doc/board/toradex/colibri_imx7.rst - u-boot - Git at Google

 .. SPDX-License-Identifier: GPL-2.0-or-later
 .. sectionauthor:: Igor Opaniuk <igor.opaniuk@toradex.com>

 Colibri iMX7 Modules
 ====================

 - SoM: https://www.toradex.com/computer-on-modules/colibri-arm-family/nxp-freescale-imx7
 - Carrier board: https://www.toradex.com/products/carrier-board/colibri-evaluation-board

 Quick Start
 -----------

 - Build U-Boot
 - NAND IMX image adjustments before flashing
 - Flashing manually U-Boot to eMMC
 - Flashing manually U-Boot to NAND
 - Using ``update_uboot`` script

 Build U-Boot
 ------------

 .. code-block:: bash

     $ export CROSS_COMPILE=arm-linux-gnueabi-
     $ make colibri_imx7_emmc_defconfig # For NAND: colibri_imx7_defconfig
     $ make

 After the build succeeds, you will obtain the final ``u-boot-dtb.imx`` IMX
 specific image, ready for flashing (but check next section for additional
 adjustments).

 The final IMX program image includes (section ``6.6.7`` from `IMX7DRM
 <https://www.nxp.com/webapp/Download?colCode=IMX7DRM>`_):

 * **Image vector table** (IVT) for BootROM
 * **Boot data** -indicates the program image location, program image size
   in bytes, and the plugin flag.
 * **Device configuration data**
 * **User image**: U-Boot image (``u-boot-dtb.bin``)

 IMX image adjustments prior to flashing
 ---------------------------------------

 1. U-Boot for both Colibri iMX7 NAND and eMMC versions
 is built with HABv4 support (`AN4581.pdf
 <https://www.nxp.com/docs/en/application-note/AN4581.pdf>`_)
 enabled by default, which requires generating a proper
 Command Sequence File (CSF) by srktool from NXP (not included in the
 U-Boot tree, check additional details in introduction_habv4.txt)
 and concatenate it to the final ``u-boot-dtb.imx``.

 2. In case you don't want to generate a proper ``CSF`` (for any reason),
 you still need to pad the IMX image so it has the same size as specified in
 the **Boot Data** section of the IMX image.
 To obtain this value, run:

 .. code-block:: bash

     $ od -X -N 0x30 u-boot-dtb.imx
     0000000    402000d1 87800000 00000000 877ff42c
     0000020    877ff420 877ff400 878a5000 00000000
                         ^^^^^^^^
     0000040    877ff000 000a8060 00000000 40b401d2
                ^^^^^^^^ ^^^^^^^^

 Where:

 * ``877ff400`` - IVT self address
 * ``877ff000`` - Program image address
 * ``000a8060`` - Program image size

 To calculate the padding:

 * IVT offset = ``0x877ff400`` - ``0x877ff000`` = ``0x400``
 * Program image size = ``0xa8060`` - ``0x400`` = ``0xa7c60``

 and then pad the image:

 .. code-block:: bash

     $ objcopy -I binary -O binary --pad-to 0xa7c60 --gap-fill=0x00 \
         u-boot-dtb.imx u-boot-dtb.imx.zero-padded

 3. Also, according to the requirement from ``6.6.7.1``, the final image
 should have ``0x400`` offset for the initial IVT table.

 For eMMC setup we handle this by flashing it to ``0x400``, however
 for NAND setup we adjust the image prior to flashing, adding padding at the
 beginning of the image.

 .. code-block:: bash

     $ dd if=u-boot-dtb.imx.zero-padded of=u-boot-dtb.imx.ready bs=1024 seek=1

 Flash U-Boot IMX image to eMMC
 ------------------------------

 Flash the ``u-boot-dtb.imx.zero-padded`` binary to the primary eMMC hardware
 boot area partition:

 .. code-block:: bash

     => load mmc 1:1 $loadaddr u-boot-dtb.imx.zero-padded
     => setexpr blkcnt ${filesize} + 0x1ff && setexpr blkcnt ${blkcnt} / 0x200
     => mmc dev 0 1
     => mmc write ${loadaddr} 0x2 ${blkcnt}

 Flash U-Boot IMX image to NAND
 ------------------------------

 .. code-block:: bash

     => load mmc 1:1 $loadaddr u-boot-dtb.imx.ready
     => nand erase.part u-boot1
     => nand write ${loadaddr} u-boot1 ${filesize}
     => nand erase.part u-boot2
     => nand write ${loadaddr} u-boot2 ${filesize}

 Using update_uboot script
 -------------------------

 You can also use U-Boot env update_uboot script,
 which wraps all eMMC/NAND specific command invocations:

 .. code-block:: bash

     => load mmc 1:1 $loadaddr u-boot-dtb.imx.ready
     => run update_uboot
	.. SPDX-License-Identifier: GPL-2.0-or-later
	.. sectionauthor:: Igor Opaniuk <igor.opaniuk@toradex.com>

	Colibri iMX7 Modules
	====================

	- SoM: https://www.toradex.com/computer-on-modules/colibri-arm-family/nxp-freescale-imx7
	- Carrier board: https://www.toradex.com/products/carrier-board/colibri-evaluation-board

	Quick Start
	-----------

	- Build U-Boot
	- NAND IMX image adjustments before flashing
	- Flashing manually U-Boot to eMMC
	- Flashing manually U-Boot to NAND
	- Using ``update_uboot`` script

	Build U-Boot
	------------

	.. code-block:: bash

	$ export CROSS_COMPILE=arm-linux-gnueabi-
	$ make colibri_imx7_emmc_defconfig # For NAND: colibri_imx7_defconfig
	$ make

	After the build succeeds, you will obtain the final ``u-boot-dtb.imx`` IMX
	specific image, ready for flashing (but check next section for additional
	adjustments).

	The final IMX program image includes (section ``6.6.7`` from `IMX7DRM
	<https://www.nxp.com/webapp/Download?colCode=IMX7DRM>`_):

	* Image vector table (IVT) for BootROM
	* Boot data -indicates the program image location, program image size
	in bytes, and the plugin flag.
	* Device configuration data
	* User image: U-Boot image (``u-boot-dtb.bin``)

	IMX image adjustments prior to flashing
	---------------------------------------

	1. U-Boot for both Colibri iMX7 NAND and eMMC versions
	is built with HABv4 support (`AN4581.pdf
	<https://www.nxp.com/docs/en/application-note/AN4581.pdf>`_)
	enabled by default, which requires generating a proper
	Command Sequence File (CSF) by srktool from NXP (not included in the
	U-Boot tree, check additional details in introduction_habv4.txt)
	and concatenate it to the final ``u-boot-dtb.imx``.

	2. In case you don't want to generate a proper ``CSF`` (for any reason),
	you still need to pad the IMX image so it has the same size as specified in
	the Boot Data section of the IMX image.
	To obtain this value, run:

	.. code-block:: bash

	$ od -X -N 0x30 u-boot-dtb.imx
	0000000 402000d1 87800000 00000000 877ff42c
	0000020 877ff420 877ff400 878a5000 00000000
	^^^^^^^^
	0000040 877ff000 000a8060 00000000 40b401d2
	^^^^^^^^ ^^^^^^^^

	Where:

	* ``877ff400`` - IVT self address
	* ``877ff000`` - Program image address
	* ``000a8060`` - Program image size

	To calculate the padding:

	* IVT offset = ``0x877ff400`` - ``0x877ff000`` = ``0x400``
	* Program image size = ``0xa8060`` - ``0x400`` = ``0xa7c60``

	and then pad the image:

	.. code-block:: bash

	$ objcopy -I binary -O binary --pad-to 0xa7c60 --gap-fill=0x00 \
	u-boot-dtb.imx u-boot-dtb.imx.zero-padded

	3. Also, according to the requirement from ``6.6.7.1``, the final image
	should have ``0x400`` offset for the initial IVT table.

	For eMMC setup we handle this by flashing it to ``0x400``, however
	for NAND setup we adjust the image prior to flashing, adding padding at the
	beginning of the image.

	.. code-block:: bash

	$ dd if=u-boot-dtb.imx.zero-padded of=u-boot-dtb.imx.ready bs=1024 seek=1

	Flash U-Boot IMX image to eMMC
	------------------------------

	Flash the ``u-boot-dtb.imx.zero-padded`` binary to the primary eMMC hardware
	boot area partition:

	.. code-block:: bash

	=> load mmc 1:1 $loadaddr u-boot-dtb.imx.zero-padded
	=> setexpr blkcnt ${filesize} + 0x1ff && setexpr blkcnt ${blkcnt} / 0x200
	=> mmc dev 0 1
	=> mmc write ${loadaddr} 0x2 ${blkcnt}

	Flash U-Boot IMX image to NAND
	------------------------------

	.. code-block:: bash

	=> load mmc 1:1 $loadaddr u-boot-dtb.imx.ready
	=> nand erase.part u-boot1
	=> nand write ${loadaddr} u-boot1 ${filesize}
	=> nand erase.part u-boot2
	=> nand write ${loadaddr} u-boot2 ${filesize}

	Using update_uboot script
	-------------------------

	You can also use U-Boot env update_uboot script,
	which wraps all eMMC/NAND specific command invocations:

	.. code-block:: bash

	=> load mmc 1:1 $loadaddr u-boot-dtb.imx.ready
	=> run update_uboot