From: Simon Glass Date: Fri, 23 Jun 2023 12:22:07 +0000 (+0100) Subject: doc: Bring in the FIT howto X-Git-Url: http://git.dujemihanovic.xyz/%22http:/www.sics.se/static/%7B%7B%20%24.Site.BaseURL%20%7D%7Dposts/index.xml?a=commitdiff_plain;h=51de69cda390f645dc69046703340d0780f52e46;p=u-boot.git doc: Bring in the FIT howto Bring this file into the documentation. Signed-off-by: Simon Glass --- diff --git a/doc/uImage.FIT/howto.txt b/doc/uImage.FIT/howto.txt deleted file mode 100644 index 6dbd17dc8c..0000000000 --- a/doc/uImage.FIT/howto.txt +++ /dev/null @@ -1,411 +0,0 @@ -How to use images in the new image format -========================================= - -Author: Bartlomiej Sieka - - -Overview --------- - -The new uImage format allows more flexibility in handling images of various -types (kernel, ramdisk, etc.), it also enhances integrity protection of images -with sha1 and md5 checksums. - -Two auxiliary tools are needed on the development host system in order to -create an uImage in the new format: mkimage and dtc, although only one -(mkimage) is invoked directly. dtc is called from within mkimage and operates -behind the scenes, but needs to be present in the $PATH nevertheless. It is -important that the dtc used has support for binary includes -- refer to - - git://git.kernel.org/pub/scm/utils/dtc/dtc.git - -for its latest version. mkimage (together with dtc) takes as input -an image source file, which describes the contents of the image and defines -its various properties used during booting. By convention, image source file -has the ".its" extension, also, the details of its format are given in -doc/uImage.FIT/source_file_format.txt. The actual data that is to be included in -the uImage (kernel, ramdisk, etc.) is specified in the image source file in the -form of paths to appropriate data files. The outcome of the image creation -process is a binary file (by convention with the ".itb" extension) that -contains all the referenced data (kernel, ramdisk, etc.) and other information -needed by U-Boot to handle the uImage properly. The uImage file is then -transferred to the target (e.g., via tftp) and booted using the bootm command. - -To summarize the prerequisites needed for new uImage creation: -- mkimage -- dtc (with support for binary includes) -- image source file (*.its) -- image data file(s) - - -Here's a graphical overview of the image creation and booting process: - -image source file mkimage + dtc transfer to target - + ---------------> image file --------------------> bootm -image data file(s) - -SPL usage ---------- - -The SPL can make use of the new image format as well, this traditionally -is used to ship multiple device tree files within one image. Code in the SPL -will choose the one matching the current board and append this to the -U-Boot proper binary to be automatically used up by it. -Aside from U-Boot proper and one device tree blob the SPL can load multiple, -arbitrary image files as well. These binaries should be specified in their -own subnode under the /images node, which should then be referenced from one or -multiple /configurations subnodes. The required images must be enumerated in -the "loadables" property as a list of strings. - -If a platform specific image source file (.its) is shipped with the U-Boot -source, it can be specified using the CONFIG_SPL_FIT_SOURCE Kconfig symbol. -In this case it will be automatically used by U-Boot's Makefile to generate -the image. -If a static source file is not flexible enough, CONFIG_SPL_FIT_GENERATOR -can point to a script which generates this image source file during -the build process. It gets passed a list of device tree files (taken from the -CONFIG_OF_LIST symbol). - -The SPL also records to a DT all additional images (called loadables) which are -loaded. The information about loadables locations is passed via the DT node with -fit-images name. - -Finally, if there are multiple xPL phases (e.g. SPL, VPL), images can be marked -as intended for a particular phase using the 'phase' property. For example, if -fit_image_load() is called with image_ph(IH_PHASE_SPL, IH_TYPE_FIRMWARE), then -only the image listed into the "firmware" property where phase is set to "spl" -will be loaded. - -Loadables Example ------------------ -Consider the following case for an ARM64 platform where U-Boot runs in EL2 -started by ATF where SPL is loading U-Boot (as loadables) and ATF (as firmware). - -/dts-v1/; - -/ { - description = "Configuration to load ATF before U-Boot"; - - images { - uboot { - description = "U-Boot (64-bit)"; - data = /incbin/("u-boot-nodtb.bin"); - type = "firmware"; - os = "u-boot"; - arch = "arm64"; - compression = "none"; - load = <0x8 0x8000000>; - entry = <0x8 0x8000000>; - hash { - algo = "md5"; - }; - }; - atf { - description = "ARM Trusted Firmware"; - data = /incbin/("bl31.bin"); - type = "firmware"; - os = "arm-trusted-firmware"; - arch = "arm64"; - compression = "none"; - load = <0xfffea000>; - entry = <0xfffea000>; - hash { - algo = "md5"; - }; - }; - fdt_1 { - description = "zynqmp-zcu102-revA"; - data = /incbin/("arch/arm/dts/zynqmp-zcu102-revA.dtb"); - type = "flat_dt"; - arch = "arm64"; - compression = "none"; - load = <0x100000>; - hash { - algo = "md5"; - }; - }; - }; - configurations { - default = "config_1"; - - config_1 { - description = "zynqmp-zcu102-revA"; - firmware = "atf"; - loadables = "uboot"; - fdt = "fdt_1"; - }; - }; -}; - -In this case the SPL records via fit-images DT node the information about -loadables U-Boot image. - -ZynqMP> fdt addr $fdtcontroladdr -ZynqMP> fdt print /fit-images -fit-images { - uboot { - os = "u-boot"; - type = "firmware"; - size = <0x001017c8>; - entry = <0x00000008 0x08000000>; - load = <0x00000008 0x08000000>; - }; -}; - -As you can see entry and load properties are 64bit wide to support loading -images above 4GB (in past entry and load properties where just 32bit). - - -Example 1 -- old-style (non-FDT) kernel booting ------------------------------------------------ - -Consider a simple scenario, where a PPC Linux kernel built from sources on the -development host is to be booted old-style (non-FDT) by U-Boot on an embedded -target. Assume that the outcome of the build is vmlinux.bin.gz, a file which -contains a gzip-compressed PPC Linux kernel (the only data file in this case). -The uImage can be produced using the image source file -doc/uImage.FIT/kernel.its (note that kernel.its assumes that vmlinux.bin.gz is -in the current working directory; if desired, an alternative path can be -specified in the kernel.its file). Here's how to create the image and inspect -its contents: - -[on the host system] -$ mkimage -f kernel.its kernel.itb -DTC: dts->dtb on file "kernel.its" -$ -$ mkimage -l kernel.itb -FIT description: Simple image with single Linux kernel -Created: Tue Mar 11 17:26:15 2008 - Image 0 (kernel) - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Size: 943347 Bytes = 921.24 kB = 0.90 MB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2ae2bb40 - Hash algo: sha1 - Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 - Default Configuration: 'config-1' - Configuration 0 (config-1) - Description: Boot Linux kernel - Kernel: kernel - - -The resulting image file kernel.itb can be now transferred to the target, -inspected and booted (note that first three U-Boot commands below are shown -for completeness -- they are part of the standard booting procedure and not -specific to the new image format). - -[on the target system] -=> print nfsargs -nfsargs=setenv bootargs root=/dev/nfs rw nfsroot=${serverip}:${rootpath} -=> print addip -addip=setenv bootargs ${bootargs} ip=${ipaddr}:${serverip}:${gatewayip}:${netmask}:${hostname}:${netdev}:off panic=1 -=> run nfsargs addip -=> tftp 900000 /path/to/tftp/location/kernel.itb -Using FEC device -TFTP from server 192.168.1.1; our IP address is 192.168.160.5 -Filename '/path/to/tftp/location/kernel.itb'. -Load address: 0x900000 -Loading: ################################################################# -done -Bytes transferred = 944464 (e6950 hex) -=> iminfo - -## Checking Image at 00900000 ... - FIT image found - FIT description: Simple image with single Linux kernel - Created: 2008-03-11 16:26:15 UTC - Image 0 (kernel) - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Start: 0x009000e0 - Data Size: 943347 Bytes = 921.2 kB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2ae2bb40 - Hash algo: sha1 - Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 - Default Configuration: 'config-1' - Configuration 0 (config-1) - Description: Boot Linux kernel - Kernel: kernel - -=> bootm -## Booting kernel from FIT Image at 00900000 ... - Using 'config-1' configuration - Trying 'kernel' kernel subimage - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Start: 0x009000e0 - Data Size: 943347 Bytes = 921.2 kB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2ae2bb40 - Hash algo: sha1 - Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 - Verifying Hash Integrity ... crc32+ sha1+ OK - Uncompressing Kernel Image ... OK -Memory BAT mapping: BAT2=256Mb, BAT3=0Mb, residual: 0Mb -Linux version 2.4.25 (m8@hekate) (gcc version 4.0.0 (DENX ELDK 4.0 4.0.0)) #2 czw lip 5 17:56:18 CEST 2007 -On node 0 totalpages: 65536 -zone(0): 65536 pages. -zone(1): 0 pages. -zone(2): 0 pages. -Kernel command line: root=/dev/nfs rw nfsroot=192.168.1.1:/opt/eldk-4.1/ppc_6xx ip=192.168.160.5:192.168.1.1::255.255.0.0:lite5200b:eth0:off panic=1 -Calibrating delay loop... 307.20 BogoMIPS - - -Example 2 -- new-style (FDT) kernel booting -------------------------------------------- - -Consider another simple scenario, where a PPC Linux kernel is to be booted -new-style, i.e., with a FDT blob. In this case there are two prerequisite data -files: vmlinux.bin.gz (Linux kernel) and target.dtb (FDT blob). The uImage can -be produced using image source file doc/uImage.FIT/kernel_fdt.its like this -(note again, that both prerequisite data files are assumed to be present in -the current working directory -- image source file kernel_fdt.its can be -modified to take the files from some other location if needed): - -[on the host system] -$ mkimage -f kernel_fdt.its kernel_fdt.itb -DTC: dts->dtb on file "kernel_fdt.its" -$ -$ mkimage -l kernel_fdt.itb -FIT description: Simple image with single Linux kernel and FDT blob -Created: Tue Mar 11 16:29:22 2008 - Image 0 (kernel) - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Size: 1092037 Bytes = 1066.44 kB = 1.04 MB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2c0cc807 - Hash algo: sha1 - Hash value: 264b59935470e42c418744f83935d44cdf59a3bb - Image 1 (fdt-1) - Description: Flattened Device Tree blob - Type: Flat Device Tree - Compression: uncompressed - Data Size: 16384 Bytes = 16.00 kB = 0.02 MB - Architecture: PowerPC - Hash algo: crc32 - Hash value: 0d655d71 - Hash algo: sha1 - Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def - Default Configuration: 'conf-1' - Configuration 0 (conf-1) - Description: Boot Linux kernel with FDT blob - Kernel: kernel - FDT: fdt-1 - - -The resulting image file kernel_fdt.itb can be now transferred to the target, -inspected and booted: - -[on the target system] -=> tftp 900000 /path/to/tftp/location/kernel_fdt.itb -Using FEC device -TFTP from server 192.168.1.1; our IP address is 192.168.160.5 -Filename '/path/to/tftp/location/kernel_fdt.itb'. -Load address: 0x900000 -Loading: ################################################################# - ########### -done -Bytes transferred = 1109776 (10ef10 hex) -=> iminfo - -## Checking Image at 00900000 ... - FIT image found - FIT description: Simple image with single Linux kernel and FDT blob - Created: 2008-03-11 15:29:22 UTC - Image 0 (kernel) - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Start: 0x009000ec - Data Size: 1092037 Bytes = 1 MB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2c0cc807 - Hash algo: sha1 - Hash value: 264b59935470e42c418744f83935d44cdf59a3bb - Image 1 (fdt-1) - Description: Flattened Device Tree blob - Type: Flat Device Tree - Compression: uncompressed - Data Start: 0x00a0abdc - Data Size: 16384 Bytes = 16 kB - Architecture: PowerPC - Hash algo: crc32 - Hash value: 0d655d71 - Hash algo: sha1 - Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def - Default Configuration: 'conf-1' - Configuration 0 (conf-1) - Description: Boot Linux kernel with FDT blob - Kernel: kernel - FDT: fdt-1 -=> bootm -## Booting kernel from FIT Image at 00900000 ... - Using 'conf-1' configuration - Trying 'kernel' kernel subimage - Description: Vanilla Linux kernel - Type: Kernel Image - Compression: gzip compressed - Data Start: 0x009000ec - Data Size: 1092037 Bytes = 1 MB - Architecture: PowerPC - OS: Linux - Load Address: 0x00000000 - Entry Point: 0x00000000 - Hash algo: crc32 - Hash value: 2c0cc807 - Hash algo: sha1 - Hash value: 264b59935470e42c418744f83935d44cdf59a3bb - Verifying Hash Integrity ... crc32+ sha1+ OK - Uncompressing Kernel Image ... OK -## Flattened Device Tree from FIT Image at 00900000 - Using 'conf-1' configuration - Trying 'fdt-1' FDT blob subimage - Description: Flattened Device Tree blob - Type: Flat Device Tree - Compression: uncompressed - Data Start: 0x00a0abdc - Data Size: 16384 Bytes = 16 kB - Architecture: PowerPC - Hash algo: crc32 - Hash value: 0d655d71 - Hash algo: sha1 - Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def - Verifying Hash Integrity ... crc32+ sha1+ OK - Booting using the fdt blob at 0xa0abdc - Loading Device Tree to 007fc000, end 007fffff ... OK -[ 0.000000] Using lite5200 machine description -[ 0.000000] Linux version 2.6.24-rc6-gaebecdfc (m8@hekate) (gcc version 4.0.0 (DENX ELDK 4.1 4.0.0)) #1 Sat Jan 12 15:38:48 CET 2008 - - -Example 3 -- advanced booting ------------------------------ - -Refer to doc/uImage.FIT/multi.its for an image source file that allows more -sophisticated booting scenarios (multiple kernels, ramdisks and fdt blobs). diff --git a/doc/usage/fit/howto.rst b/doc/usage/fit/howto.rst new file mode 100644 index 0000000000..c933703d1d --- /dev/null +++ b/doc/usage/fit/howto.rst @@ -0,0 +1,419 @@ +.. SPDX-License-Identifier: GPL-2.0+ + +How to use images in the new image format +========================================= + +Overview +-------- + +The new uImage format allows more flexibility in handling images of various +types (kernel, ramdisk, etc.), it also enhances integrity protection of images +with sha1 and md5 checksums. + +Two auxiliary tools are needed on the development host system in order to +create an uImage in the new format: mkimage and dtc, although only one +(mkimage) is invoked directly. dtc is called from within mkimage and operates +behind the scenes, but needs to be present in the $PATH nevertheless. It is +important that the dtc used has support for binary includes -- refer to:: + + git://git.kernel.org/pub/scm/utils/dtc/dtc.git + +for its latest version. mkimage (together with dtc) takes as input +an image source file, which describes the contents of the image and defines +its various properties used during booting. By convention, image source file +has the ".its" extension, also, the details of its format are given in +doc/uImage.FIT/source_file_format.txt. The actual data that is to be included in +the uImage (kernel, ramdisk, etc.) is specified in the image source file in the +form of paths to appropriate data files. The outcome of the image creation +process is a binary file (by convention with the ".itb" extension) that +contains all the referenced data (kernel, ramdisk, etc.) and other information +needed by U-Boot to handle the uImage properly. The uImage file is then +transferred to the target (e.g., via tftp) and booted using the bootm command. + +To summarize the prerequisites needed for new uImage creation: + +- mkimage +- dtc (with support for binary includes) +- image source file (`*.its`) +- image data file(s) + + +Here's a graphical overview of the image creation and booting process:: + + image source file mkimage + dtc transfer to target + + ---------------> image file --------------------> bootm + image data file(s) + +SPL usage +--------- + +The SPL can make use of the new image format as well, this traditionally +is used to ship multiple device tree files within one image. Code in the SPL +will choose the one matching the current board and append this to the +U-Boot proper binary to be automatically used up by it. +Aside from U-Boot proper and one device tree blob the SPL can load multiple, +arbitrary image files as well. These binaries should be specified in their +own subnode under the /images node, which should then be referenced from one or +multiple /configurations subnodes. The required images must be enumerated in +the "loadables" property as a list of strings. + +If a platform specific image source file (.its) is shipped with the U-Boot +source, it can be specified using the CONFIG_SPL_FIT_SOURCE Kconfig symbol. +In this case it will be automatically used by U-Boot's Makefile to generate +the image. +If a static source file is not flexible enough, CONFIG_SPL_FIT_GENERATOR +can point to a script which generates this image source file during +the build process. It gets passed a list of device tree files (taken from the +CONFIG_OF_LIST symbol). + +The SPL also records to a DT all additional images (called loadables) which are +loaded. The information about loadables locations is passed via the DT node with +fit-images name. + +Finally, if there are multiple xPL phases (e.g. SPL, VPL), images can be marked +as intended for a particular phase using the 'phase' property. For example, if +fit_image_load() is called with image_ph(IH_PHASE_SPL, IH_TYPE_FIRMWARE), then +only the image listed into the "firmware" property where phase is set to "spl" +will be loaded. + +Loadables Example +----------------- +Consider the following case for an ARM64 platform where U-Boot runs in EL2 +started by ATF where SPL is loading U-Boot (as loadables) and ATF (as firmware). + +:: + + /dts-v1/; + + / { + description = "Configuration to load ATF before U-Boot"; + + images { + uboot { + description = "U-Boot (64-bit)"; + data = /incbin/("u-boot-nodtb.bin"); + type = "firmware"; + os = "u-boot"; + arch = "arm64"; + compression = "none"; + load = <0x8 0x8000000>; + entry = <0x8 0x8000000>; + hash { + algo = "md5"; + }; + }; + atf { + description = "ARM Trusted Firmware"; + data = /incbin/("bl31.bin"); + type = "firmware"; + os = "arm-trusted-firmware"; + arch = "arm64"; + compression = "none"; + load = <0xfffea000>; + entry = <0xfffea000>; + hash { + algo = "md5"; + }; + }; + fdt_1 { + description = "zynqmp-zcu102-revA"; + data = /incbin/("arch/arm/dts/zynqmp-zcu102-revA.dtb"); + type = "flat_dt"; + arch = "arm64"; + compression = "none"; + load = <0x100000>; + hash { + algo = "md5"; + }; + }; + }; + configurations { + default = "config_1"; + + config_1 { + description = "zynqmp-zcu102-revA"; + firmware = "atf"; + loadables = "uboot"; + fdt = "fdt_1"; + }; + }; + }; + +In this case the SPL records via fit-images DT node the information about +loadables U-Boot image:: + + ZynqMP> fdt addr $fdtcontroladdr + ZynqMP> fdt print /fit-images + fit-images { + uboot { + os = "u-boot"; + type = "firmware"; + size = <0x001017c8>; + entry = <0x00000008 0x08000000>; + load = <0x00000008 0x08000000>; + }; + }; + +As you can see entry and load properties are 64bit wide to support loading +images above 4GB (in past entry and load properties where just 32bit). + + +Example 1 -- old-style (non-FDT) kernel booting +----------------------------------------------- + +Consider a simple scenario, where a PPC Linux kernel built from sources on the +development host is to be booted old-style (non-FDT) by U-Boot on an embedded +target. Assume that the outcome of the build is vmlinux.bin.gz, a file which +contains a gzip-compressed PPC Linux kernel (the only data file in this case). +The uImage can be produced using the image source file +doc/uImage.FIT/kernel.its (note that kernel.its assumes that vmlinux.bin.gz is +in the current working directory; if desired, an alternative path can be +specified in the kernel.its file). Here's how to create the image and inspect +its contents: + +[on the host system]:: + + $ mkimage -f kernel.its kernel.itb + DTC: dts->dtb on file "kernel.its" + $ + $ mkimage -l kernel.itb + FIT description: Simple image with single Linux kernel + Created: Tue Mar 11 17:26:15 2008 + Image 0 (kernel) + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Size: 943347 Bytes = 921.24 kB = 0.90 MB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2ae2bb40 + Hash algo: sha1 + Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 + Default Configuration: 'config-1' + Configuration 0 (config-1) + Description: Boot Linux kernel + Kernel: kernel + + +The resulting image file kernel.itb can be now transferred to the target, +inspected and booted (note that first three U-Boot commands below are shown +for completeness -- they are part of the standard booting procedure and not +specific to the new image format). + +[on the target system]:: + + => print nfsargs + nfsargs=setenv bootargs root=/dev/nfs rw nfsroot=${serverip}:${rootpath} + => print addip + addip=setenv bootargs ${bootargs} ip=${ipaddr}:${serverip}:${gatewayip}:${netmask}:${hostname}:${netdev}:off panic=1 + => run nfsargs addip + => tftp 900000 /path/to/tftp/location/kernel.itb + Using FEC device + TFTP from server 192.168.1.1; our IP address is 192.168.160.5 + Filename '/path/to/tftp/location/kernel.itb'. + Load address: 0x900000 + Loading: ################################################################# + done + Bytes transferred = 944464 (e6950 hex) + => iminfo + + ## Checking Image at 00900000 ... + FIT image found + FIT description: Simple image with single Linux kernel + Created: 2008-03-11 16:26:15 UTC + Image 0 (kernel) + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Start: 0x009000e0 + Data Size: 943347 Bytes = 921.2 kB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2ae2bb40 + Hash algo: sha1 + Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 + Default Configuration: 'config-1' + Configuration 0 (config-1) + Description: Boot Linux kernel + Kernel: kernel + + => bootm + ## Booting kernel from FIT Image at 00900000 ... + Using 'config-1' configuration + Trying 'kernel' kernel subimage + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Start: 0x009000e0 + Data Size: 943347 Bytes = 921.2 kB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2ae2bb40 + Hash algo: sha1 + Hash value: 3c200f34e2c226ddc789240cca0c59fc54a67cf4 + Verifying Hash Integrity ... crc32+ sha1+ OK + Uncompressing Kernel Image ... OK + Memory BAT mapping: BAT2=256Mb, BAT3=0Mb, residual: 0Mb + Linux version 2.4.25 (m8@hekate) (gcc version 4.0.0 (DENX ELDK 4.0 4.0.0)) #2 czw lip 5 17:56:18 CEST 2007 + On node 0 totalpages: 65536 + zone(0): 65536 pages. + zone(1): 0 pages. + zone(2): 0 pages. + Kernel command line: root=/dev/nfs rw nfsroot=192.168.1.1:/opt/eldk-4.1/ppc_6xx ip=192.168.160.5:192.168.1.1::255.255.0.0:lite5200b:eth0:off panic=1 + Calibrating delay loop... 307.20 BogoMIPS + + +Example 2 -- new-style (FDT) kernel booting +------------------------------------------- + +Consider another simple scenario, where a PPC Linux kernel is to be booted +new-style, i.e., with a FDT blob. In this case there are two prerequisite data +files: vmlinux.bin.gz (Linux kernel) and target.dtb (FDT blob). The uImage can +be produced using image source file doc/uImage.FIT/kernel_fdt.its like this +(note again, that both prerequisite data files are assumed to be present in +the current working directory -- image source file kernel_fdt.its can be +modified to take the files from some other location if needed): + +[on the host system]:: + + $ mkimage -f kernel_fdt.its kernel_fdt.itb + DTC: dts->dtb on file "kernel_fdt.its" + $ + $ mkimage -l kernel_fdt.itb + FIT description: Simple image with single Linux kernel and FDT blob + Created: Tue Mar 11 16:29:22 2008 + Image 0 (kernel) + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Size: 1092037 Bytes = 1066.44 kB = 1.04 MB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2c0cc807 + Hash algo: sha1 + Hash value: 264b59935470e42c418744f83935d44cdf59a3bb + Image 1 (fdt-1) + Description: Flattened Device Tree blob + Type: Flat Device Tree + Compression: uncompressed + Data Size: 16384 Bytes = 16.00 kB = 0.02 MB + Architecture: PowerPC + Hash algo: crc32 + Hash value: 0d655d71 + Hash algo: sha1 + Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def + Default Configuration: 'conf-1' + Configuration 0 (conf-1) + Description: Boot Linux kernel with FDT blob + Kernel: kernel + FDT: fdt-1 + + +The resulting image file kernel_fdt.itb can be now transferred to the target, +inspected and booted: + +[on the target system]:: + + => tftp 900000 /path/to/tftp/location/kernel_fdt.itb + Using FEC device + TFTP from server 192.168.1.1; our IP address is 192.168.160.5 + Filename '/path/to/tftp/location/kernel_fdt.itb'. + Load address: 0x900000 + Loading: ################################################################# + ########### + done + Bytes transferred = 1109776 (10ef10 hex) + => iminfo + + ## Checking Image at 00900000 ... + FIT image found + FIT description: Simple image with single Linux kernel and FDT blob + Created: 2008-03-11 15:29:22 UTC + Image 0 (kernel) + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Start: 0x009000ec + Data Size: 1092037 Bytes = 1 MB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2c0cc807 + Hash algo: sha1 + Hash value: 264b59935470e42c418744f83935d44cdf59a3bb + Image 1 (fdt-1) + Description: Flattened Device Tree blob + Type: Flat Device Tree + Compression: uncompressed + Data Start: 0x00a0abdc + Data Size: 16384 Bytes = 16 kB + Architecture: PowerPC + Hash algo: crc32 + Hash value: 0d655d71 + Hash algo: sha1 + Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def + Default Configuration: 'conf-1' + Configuration 0 (conf-1) + Description: Boot Linux kernel with FDT blob + Kernel: kernel + FDT: fdt-1 + => bootm + ## Booting kernel from FIT Image at 00900000 ... + Using 'conf-1' configuration + Trying 'kernel' kernel subimage + Description: Vanilla Linux kernel + Type: Kernel Image + Compression: gzip compressed + Data Start: 0x009000ec + Data Size: 1092037 Bytes = 1 MB + Architecture: PowerPC + OS: Linux + Load Address: 0x00000000 + Entry Point: 0x00000000 + Hash algo: crc32 + Hash value: 2c0cc807 + Hash algo: sha1 + Hash value: 264b59935470e42c418744f83935d44cdf59a3bb + Verifying Hash Integrity ... crc32+ sha1+ OK + Uncompressing Kernel Image ... OK + ## Flattened Device Tree from FIT Image at 00900000 + Using 'conf-1' configuration + Trying 'fdt-1' FDT blob subimage + Description: Flattened Device Tree blob + Type: Flat Device Tree + Compression: uncompressed + Data Start: 0x00a0abdc + Data Size: 16384 Bytes = 16 kB + Architecture: PowerPC + Hash algo: crc32 + Hash value: 0d655d71 + Hash algo: sha1 + Hash value: 25ab4e15cd4b8a5144610394560d9c318ce52def + Verifying Hash Integrity ... crc32+ sha1+ OK + Booting using the fdt blob at 0xa0abdc + Loading Device Tree to 007fc000, end 007fffff ... OK + [ 0.000000] Using lite5200 machine description + [ 0.000000] Linux version 2.6.24-rc6-gaebecdfc (m8@hekate) (gcc version 4.0.0 (DENX ELDK 4.1 4.0.0)) #1 Sat Jan 12 15:38:48 CET 2008 + + +Example 3 -- advanced booting +----------------------------- + +Refer to :doc:`multi` for an image source file that allows more +sophisticated booting scenarios (multiple kernels, ramdisks and fdt blobs). + +.. sectionauthor:: Bartlomiej Sieka diff --git a/doc/usage/fit/index.rst b/doc/usage/fit/index.rst index 0576675ec0..83bc4d01ca 100644 --- a/doc/usage/fit/index.rst +++ b/doc/usage/fit/index.rst @@ -11,6 +11,7 @@ doc/uImage.FIT :maxdepth: 1 source_file_format + howto x86-fit-boot signature verified-boot