. See 'Sections and hierarchical images' |
| in the binman README for more information. |
| |
| The base implementation simply joins the various entries together, using |
| various rules about alignment, etc. |
| |
| Subclassing |
| ~~~~~~~~~~~ |
| |
| This class can be subclassed to support other file formats which hold |
| multiple entries, such as CBFS. To do this, override the following |
| functions. The documentation here describes what your function should do. |
| For example code, see etypes which subclass `Entry_section`, or `cbfs.py` |
| for a more involved example:: |
| |
| $ grep -l \(Entry_section tools/binman/etype/*.py |
| |
| ReadNode() |
| Call `super().ReadNode()`, then read any special properties for the |
| section. Then call `self.ReadEntries()` to read the entries. |
| |
| Binman calls this at the start when reading the image description. |
| |
| ReadEntries() |
| Read in the subnodes of the section. This may involve creating entries |
| of a particular etype automatically, as well as reading any special |
| properties in the entries. For each entry, entry.ReadNode() should be |
| called, to read the basic entry properties. The properties should be |
| added to `self._entries[]`, in the correct order, with a suitable name. |
| |
| Binman calls this at the start when reading the image description. |
| |
| BuildSectionData(required) |
| Create the custom file format that you want and return it as bytes. |
| This likely sets up a file header, then loops through the entries, |
| adding them to the file. For each entry, call `entry.GetData()` to |
| obtain the data. If that returns None, and `required` is False, then |
| this method must give up and return None. But if `required` is True then |
| it should assume that all data is valid. |
| |
| Binman calls this when packing the image, to find out the size of |
| everything. It is called again at the end when building the final image. |
| |
| SetImagePos(image_pos): |
| Call `super().SetImagePos(image_pos)`, then set the `image_pos` values |
| for each of the entries. This should use the custom file format to find |
| the `start offset` (and `image_pos`) of each entry. If the file format |
| uses compression in such a way that there is no offset available (other |
| than reading the whole file and decompressing it), then the offsets for |
| affected entries can remain unset (`None`). The size should also be set |
| if possible. |
| |
| Binman calls this after the image has been packed, to update the |
| location that all the entries ended up at. |
| |
| ReadChildData(child, decomp, alt_format): |
| The default version of this may be good enough, if you are able to |
| implement SetImagePos() correctly. But that is a bit of a bypass, so |
| you can override this method to read from your custom file format. It |
| should read the entire entry containing the custom file using |
| `super().ReadData(True)`, then parse the file to get the data for the |
| given child, then return that data. |
| |
| If your file format supports compression, the `decomp` argument tells |
| you whether to return the compressed data (`decomp` is False) or to |
| uncompress it first, then return the uncompressed data (`decomp` is |
| True). This is used by the `binman extract -U` option. |
| |
| If your entry supports alternative formats, the alt_format provides the |
| alternative format that the user has selected. Your function should |
| return data in that format. This is used by the 'binman extract -l' |
| option. |
| |
| Binman calls this when reading in an image, in order to populate all the |
| entries with the data from that image (`binman ls`). |
| |
| WriteChildData(child): |
| Binman calls this after `child.data` is updated, to inform the custom |
| file format about this, in case it needs to do updates. |
| |
| The default version of this does nothing and probably needs to be |
| overridden for the 'binman replace' command to work. Your version should |
| use `child.data` to update the data for that child in the custom file |
| format. |
| |
| Binman calls this when updating an image that has been read in and in |
| particular to update the data for a particular entry (`binman replace`) |
| |
| Properties / Entry arguments |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| See :ref:`develop/package/binman:Image description format` for more |
| information. |
| |
| align-default |
| Default alignment for this section, if no alignment is given in the |
| entry |
| |
| pad-byte |
| Pad byte to use when padding |
| |
| sort-by-offset |
| True if entries should be sorted by offset, False if they must be |
| in-order in the device tree description |
| |
| end-at-4gb |
| Used to build an x86 ROM which ends at 4GB (2^32) |
| |
| name-prefix |
| Adds a prefix to the name of every entry in the section when writing out |
| the map |
| |
| skip-at-start |
| Number of bytes before the first entry starts. These effectively adjust |
| the starting offset of entries. For example, if this is 16, then the |
| first entry would start at 16. An entry with offset = 20 would in fact |
| be written at offset 4 in the image file, since the first 16 bytes are |
| skipped when writing. |
| |
| filename |
| filename to write the unpadded section contents to within the output |
| directory (None to skip this). |
| |
| Since a section is also an entry, it inherits all the properies of entries |
| too. |
| |
| Note that the `allow_missing` member controls whether this section permits |
| external blobs to be missing their contents. The option will produce an |
| image but of course it will not work. It is useful to make sure that |
| Continuous Integration systems can build without the binaries being |
| available. This is set by the `SetAllowMissing()` method, if |
| `--allow-missing` is passed to binman. |
| |
| |
| |
| .. _etype_tee_os: |
| |
| Entry: tee-os: Entry containing an OP-TEE Trusted OS (TEE) blob |
| --------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - tee-os-path: Filename of file to read into entry. This is typically |
| called tee.bin or tee.elf |
| |
| This entry holds the run-time firmware, typically started by U-Boot SPL. |
| See the U-Boot README for your architecture or board for how to use it. See |
| https://github.com/OP-TEE/optee_os for more information about OP-TEE. |
| |
| Note that if the file is in ELF format, it must go in a FIT. In that case, |
| this entry will mark itself as absent, providing the data only through the |
| read_elf_segments() method. |
| |
| Marking this entry as absent means that it if is used in the wrong context |
| it can be automatically dropped. Thus it is possible to add an OP-TEE entry |
| like this:: |
| |
| binman { |
| tee-os { |
| }; |
| }; |
| |
| and pass either an ELF or plain binary in with -a tee-os-path <filename> |
| and have binman do the right thing: |
| |
| - include the entry if tee.bin is provided and it does NOT have the v1 |
| header |
| - drop it otherwise |
| |
| When used within a FIT, we can do:: |
| |
| binman { |
| fit { |
| tee-os { |
| }; |
| }; |
| }; |
| |
| which will split the ELF into separate nodes for each segment, if an ELF |
| file is provided (see :ref:`etype_fit`), or produce a single node if the |
| OP-TEE binary v1 format is provided (see optee_doc_) . |
| |
| .. _optee_doc: https://optee.readthedocs.io/en/latest/architecture/core.html#partitioning-of-the-binary |
| |
| |
| |
| .. _etype_text: |
| |
| Entry: text: An entry which contains text |
| ----------------------------------------- |
| |
| The text can be provided either in the node itself or by a command-line |
| argument. There is a level of indirection to allow multiple text strings |
| and sharing of text. |
| |
| Properties / Entry arguments: |
| text-label: The value of this string indicates the property / entry-arg |
| that contains the string to place in the entry |
| <xxx> (actual name is the value of text-label): contains the string to |
| place in the entry. |
| <text>: The text to place in the entry (overrides the above mechanism). |
| This is useful when the text is constant. |
| |
| Example node:: |
| |
| text { |
| size = <50>; |
| text-label = "message"; |
| }; |
| |
| You can then use: |
| |
| binman -amessage="this is my message" |
| |
| and binman will insert that string into the entry. |
| |
| It is also possible to put the string directly in the node:: |
| |
| text { |
| size = <8>; |
| text-label = "message"; |
| message = "a message directly in the node" |
| }; |
| |
| or just:: |
| |
| text { |
| size = <8>; |
| text = "some text directly in the node" |
| }; |
| |
| The text is not itself nul-terminated. This can be achieved, if required, |
| by setting the size of the entry to something larger than the text. |
| |
| |
| |
| .. _etype_ti_board_config: |
| |
| Entry: ti-board-config: An entry containing a TI schema validated board config binary |
| ------------------------------------------------------------------------------------- |
| |
| This etype supports generation of two kinds of board configuration |
| binaries: singular board config binary as well as combined board config |
| binary. |
| |
| Properties / Entry arguments: |
| - config-file: File containing board configuration data in YAML |
| - schema-file: File containing board configuration YAML schema against |
| which the config file is validated |
| |
| Output files: |
| - board config binary: File containing board configuration binary |
| |
| These above parameters are used only when the generated binary is |
| intended to be a single board configuration binary. Example:: |
| |
| my-ti-board-config { |
| ti-board-config { |
| config = "board-config.yaml"; |
| schema = "schema.yaml"; |
| }; |
| }; |
| |
| To generate a combined board configuration binary, we pack the |
| needed individual binaries into a ti-board-config binary. In this case, |
| the available supported subnode names are board-cfg, pm-cfg, sec-cfg and |
| rm-cfg. The final binary is prepended with a header containing details about |
| the included board config binaries. Example:: |
| |
| my-combined-ti-board-config { |
| ti-board-config { |
| board-cfg { |
| config = "board-cfg.yaml"; |
| schema = "schema.yaml"; |
| }; |
| sec-cfg { |
| config = "sec-cfg.yaml"; |
| schema = "schema.yaml"; |
| }; |
| } |
| } |
| |
| |
| |
| .. _etype_ti_secure: |
| |
| Entry: ti-secure: Entry containing a TI x509 certificate binary |
| --------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - content: List of phandles to entries to sign |
| - keyfile: Filename of file containing key to sign binary with |
| - sha: Hash function to be used for signing |
| |
| Output files: |
| - input.<unique_name> - input file passed to openssl |
| - config.<unique_name> - input file generated for openssl (which is |
| used as the config file) |
| - cert.<unique_name> - output file generated by openssl (which is |
| used as the entry contents) |
| |
| openssl signs the provided data, using the TI templated config file and |
| writes the signature in this entry. This allows verification that the |
| data is genuine. |
| |
| |
| |
| .. _etype_ti_secure_rom: |
| |
| Entry: ti-secure-rom: Entry containing a TI x509 certificate binary for images booted by ROM |
| -------------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - keyfile: Filename of file containing key to sign binary with |
| - combined: boolean if device follows combined boot flow |
| - countersign: boolean if device contains countersigned system firmware |
| - load: load address of SPL |
| - sw-rev: software revision |
| - sha: Hash function to be used for signing |
| - core: core on which bootloader runs, valid cores are 'secure' and 'public' |
| - content: phandle of SPL in case of legacy bootflow or phandles of component binaries |
| in case of combined bootflow |
| |
| The following properties are only for generating a combined bootflow binary: |
| - sysfw-inner-cert: boolean if binary contains sysfw inner certificate |
| - dm-data: boolean if binary contains dm-data binary |
| - content-sbl: phandle of SPL binary |
| - content-sysfw: phandle of sysfw binary |
| - content-sysfw-data: phandle of sysfw-data or tifs-data binary |
| - content-sysfw-inner-cert (optional): phandle of sysfw inner certificate binary |
| - content-dm-data (optional): phandle of dm-data binary |
| - load-sysfw: load address of sysfw binary |
| - load-sysfw-data: load address of sysfw-data or tifs-data binary |
| - load-sysfw-inner-cert (optional): load address of sysfw inner certificate binary |
| - load-dm-data (optional): load address of dm-data binary |
| |
| Output files: |
| - input.<unique_name> - input file passed to openssl |
| - config.<unique_name> - input file generated for openssl (which is |
| used as the config file) |
| - cert.<unique_name> - output file generated by openssl (which is |
| used as the entry contents) |
| |
| openssl signs the provided data, using the TI templated config file and |
| writes the signature in this entry. This allows verification that the |
| data is genuine. |
| |
| |
| |
| .. _etype_u_boot: |
| |
| Entry: u-boot: U-Boot flat binary |
| --------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.bin (default 'u-boot.bin') |
| |
| This is the U-Boot binary, containing relocation information to allow it |
| to relocate itself at runtime. The binary typically includes a device tree |
| blob at the end of it. |
| |
| U-Boot can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| Note that this entry is automatically replaced with u-boot-expanded unless |
| --no-expanded is used or the node has a 'no-expanded' property. |
| |
| |
| |
| .. _etype_u_boot_dtb: |
| |
| Entry: u-boot-dtb: U-Boot device tree |
| ------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.dtb (default 'u-boot.dtb') |
| |
| This is the U-Boot device tree, containing configuration information for |
| U-Boot. U-Boot needs this to know what devices are present and which drivers |
| to activate. |
| |
| Note: This is mostly an internal entry type, used by others. This allows |
| binman to know which entries contain a device tree. |
| |
| |
| |
| .. _etype_u_boot_dtb_with_ucode: |
| |
| Entry: u-boot-dtb-with-ucode: A U-Boot device tree file, with the microcode removed |
| ----------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.dtb (default 'u-boot.dtb') |
| |
| See Entry_u_boot_ucode for full details of the three entries involved in |
| this process. This entry provides the U-Boot device-tree file, which |
| contains the microcode. If the microcode is not being collated into one |
| place then the offset and size of the microcode is recorded by this entry, |
| for use by u-boot-with-ucode_ptr. If it is being collated, then this |
| entry deletes the microcode from the device tree (to save space) and makes |
| it available to u-boot-ucode. |
| |
| |
| |
| .. _etype_u_boot_elf: |
| |
| Entry: u-boot-elf: U-Boot ELF image |
| ----------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot (default 'u-boot') |
| |
| This is the U-Boot ELF image. It does not include a device tree but can be |
| relocated to any address for execution. |
| |
| |
| |
| .. _etype_u_boot_env: |
| |
| Entry: u-boot-env: An entry which contains a U-Boot environment |
| --------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: File containing the environment text, with each line in the |
| form var=value |
| |
| |
| |
| .. _etype_u_boot_expanded: |
| |
| Entry: u-boot-expanded: U-Boot flat binary broken out into its component parts |
| ------------------------------------------------------------------------------ |
| |
| This is a section containing the U-Boot binary and a devicetree. Using this |
| entry type automatically creates this section, with the following entries |
| in it: |
| |
| u-boot-nodtb |
| u-boot-dtb |
| |
| Having the devicetree separate allows binman to update it in the final |
| image, so that the entries positions are provided to the running U-Boot. |
| |
| |
| |
| .. _etype_u_boot_img: |
| |
| Entry: u-boot-img: U-Boot legacy image |
| -------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.img (default 'u-boot.img') |
| |
| This is the U-Boot binary as a packaged image, in legacy format. It has a |
| header which allows it to be loaded at the correct address for execution. |
| |
| You should use FIT (Flat Image Tree) instead of the legacy image for new |
| applications. |
| |
| |
| |
| .. _etype_u_boot_nodtb: |
| |
| Entry: u-boot-nodtb: U-Boot flat binary without device tree appended |
| -------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename to include (default 'u-boot-nodtb.bin') |
| |
| This is the U-Boot binary, containing relocation information to allow it |
| to relocate itself at runtime. It does not include a device tree blob at |
| the end of it so normally cannot work without it. You can add a u-boot-dtb |
| entry after this one, or use a u-boot entry instead, normally expands to a |
| section containing u-boot and u-boot-dtb |
| |
| |
| |
| .. _etype_u_boot_spl: |
| |
| Entry: u-boot-spl: U-Boot SPL binary |
| ------------------------------------ |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-spl.bin (default 'spl/u-boot-spl.bin') |
| |
| This is the U-Boot SPL (Secondary Program Loader) binary. This is a small |
| binary which loads before U-Boot proper, typically into on-chip SRAM. It is |
| responsible for locating, loading and jumping to U-Boot. Note that SPL is |
| not relocatable so must be loaded to the correct address in SRAM, or written |
| to run from the correct address if direct flash execution is possible (e.g. |
| on x86 devices). |
| |
| SPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| in the binman README for more information. |
| |
| The ELF file 'spl/u-boot-spl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the SPL binary. |
| |
| Note that this entry is automatically replaced with u-boot-spl-expanded |
| unless --no-expanded is used or the node has a 'no-expanded' property. |
| |
| |
| |
| .. _etype_u_boot_spl_bss_pad: |
| |
| Entry: u-boot-spl-bss-pad: U-Boot SPL binary padded with a BSS region |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| This holds the padding added after the SPL binary to cover the BSS (Block |
| Started by Symbol) region. This region holds the various variables used by |
| SPL. It is set to 0 by SPL when it starts up. If you want to append data to |
| the SPL image (such as a device tree file), you must pad out the BSS region |
| to avoid the data overlapping with U-Boot variables. This entry is useful in |
| that case. It automatically pads out the entry size to cover both the code, |
| data and BSS. |
| |
| The contents of this entry will a certain number of zero bytes, determined |
| by __bss_size |
| |
| The ELF file 'spl/u-boot-spl' must also be available for this to work, since |
| binman uses that to look up the BSS address. |
| |
| |
| |
| .. _etype_u_boot_spl_dtb: |
| |
| Entry: u-boot-spl-dtb: U-Boot SPL device tree |
| --------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.dtb (default 'spl/u-boot-spl.dtb') |
| |
| This is the SPL device tree, containing configuration information for |
| SPL. SPL needs this to know what devices are present and which drivers |
| to activate. |
| |
| |
| |
| .. _etype_u_boot_spl_elf: |
| |
| Entry: u-boot-spl-elf: U-Boot SPL ELF image |
| ------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of SPL u-boot (default 'spl/u-boot-spl') |
| |
| This is the U-Boot SPL ELF image. It does not include a device tree but can |
| be relocated to any address for execution. |
| |
| |
| |
| .. _etype_u_boot_spl_expanded: |
| |
| Entry: u-boot-spl-expanded: U-Boot SPL flat binary broken out into its component parts |
| -------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - spl-dtb: Controls whether this entry is selected (set to 'y' or '1' to |
| select) |
| |
| This is a section containing the U-Boot binary, BSS padding if needed and a |
| devicetree. Using this entry type automatically creates this section, with |
| the following entries in it: |
| |
| u-boot-spl-nodtb |
| u-boot-spl-bss-pad |
| u-boot-dtb |
| |
| Having the devicetree separate allows binman to update it in the final |
| image, so that the entries positions are provided to the running U-Boot. |
| |
| This entry is selected based on the value of the 'spl-dtb' entryarg. If |
| this is non-empty (and not 'n' or '0') then this expanded entry is selected. |
| |
| |
| |
| .. _etype_u_boot_spl_nodtb: |
| |
| Entry: u-boot-spl-nodtb: SPL binary without device tree appended |
| ---------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename to include (default 'spl/u-boot-spl-nodtb.bin') |
| |
| This is the U-Boot SPL binary, It does not include a device tree blob at |
| the end of it so may not be able to work without it, assuming SPL needs |
| a device tree to operate on your platform. You can add a u-boot-spl-dtb |
| entry after this one, or use a u-boot-spl entry instead' which normally |
| expands to a section containing u-boot-spl-dtb, u-boot-spl-bss-pad and |
| u-boot-spl-dtb |
| |
| SPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| in the binman README for more information. |
| |
| The ELF file 'spl/u-boot-spl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the SPL binary. |
| |
| |
| |
| .. _etype_u_boot_spl_with_ucode_ptr: |
| |
| Entry: u-boot-spl-with-ucode-ptr: U-Boot SPL with embedded microcode pointer |
| ---------------------------------------------------------------------------- |
| |
| This is used when SPL must set up the microcode for U-Boot. |
| |
| See Entry_u_boot_ucode for full details of the entries involved in this |
| process. |
| |
| |
| |
| .. _etype_u_boot_tpl: |
| |
| Entry: u-boot-tpl: U-Boot TPL binary |
| ------------------------------------ |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-tpl.bin (default 'tpl/u-boot-tpl.bin') |
| |
| This is the U-Boot TPL (Tertiary Program Loader) binary. This is a small |
| binary which loads before SPL, typically into on-chip SRAM. It is |
| responsible for locating, loading and jumping to SPL, the next-stage |
| loader. Note that SPL is not relocatable so must be loaded to the correct |
| address in SRAM, or written to run from the correct address if direct |
| flash execution is possible (e.g. on x86 devices). |
| |
| SPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| in the binman README for more information. |
| |
| The ELF file 'tpl/u-boot-tpl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the TPL binary. |
| |
| Note that this entry is automatically replaced with u-boot-tpl-expanded |
| unless --no-expanded is used or the node has a 'no-expanded' property. |
| |
| |
| |
| .. _etype_u_boot_tpl_bss_pad: |
| |
| Entry: u-boot-tpl-bss-pad: U-Boot TPL binary padded with a BSS region |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| This holds the padding added after the TPL binary to cover the BSS (Block |
| Started by Symbol) region. This region holds the various variables used by |
| TPL. It is set to 0 by TPL when it starts up. If you want to append data to |
| the TPL image (such as a device tree file), you must pad out the BSS region |
| to avoid the data overlapping with U-Boot variables. This entry is useful in |
| that case. It automatically pads out the entry size to cover both the code, |
| data and BSS. |
| |
| The contents of this entry will a certain number of zero bytes, determined |
| by __bss_size |
| |
| The ELF file 'tpl/u-boot-tpl' must also be available for this to work, since |
| binman uses that to look up the BSS address. |
| |
| |
| |
| .. _etype_u_boot_tpl_dtb: |
| |
| Entry: u-boot-tpl-dtb: U-Boot TPL device tree |
| --------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.dtb (default 'tpl/u-boot-tpl.dtb') |
| |
| This is the TPL device tree, containing configuration information for |
| TPL. TPL needs this to know what devices are present and which drivers |
| to activate. |
| |
| |
| |
| .. _etype_u_boot_tpl_dtb_with_ucode: |
| |
| Entry: u-boot-tpl-dtb-with-ucode: U-Boot TPL with embedded microcode pointer |
| ---------------------------------------------------------------------------- |
| |
| This is used when TPL must set up the microcode for U-Boot. |
| |
| See Entry_u_boot_ucode for full details of the entries involved in this |
| process. |
| |
| |
| |
| .. _etype_u_boot_tpl_elf: |
| |
| Entry: u-boot-tpl-elf: U-Boot TPL ELF image |
| ------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of TPL u-boot (default 'tpl/u-boot-tpl') |
| |
| This is the U-Boot TPL ELF image. It does not include a device tree but can |
| be relocated to any address for execution. |
| |
| |
| |
| .. _etype_u_boot_tpl_expanded: |
| |
| Entry: u-boot-tpl-expanded: U-Boot TPL flat binary broken out into its component parts |
| -------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - tpl-dtb: Controls whether this entry is selected (set to 'y' or '1' to |
| select) |
| |
| This is a section containing the U-Boot binary, BSS padding if needed and a |
| devicetree. Using this entry type automatically creates this section, with |
| the following entries in it: |
| |
| u-boot-tpl-nodtb |
| u-boot-tpl-bss-pad |
| u-boot-dtb |
| |
| Having the devicetree separate allows binman to update it in the final |
| image, so that the entries positions are provided to the running U-Boot. |
| |
| This entry is selected based on the value of the 'tpl-dtb' entryarg. If |
| this is non-empty (and not 'n' or '0') then this expanded entry is selected. |
| |
| |
| |
| .. _etype_u_boot_tpl_nodtb: |
| |
| Entry: u-boot-tpl-nodtb: TPL binary without device tree appended |
| ---------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename to include (default 'tpl/u-boot-tpl-nodtb.bin') |
| |
| This is the U-Boot TPL binary, It does not include a device tree blob at |
| the end of it so may not be able to work without it, assuming TPL needs |
| a device tree to operate on your platform. You can add a u-boot-tpl-dtb |
| entry after this one, or use a u-boot-tpl entry instead, which normally |
| expands to a section containing u-boot-tpl-dtb, u-boot-tpl-bss-pad and |
| u-boot-tpl-dtb |
| |
| TPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| in the binman README for more information. |
| |
| The ELF file 'tpl/u-boot-tpl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the TPL binary. |
| |
| |
| |
| .. _etype_u_boot_tpl_with_ucode_ptr: |
| |
| Entry: u-boot-tpl-with-ucode-ptr: U-Boot TPL with embedded microcode pointer |
| ---------------------------------------------------------------------------- |
| |
| See Entry_u_boot_ucode for full details of the entries involved in this |
| process. |
| |
| |
| |
| .. _etype_u_boot_ucode: |
| |
| Entry: u-boot-ucode: U-Boot microcode block |
| ------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| The contents of this entry are filled in automatically by other entries |
| which must also be in the image. |
| |
| U-Boot on x86 needs a single block of microcode. This is collected from |
| the various microcode update nodes in the device tree. It is also unable |
| to read the microcode from the device tree on platforms that use FSP |
| (Firmware Support Package) binaries, because the API requires that the |
| microcode is supplied before there is any SRAM available to use (i.e. |
| the FSP sets up the SRAM / cache-as-RAM but does so in the call that |
| requires the microcode!). To keep things simple, all x86 platforms handle |
| microcode the same way in U-Boot (even non-FSP platforms). This is that |
| a table is placed at _dt_ucode_base_size containing the base address and |
| size of the microcode. This is either passed to the FSP (for FSP |
| platforms), or used to set up the microcode (for non-FSP platforms). |
| This all happens in the build system since it is the only way to get |
| the microcode into a single blob and accessible without SRAM. |
| |
| There are two cases to handle. If there is only one microcode blob in |
| the device tree, then the ucode pointer it set to point to that. This |
| entry (u-boot-ucode) is empty. If there is more than one update, then |
| this entry holds the concatenation of all updates, and the device tree |
| entry (u-boot-dtb-with-ucode) is updated to remove the microcode. This |
| last step ensures that that the microcode appears in one contiguous |
| block in the image and is not unnecessarily duplicated in the device |
| tree. It is referred to as 'collation' here. |
| |
| Entry types that have a part to play in handling microcode: |
| |
| Entry_u_boot_with_ucode_ptr: |
| Contains u-boot-nodtb.bin (i.e. U-Boot without the device tree). |
| It updates it with the address and size of the microcode so that |
| U-Boot can find it early on start-up. |
| Entry_u_boot_dtb_with_ucode: |
| Contains u-boot.dtb. It stores the microcode in a |
| 'self.ucode_data' property, which is then read by this class to |
| obtain the microcode if needed. If collation is performed, it |
| removes the microcode from the device tree. |
| Entry_u_boot_ucode: |
| This class. If collation is enabled it reads the microcode from |
| the Entry_u_boot_dtb_with_ucode entry, and uses it as the |
| contents of this entry. |
| |
| |
| |
| .. _etype_u_boot_vpl: |
| |
| Entry: u-boot-vpl: U-Boot VPL binary |
| ------------------------------------ |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-vpl.bin (default 'vpl/u-boot-vpl.bin') |
| |
| This is the U-Boot VPL (Verifying Program Loader) binary. This is a small |
| binary which loads before SPL, typically into on-chip SRAM. It is |
| responsible for locating, loading and jumping to SPL, the next-stage |
| loader. Note that VPL is not relocatable so must be loaded to the correct |
| address in SRAM, or written to run from the correct address if direct |
| flash execution is possible (e.g. on x86 devices). |
| |
| SPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| in the binman README for more information. |
| |
| The ELF file 'vpl/u-boot-vpl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the VPL binary. |
| |
| |
| |
| .. _etype_u_boot_vpl_bss_pad: |
| |
| Entry: u-boot-vpl-bss-pad: U-Boot VPL binary padded with a BSS region |
| --------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| None |
| |
| This holds the padding added after the VPL binary to cover the BSS (Block |
| Started by Symbol) region. This region holds the various variables used by |
| VPL. It is set to 0 by VPL when it starts up. If you want to append data to |
| the VPL image (such as a device tree file), you must pad out the BSS region |
| to avoid the data overlapping with U-Boot variables. This entry is useful in |
| that case. It automatically pads out the entry size to cover both the code, |
| data and BSS. |
| |
| The contents of this entry will a certain number of zero bytes, determined |
| by __bss_size |
| |
| The ELF file 'vpl/u-boot-vpl' must also be available for this to work, since |
| binman uses that to look up the BSS address. |
| |
| |
| |
| .. _etype_u_boot_vpl_dtb: |
| |
| Entry: u-boot-vpl-dtb: U-Boot VPL device tree |
| --------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot.dtb (default 'vpl/u-boot-vpl.dtb') |
| |
| This is the VPL device tree, containing configuration information for |
| VPL. VPL needs this to know what devices are present and which drivers |
| to activate. |
| |
| |
| |
| .. _etype_u_boot_vpl_elf: |
| |
| Entry: u-boot-vpl-elf: U-Boot VPL ELF image |
| ------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of VPL u-boot (default 'vpl/u-boot-vpl') |
| |
| This is the U-Boot VPL ELF image. It does not include a device tree but can |
| be relocated to any address for execution. |
| |
| |
| |
| .. _etype_u_boot_vpl_expanded: |
| |
| Entry: u-boot-vpl-expanded: U-Boot VPL flat binary broken out into its component parts |
| -------------------------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - vpl-dtb: Controls whether this entry is selected (set to 'y' or '1' to |
| select) |
| |
| This is a section containing the U-Boot binary, BSS padding if needed and a |
| devicetree. Using this entry type automatically creates this section, with |
| the following entries in it: |
| |
| u-boot-vpl-nodtb |
| u-boot-vpl-bss-pad |
| u-boot-dtb |
| |
| Having the devicetree separate allows binman to update it in the final |
| image, so that the entries positions are provided to the running U-Boot. |
| |
| This entry is selected based on the value of the 'vpl-dtb' entryarg. If |
| this is non-empty (and not 'n' or '0') then this expanded entry is selected. |
| |
| |
| |
| .. _etype_u_boot_vpl_nodtb: |
| |
| Entry: u-boot-vpl-nodtb: VPL binary without device tree appended |
| ---------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename to include (default 'vpl/u-boot-vpl-nodtb.bin') |
| |
| This is the U-Boot VPL binary, It does not include a device tree blob at |
| the end of it so may not be able to work without it, assuming VPL needs |
| a device tree to operate on your platform. You can add a u_boot_vpl_dtb |
| entry after this one, or use a u_boot_vpl entry instead, which normally |
| expands to a section containing u-boot-vpl-dtb, u-boot-vpl-bss-pad and |
| u-boot-vpl-dtb |
| |
| VPL can access binman symbols at runtime. See :ref:`binman_fdt`. |
| |
| The ELF file 'vpl/u-boot-vpl' must also be available for this to work, since |
| binman uses that to look up symbols to write into the VPL binary. |
| |
| |
| |
| .. _etype_u_boot_with_ucode_ptr: |
| |
| Entry: u-boot-with-ucode-ptr: U-Boot with embedded microcode pointer |
| -------------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-nodtb.bin (default 'u-boot-nodtb.bin') |
| - optional-ucode: boolean property to make microcode optional. If the |
| u-boot.bin image does not include microcode, no error will |
| be generated. |
| |
| See Entry_u_boot_ucode for full details of the three entries involved in |
| this process. This entry updates U-Boot with the offset and size of the |
| microcode, to allow early x86 boot code to find it without doing anything |
| complicated. Otherwise it is the same as the u-boot entry. |
| |
| |
| |
| .. _etype_vblock: |
| |
| Entry: vblock: An entry which contains a Chromium OS verified boot block |
| ------------------------------------------------------------------------ |
| |
| Properties / Entry arguments: |
| - content: List of phandles to entries to sign |
| - keydir: Directory containing the public keys to use |
| - keyblock: Name of the key file to use (inside keydir) |
| - signprivate: Name of provide key file to use (inside keydir) |
| - version: Version number of the vblock (typically 1) |
| - kernelkey: Name of the kernel key to use (inside keydir) |
| - preamble-flags: Value of the vboot preamble flags (typically 0) |
| |
| Output files: |
| - input.<unique_name> - input file passed to futility |
| - vblock.<unique_name> - output file generated by futility (which is |
| used as the entry contents) |
| |
| Chromium OS signs the read-write firmware and kernel, writing the signature |
| in this block. This allows U-Boot to verify that the next firmware stage |
| and kernel are genuine. |
| |
| |
| |
| .. _etype_x509_cert: |
| |
| Entry: x509-cert: An entry which contains an X509 certificate |
| ------------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - content: List of phandles to entries to sign |
| |
| Output files: |
| - input.<unique_name> - input file passed to openssl |
| - cert.<unique_name> - output file generated by openssl (which is |
| used as the entry contents) |
| |
| openssl signs the provided data, writing the signature in this entry. This |
| allows verification that the data is genuine |
| |
| |
| |
| .. _etype_x86_reset16: |
| |
| Entry: x86-reset16: x86 16-bit reset code for U-Boot |
| ---------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-x86-reset16.bin (default |
| 'u-boot-x86-reset16.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed at a particular address. This entry holds that code. It is |
| typically placed at offset CONFIG_RESET_VEC_LOC. The code is responsible |
| for jumping to the x86-start16 code, which continues execution. |
| |
| For 64-bit U-Boot, the 'x86_reset16_spl' entry type is used instead. |
| |
| |
| |
| .. _etype_x86_reset16_spl: |
| |
| Entry: x86-reset16-spl: x86 16-bit reset code for U-Boot |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-x86-reset16.bin (default |
| 'u-boot-x86-reset16.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed at a particular address. This entry holds that code. It is |
| typically placed at offset CONFIG_RESET_VEC_LOC. The code is responsible |
| for jumping to the x86-start16 code, which continues execution. |
| |
| For 32-bit U-Boot, the 'x86_reset_spl' entry type is used instead. |
| |
| |
| |
| .. _etype_x86_reset16_tpl: |
| |
| Entry: x86-reset16-tpl: x86 16-bit reset code for U-Boot |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-x86-reset16.bin (default |
| 'u-boot-x86-reset16.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed at a particular address. This entry holds that code. It is |
| typically placed at offset CONFIG_RESET_VEC_LOC. The code is responsible |
| for jumping to the x86-start16 code, which continues execution. |
| |
| For 32-bit U-Boot, the 'x86_reset_tpl' entry type is used instead. |
| |
| |
| |
| .. _etype_x86_start16: |
| |
| Entry: x86-start16: x86 16-bit start-up code for U-Boot |
| ------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of u-boot-x86-start16.bin (default |
| 'u-boot-x86-start16.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed in the top 64KB of the ROM. The reset code jumps to it. This |
| entry holds that code. It is typically placed at offset |
| CONFIG_SYS_X86_START16. The code is responsible for changing to 32-bit mode |
| and jumping to U-Boot's entry point, which requires 32-bit mode (for 32-bit |
| U-Boot). |
| |
| For 64-bit U-Boot, the 'x86_start16_spl' entry type is used instead. |
| |
| |
| |
| .. _etype_x86_start16_spl: |
| |
| Entry: x86-start16-spl: x86 16-bit start-up code for SPL |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of spl/u-boot-x86-start16-spl.bin (default |
| 'spl/u-boot-x86-start16-spl.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed in the top 64KB of the ROM. The reset code jumps to it. This |
| entry holds that code. It is typically placed at offset |
| CONFIG_SYS_X86_START16. The code is responsible for changing to 32-bit mode |
| and jumping to U-Boot's entry point, which requires 32-bit mode (for 32-bit |
| U-Boot). |
| |
| For 32-bit U-Boot, the 'x86-start16' entry type is used instead. |
| |
| |
| |
| .. _etype_x86_start16_tpl: |
| |
| Entry: x86-start16-tpl: x86 16-bit start-up code for TPL |
| -------------------------------------------------------- |
| |
| Properties / Entry arguments: |
| - filename: Filename of tpl/u-boot-x86-start16-tpl.bin (default |
| 'tpl/u-boot-x86-start16-tpl.bin') |
| |
| x86 CPUs start up in 16-bit mode, even if they are 32-bit CPUs. This code |
| must be placed in the top 64KB of the ROM. The reset code jumps to it. This |
| entry holds that code. It is typically placed at offset |
| CONFIG_SYS_X86_START16. The code is responsible for changing to 32-bit mode |
| and jumping to U-Boot's entry point, which requires 32-bit mode (for 32-bit |
| U-Boot). |
| |
| If TPL is not being used, the 'x86-start16-spl or 'x86-start16' entry types |
| may be used instead. |
| |
| |
| |