board/st/stm32mp1/README - u-boot-mtk - Git at Google

 SPDX-License-Identifier: GPL-2.0+ OR BSD-3-Clause
 #
 # Copyright (C) 2018 STMicroelectronics - All Rights Reserved
 #

 U-Boot on STMicroelectronics STM32MP1
 ======================================

 1. Summary
 ==========
 This is a quick instruction for setup stm32mp1 boards.

 2. Supported devices
 ====================
 U-Boot supports one STMP32MP1 SoCs: STM32MP157

 The STM32MP157 is a Cortex-A MPU aimed at various applications.
 It features:
 - Dual core Cortex-A7 application core
 - 2D/3D image composition with GPU
 - Standard memories interface support
 - Standard connectivity, widely inherited from the STM32 MCU family
 - Comprehensive security support

 Everything is supported in Linux but U-Boot is limited to:
 1. UART
 2. SDCard/MMC controller (SDMMC)
 3. NAND controller (FMC)
 4. NOR controller (QSPI)
 5. USB controller (OTG DWC2)
 6. Ethernet controller

 And the necessary drivers
 1. I2C
 2. STPMIC1 (PMIC and regulator)
 3. Clock, Reset, Sysreset
 4. Fuse

 Currently the following boards are supported:
 + stm32mp157c-ev1
 + stm32mp157c-ed1
 + stm32mp157a-dk1
 + stm32mp157c-dk2
 + stm32mp157a-avenger96

 3. Boot Sequences
 =================

 BootRom => FSBL in SYSRAM => SSBL in DDR => OS (Linux Kernel)

 with FSBL = First Stage Bootloader
      SSBL = Second Stage Bootloader

 3 boot configurations are supported:

 1) The "Trusted" boot chain (defconfig_file : stm32mp15_trusted_defconfig)
    BootRom => FSBL = Trusted Firmware-A (TF-A) => SSBL = U-Boot
    TF-A performs a full initialization of Secure peripherals and installs a
    secure monitor.
    U-Boot is running in normal world and uses TF-A monitor
    to access to secure resources.

 2) The "Trusted" boot chain with OP-TEE
    (defconfig_file : stm32mp15_optee_defconfig)
    BootRom => FSBL = Trusted Firmware-A (TF-A) => SSBL = U-Boot
    TF-A performs a full initialization of Secure peripherals and installs OP-TEE
    from specific partitions (teeh, teed, teex).
    U-Boot is running in normal world and uses OP-TEE monitor to access
    to secure resources.

 3) The "Basic" boot chain (defconfig_file : stm32mp15_basic_defconfig)
    BootRom => FSBL = U-Boot SPL => SSBL = U-Boot
    SPL has limited security initialisation
    U-Boot is running in secure mode and provide a secure monitor to the kernel
    with only PSCI support (Power State Coordination Interface defined by ARM).

 All the STM32MP1 boards supported by U-Boot use the same generic board
 stm32mp1 which support all the bootable devices.

 Each board is configurated only with the associated device tree.

 4. Device Tree Selection
 ========================

 You need to select the appropriate device tree for your board,
 the supported device trees for stm32mp157 are:

 + ev1: eval board with pmic stpmic1 (ev1 = mother board + daughter ed1)
   dts: stm32mp157c-ev1

 + ed1: daughter board with pmic stpmic1
   dts: stm32mp157c-ed1

 + dk1: Discovery board
   dts: stm32mp157a-dk1

 + dk2: Discovery board = dk1 with a BT/WiFI combo and a DSI panel
   dts: stm32mp157c-dk2

 + avenger96: Avenger96 board from Arrow Electronics
   dts: stm32mp157a-avenger96

 5. Build Procedure
 ==================

 1. Install required tools for U-Boot

    + install package needed in U-Boot makefile
      (libssl-dev, swig, libpython-dev...)
    + install ARMv7 toolchain for 32bit Cortex-A (from Linaro,
      from SDK for STM32MP1, or any crosstoolchains from your distribution)

 2. Set the cross compiler:

 	# export CROSS_COMPILE=/path/to/toolchain/arm-linux-gnueabi-
 	(you can use any gcc cross compiler compatible with U-Boot)

 3. Select the output directory (optional)

 	# export KBUILD_OUTPUT=/path/to/output

 	for example: use one output directory for each configuration
 	# export KBUILD_OUTPUT=stm32mp15_trusted
 	# export KBUILD_OUTPUT=stm32mp15_optee
 	# export KBUILD_OUTPUT=stm32mp15_basic

 	you can build outside of code directory:
 	# export KBUILD_OUTPUT=../build/stm32mp15_trusted

 4. Configure U-Boot:

 	# make <defconfig_file>

 	- For trusted boot mode : "stm32mp15_trusted_defconfig"
 	- For trusted with OP-TEE boot mode : "stm32mp15_optee_defconfig"
 	- For basic boot mode: "stm32mp15_basic_defconfig"

 5. Configure the device-tree and build the U-Boot image:

 	# make DEVICE_TREE=<name> all

   example:
   a) trusted boot on ev1
 	# export KBUILD_OUTPUT=stm32mp15_trusted
 	# make stm32mp15_trusted_defconfig
 	# make DEVICE_TREE=stm32mp157c-ev1 all

   b) trusted with OP-TEE boot on dk2
 	# export KBUILD_OUTPUT=stm32mp15_optee
 	# make stm32mp15_optee_defconfig
 	# make DEVICE_TREE=stm32mp157c-dk2 all

   c) basic boot on ev1
 	# export KBUILD_OUTPUT=stm32mp15_basic
 	# make stm32mp15_basic_defconfig
 	# make DEVICE_TREE=stm32mp157c-ev1 all

   d) basic boot on ed1
 	# export KBUILD_OUTPUT=stm32mp15_basic
 	# make stm32mp15_basic_defconfig
 	# make DEVICE_TREE=stm32mp157c-ed1 all

   e) basic boot on dk1
 	# export KBUILD_OUTPUT=stm32mp15_basic
 	# make stm32mp15_basic_defconfig
 	# make DEVICE_TREE=stm32mp157a-dk1 all

   f) basic boot on avenger96
 	# export KBUILD_OUTPUT=stm32mp15_basic
 	# make stm32mp15_basic_defconfig
 	# make DEVICE_TREE=stm32mp157a-avenger96 all

 6. Output files

   BootRom and TF-A expect binaries with STM32 image header
   SPL expects file with U-Boot uImage header

   So in the output directory (selected by KBUILD_OUTPUT),
   you can found the needed files:

   a) For Trusted boot (with or without OP-TEE)
    + FSBL = tf-a.stm32 (provided by TF-A compilation)
    + SSBL = u-boot.stm32

   b) For Basic boot
    + FSBL = spl/u-boot-spl.stm32
    + SSBL = u-boot.img

 6. Switch Setting for Boot Mode
 ===============================

 You can select the boot mode, on the board with one switch :

 - on the daugther board ed1 with the switch SW1 : BOOT0, BOOT1, BOOT2

  -----------------------------------
   Boot Mode   BOOT2   BOOT1   BOOT0
  -----------------------------------
   Reserved	0	0	0
   NOR		0	0	1
   SD-Card	1	0	1
   eMMC		0	1	0
   NAND		0	1	1
   Recovery	1	1	0
   Recovery	0	0	0

 - on board DK1/DK2 with the switch SW1 : BOOT0, BOOT2
   (BOOT1 forced to 0, NOR not supported)

  --------------------------
   Boot Mode   BOOT2  BOOT0
  --------------------------
   Reserved	1      0
   SD-Card	1      1
   Recovery	0      0

 - Boot mode of Avenger96 can be selected using switch S3

  -----------------------------------
   Boot Mode   BOOT2   BOOT1   BOOT0
  -----------------------------------
   Recovery	0	0	0
   NOR		0	0	1
   SD-Card	1	0	1
   eMMC		0	1	0
   NAND		0	1	1
   Reserved	1	0	0
   Recovery	1	1	0
   SD-Card	1	1	1

 Recovery is a boot from serial link (UART/USB) and it is used with
 STM32CubeProgrammer tool to load executable in RAM and to update the flash
 devices available on the board (NOR/NAND/eMMC/SDCARD).
 The communication between HOST and board is based on
 - for UARTs : the uart protocol used with all MCU STM32
 - for USB : based on USB DFU 1.1 (without the ST extensions used on MCU STM32)

 7. Prepare an SDCard
 ===================

 The minimal requirements for STMP32MP1 boot up to U-Boot are:
 - GPT partitioning (with gdisk or with sgdisk)
 - 2 fsbl partitions, named fsbl1 and fsbl2, size at least 256KiB
 - one ssbl partition for U-Boot

 Then the minimal GPT partition is:
    ----- ------- --------- --------------
   | Num | Name  | Size    |  Content     |
    ----- ------- -------- ---------------
   |  1  | fsbl1 | 256 KiB |  TF-A or SPL |
   |  2  | fsbl2 | 256 KiB |  TF-A or SPL |
   |  3  | ssbl  | enought |  U-Boot      |
   |  *  |  -    |  -      |  Boot/Rootfs |
    ----- ------- --------- --------------

 (*) add bootable partition for extlinux.conf
     following Generic Distribution
     (doc/README.distro for use)

   according the used card reader select the block device
   (/dev/sdx or /dev/mmcblk0)
   in the next example I use /dev/mmcblk0

 for example: with gpt table with 128 entries

   a) remove previous formatting
 	# sgdisk -o /dev/<SDCard dev>

   b) create minimal image
 	# sgdisk --resize-table=128 -a 1 \
 		-n 1:34:545		-c 1:fsbl1 \
 		-n 2:546:1057		-c 2:fsbl2 \
 		-n 3:1058:5153		-c 3:ssbl \
 		-p /dev/<SDCard dev>

 	you can add other partitions for kernel
 	one partition rootfs for example:
 		-n 4:5154:		-c 4:rootfs \

   c) copy the FSBL (2 times) and SSBL file on the correct partition.
      in this example in partition 1 to 3

      for basic boot mode : <SDCard dev> = /dev/mmcblk0
 	# dd if=u-boot-spl.stm32 of=/dev/mmcblk0p1
 	# dd if=u-boot-spl.stm32 of=/dev/mmcblk0p2
 	# dd if=u-boot.img of=/dev/mmcblk0p3

      for trusted boot mode :
 	# dd if=tf-a.stm32 of=/dev/mmcblk0p1
 	# dd if=tf-a.stm32 of=/dev/mmcblk0p2
 	# dd if=u-boot.stm32 of=/dev/mmcblk0p3

 To boot from SDCard, select BootPinMode = 1 0 1 and reset.

 8. Prepare eMMC
 ===============
 You can use U-Boot to copy binary in eMMC.

 In the next example, you need to boot from SDCARD and the images (u-boot-spl.stm32, u-boot.img)
 are presents on SDCARD (mmc 0) in ext4 partition 4 (bootfs).

 To boot from SDCard, select BootPinMode = 1 0 1 and reset.

 Then you update the eMMC with the next U-Boot command :

 a) prepare GPT on eMMC,
 	example with 2 partitions, bootfs and roots:

 	# setenv emmc_part "name=ssbl,size=2MiB;name=bootfs,type=linux,bootable,size=64MiB;name=rootfs,type=linux,size=512"
 	# gpt write mmc 1 ${emmc_part}

 b) copy SPL on eMMC on firts boot partition
 	(SPL max size is 256kB, with LBA 512, 0x200)

 	# ext4load mmc 0:4 0xC0000000 u-boot-spl.stm32
 	# mmc dev 1
 	# mmc partconf 1 1 1 1
 	# mmc write ${fileaddr} 0 200
 	# mmc partconf 1 1 1 0

 c) copy U-Boot in first GPT partition of eMMC

 	# ext4load mmc 0:4 0xC0000000 u-boot.img
 	# mmc dev 1
 	# part start mmc 1 1 partstart
 	# part size mmc 1 1 partsize
 	# mmc write ${fileaddr} ${partstart} ${partsize}

 To boot from eMMC, select BootPinMode = 0 1 0 and reset.

 9. MAC Address
 ==============

 Please read doc/README.enetaddr for the implementation guidelines for mac id
 usage. Basically, environment has precedence over board specific storage.

 Mac id storage and retrieval in stm32mp otp :
 - OTP_57[31:0] = MAC_ADDR[31:0]
 - OTP_58[15:0] = MAC_ADDR[47:32]

 To program a MAC address on virgin OTP words above, you can use the fuse command
 on bank 0 to access to internal OTP:

     example to set mac address "12:34:56:78:9a:bc"

     1- Write OTP
        STM32MP> fuse prog -y 0 57 0x78563412 0x0000bc9a

     2- Read OTP
        STM32MP> fuse sense 0 57 2
        Sensing bank 0:
        Word 0x00000039: 78563412 0000bc9a

     3- next REBOOT :
        ### Setting environment from OTP MAC address = "12:34:56:78:9a:bc"

     4 check env update
        STM32MP> print ethaddr
        ethaddr=12:34:56:78:9a:bc

 10. Coprocessor firmware
 ========================

 U-Boot can boot the coprocessor before the kernel (coprocessor early boot).

 A/ Manuallly by using rproc commands (update the bootcmd)
      Configurations
 	# env set name_copro "rproc-m4-fw.elf"
 	# env set dev_copro 0
 	# env set loadaddr_copro 0xC1000000

      Load binary from bootfs partition (number 4) on SDCard (mmc 0)
 	# ext4load mmc 0:4 ${loadaddr_copro} ${name_copro}
 	=> ${filesize} updated with the size of the loaded file

      Start M4 firmware with remote proc command
 	# rproc init
 	# rproc load ${dev_copro} ${loadaddr_copro} ${filesize}
 	# rproc start ${dev_copro}

 B/ Automatically by using FIT feature and generic DISTRO bootcmd

    see examples in this directory :

    Generate FIT including kernel + device tree + M4 firmware
    with cfg with M4 boot
         $> mkimage -f fit_copro_kernel_dtb.its fit_copro_kernel_dtb.itb

     Then using DISTRO configuration file: see extlinux.conf to select
     the correct configuration
 	=> stm32mp157c-ev1-m4
 	=> stm32mp157c-dk2-m4
	SPDX-License-Identifier: GPL-2.0+ OR BSD-3-Clause
	#
	# Copyright (C) 2018 STMicroelectronics - All Rights Reserved
	#

	U-Boot on STMicroelectronics STM32MP1
	======================================

	1. Summary
	==========
	This is a quick instruction for setup stm32mp1 boards.

	2. Supported devices
	====================
	U-Boot supports one STMP32MP1 SoCs: STM32MP157

	The STM32MP157 is a Cortex-A MPU aimed at various applications.
	It features:
	- Dual core Cortex-A7 application core
	- 2D/3D image composition with GPU
	- Standard memories interface support
	- Standard connectivity, widely inherited from the STM32 MCU family
	- Comprehensive security support

	Everything is supported in Linux but U-Boot is limited to:
	1. UART
	2. SDCard/MMC controller (SDMMC)
	3. NAND controller (FMC)
	4. NOR controller (QSPI)
	5. USB controller (OTG DWC2)
	6. Ethernet controller

	And the necessary drivers
	1. I2C
	2. STPMIC1 (PMIC and regulator)
	3. Clock, Reset, Sysreset
	4. Fuse

	Currently the following boards are supported:
	+ stm32mp157c-ev1
	+ stm32mp157c-ed1
	+ stm32mp157a-dk1
	+ stm32mp157c-dk2
	+ stm32mp157a-avenger96

	3. Boot Sequences
	=================

	BootRom => FSBL in SYSRAM => SSBL in DDR => OS (Linux Kernel)

	with FSBL = First Stage Bootloader
	SSBL = Second Stage Bootloader

	3 boot configurations are supported:

	1) The "Trusted" boot chain (defconfig_file : stm32mp15_trusted_defconfig)
	BootRom => FSBL = Trusted Firmware-A (TF-A) => SSBL = U-Boot
	TF-A performs a full initialization of Secure peripherals and installs a
	secure monitor.
	U-Boot is running in normal world and uses TF-A monitor
	to access to secure resources.

	2) The "Trusted" boot chain with OP-TEE
	(defconfig_file : stm32mp15_optee_defconfig)
	BootRom => FSBL = Trusted Firmware-A (TF-A) => SSBL = U-Boot
	TF-A performs a full initialization of Secure peripherals and installs OP-TEE
	from specific partitions (teeh, teed, teex).
	U-Boot is running in normal world and uses OP-TEE monitor to access
	to secure resources.

	3) The "Basic" boot chain (defconfig_file : stm32mp15_basic_defconfig)
	BootRom => FSBL = U-Boot SPL => SSBL = U-Boot
	SPL has limited security initialisation
	U-Boot is running in secure mode and provide a secure monitor to the kernel
	with only PSCI support (Power State Coordination Interface defined by ARM).

	All the STM32MP1 boards supported by U-Boot use the same generic board
	stm32mp1 which support all the bootable devices.

	Each board is configurated only with the associated device tree.

	4. Device Tree Selection
	========================

	You need to select the appropriate device tree for your board,
	the supported device trees for stm32mp157 are:

	+ ev1: eval board with pmic stpmic1 (ev1 = mother board + daughter ed1)
	dts: stm32mp157c-ev1

	+ ed1: daughter board with pmic stpmic1
	dts: stm32mp157c-ed1

	+ dk1: Discovery board
	dts: stm32mp157a-dk1

	+ dk2: Discovery board = dk1 with a BT/WiFI combo and a DSI panel
	dts: stm32mp157c-dk2

	+ avenger96: Avenger96 board from Arrow Electronics
	dts: stm32mp157a-avenger96

	5. Build Procedure
	==================

	1. Install required tools for U-Boot

	+ install package needed in U-Boot makefile
	(libssl-dev, swig, libpython-dev...)
	+ install ARMv7 toolchain for 32bit Cortex-A (from Linaro,
	from SDK for STM32MP1, or any crosstoolchains from your distribution)

	2. Set the cross compiler:

	# export CROSS_COMPILE=/path/to/toolchain/arm-linux-gnueabi-
	(you can use any gcc cross compiler compatible with U-Boot)

	3. Select the output directory (optional)

	# export KBUILD_OUTPUT=/path/to/output

	for example: use one output directory for each configuration
	# export KBUILD_OUTPUT=stm32mp15_trusted
	# export KBUILD_OUTPUT=stm32mp15_optee
	# export KBUILD_OUTPUT=stm32mp15_basic

	you can build outside of code directory:
	# export KBUILD_OUTPUT=../build/stm32mp15_trusted

	4. Configure U-Boot:

	# make <defconfig_file>

	- For trusted boot mode : "stm32mp15_trusted_defconfig"
	- For trusted with OP-TEE boot mode : "stm32mp15_optee_defconfig"
	- For basic boot mode: "stm32mp15_basic_defconfig"

	5. Configure the device-tree and build the U-Boot image:

	# make DEVICE_TREE=<name> all

	example:
	a) trusted boot on ev1
	# export KBUILD_OUTPUT=stm32mp15_trusted
	# make stm32mp15_trusted_defconfig
	# make DEVICE_TREE=stm32mp157c-ev1 all

	b) trusted with OP-TEE boot on dk2
	# export KBUILD_OUTPUT=stm32mp15_optee
	# make stm32mp15_optee_defconfig
	# make DEVICE_TREE=stm32mp157c-dk2 all

	c) basic boot on ev1
	# export KBUILD_OUTPUT=stm32mp15_basic
	# make stm32mp15_basic_defconfig
	# make DEVICE_TREE=stm32mp157c-ev1 all

	d) basic boot on ed1
	# export KBUILD_OUTPUT=stm32mp15_basic
	# make stm32mp15_basic_defconfig
	# make DEVICE_TREE=stm32mp157c-ed1 all

	e) basic boot on dk1
	# export KBUILD_OUTPUT=stm32mp15_basic
	# make stm32mp15_basic_defconfig
	# make DEVICE_TREE=stm32mp157a-dk1 all

	f) basic boot on avenger96
	# export KBUILD_OUTPUT=stm32mp15_basic
	# make stm32mp15_basic_defconfig
	# make DEVICE_TREE=stm32mp157a-avenger96 all

	6. Output files

	BootRom and TF-A expect binaries with STM32 image header
	SPL expects file with U-Boot uImage header

	So in the output directory (selected by KBUILD_OUTPUT),
	you can found the needed files:

	a) For Trusted boot (with or without OP-TEE)
	+ FSBL = tf-a.stm32 (provided by TF-A compilation)
	+ SSBL = u-boot.stm32

	b) For Basic boot
	+ FSBL = spl/u-boot-spl.stm32
	+ SSBL = u-boot.img

	6. Switch Setting for Boot Mode
	===============================

	You can select the boot mode, on the board with one switch :

	- on the daugther board ed1 with the switch SW1 : BOOT0, BOOT1, BOOT2

	-----------------------------------
	Boot Mode BOOT2 BOOT1 BOOT0
	-----------------------------------
	Reserved 0 0 0
	NOR 0 0 1
	SD-Card 1 0 1
	eMMC 0 1 0
	NAND 0 1 1
	Recovery 1 1 0
	Recovery 0 0 0

	- on board DK1/DK2 with the switch SW1 : BOOT0, BOOT2
	(BOOT1 forced to 0, NOR not supported)

	--------------------------
	Boot Mode BOOT2 BOOT0
	--------------------------
	Reserved 1 0
	SD-Card 1 1
	Recovery 0 0

	- Boot mode of Avenger96 can be selected using switch S3

	-----------------------------------
	Boot Mode BOOT2 BOOT1 BOOT0
	-----------------------------------
	Recovery 0 0 0
	NOR 0 0 1
	SD-Card 1 0 1
	eMMC 0 1 0
	NAND 0 1 1
	Reserved 1 0 0
	Recovery 1 1 0
	SD-Card 1 1 1

	Recovery is a boot from serial link (UART/USB) and it is used with
	STM32CubeProgrammer tool to load executable in RAM and to update the flash
	devices available on the board (NOR/NAND/eMMC/SDCARD).
	The communication between HOST and board is based on
	- for UARTs : the uart protocol used with all MCU STM32
	- for USB : based on USB DFU 1.1 (without the ST extensions used on MCU STM32)

	7. Prepare an SDCard
	===================

	The minimal requirements for STMP32MP1 boot up to U-Boot are:
	- GPT partitioning (with gdisk or with sgdisk)
	- 2 fsbl partitions, named fsbl1 and fsbl2, size at least 256KiB
	- one ssbl partition for U-Boot

	Then the minimal GPT partition is:
	----- ------- --------- --------------
	\| Num \| Name \| Size \| Content \|
	----- ------- -------- ---------------
	\| 1 \| fsbl1 \| 256 KiB \| TF-A or SPL \|
	\| 2 \| fsbl2 \| 256 KiB \| TF-A or SPL \|
	\| 3 \| ssbl \| enought \| U-Boot \|
	\| * \| - \| - \| Boot/Rootfs \|
	----- ------- --------- --------------

	(*) add bootable partition for extlinux.conf
	following Generic Distribution
	(doc/README.distro for use)

	according the used card reader select the block device
	(/dev/sdx or /dev/mmcblk0)
	in the next example I use /dev/mmcblk0

	for example: with gpt table with 128 entries

	a) remove previous formatting
	# sgdisk -o /dev/<SDCard dev>

	b) create minimal image
	# sgdisk --resize-table=128 -a 1 \
	-n 1:34:545 -c 1:fsbl1 \
	-n 2:546:1057 -c 2:fsbl2 \
	-n 3:1058:5153 -c 3:ssbl \
	-p /dev/<SDCard dev>

	you can add other partitions for kernel
	one partition rootfs for example:
	-n 4:5154: -c 4:rootfs \

	c) copy the FSBL (2 times) and SSBL file on the correct partition.
	in this example in partition 1 to 3

	for basic boot mode : <SDCard dev> = /dev/mmcblk0
	# dd if=u-boot-spl.stm32 of=/dev/mmcblk0p1
	# dd if=u-boot-spl.stm32 of=/dev/mmcblk0p2
	# dd if=u-boot.img of=/dev/mmcblk0p3

	for trusted boot mode :
	# dd if=tf-a.stm32 of=/dev/mmcblk0p1
	# dd if=tf-a.stm32 of=/dev/mmcblk0p2
	# dd if=u-boot.stm32 of=/dev/mmcblk0p3

	To boot from SDCard, select BootPinMode = 1 0 1 and reset.

	8. Prepare eMMC
	===============
	You can use U-Boot to copy binary in eMMC.

	In the next example, you need to boot from SDCARD and the images (u-boot-spl.stm32, u-boot.img)
	are presents on SDCARD (mmc 0) in ext4 partition 4 (bootfs).

	To boot from SDCard, select BootPinMode = 1 0 1 and reset.

	Then you update the eMMC with the next U-Boot command :

	a) prepare GPT on eMMC,
	example with 2 partitions, bootfs and roots:

	# setenv emmc_part "name=ssbl,size=2MiB;name=bootfs,type=linux,bootable,size=64MiB;name=rootfs,type=linux,size=512"
	# gpt write mmc 1 ${emmc_part}

	b) copy SPL on eMMC on firts boot partition
	(SPL max size is 256kB, with LBA 512, 0x200)

	# ext4load mmc 0:4 0xC0000000 u-boot-spl.stm32
	# mmc dev 1
	# mmc partconf 1 1 1 1
	# mmc write ${fileaddr} 0 200
	# mmc partconf 1 1 1 0

	c) copy U-Boot in first GPT partition of eMMC

	# ext4load mmc 0:4 0xC0000000 u-boot.img
	# mmc dev 1
	# part start mmc 1 1 partstart
	# part size mmc 1 1 partsize
	# mmc write ${fileaddr} ${partstart} ${partsize}

	To boot from eMMC, select BootPinMode = 0 1 0 and reset.

	9. MAC Address
	==============

	Please read doc/README.enetaddr for the implementation guidelines for mac id
	usage. Basically, environment has precedence over board specific storage.

	Mac id storage and retrieval in stm32mp otp :
	- OTP_57[31:0] = MAC_ADDR[31:0]
	- OTP_58[15:0] = MAC_ADDR[47:32]

	To program a MAC address on virgin OTP words above, you can use the fuse command
	on bank 0 to access to internal OTP:

	example to set mac address "12:34:56:78:9a:bc"

	1- Write OTP
	STM32MP> fuse prog -y 0 57 0x78563412 0x0000bc9a

	2- Read OTP
	STM32MP> fuse sense 0 57 2
	Sensing bank 0:
	Word 0x00000039: 78563412 0000bc9a

	3- next REBOOT :
	### Setting environment from OTP MAC address = "12:34:56:78:9a:bc"

	4 check env update
	STM32MP> print ethaddr
	ethaddr=12:34:56:78:9a:bc

	10. Coprocessor firmware
	========================

	U-Boot can boot the coprocessor before the kernel (coprocessor early boot).

	A/ Manuallly by using rproc commands (update the bootcmd)
	Configurations
	# env set name_copro "rproc-m4-fw.elf"
	# env set dev_copro 0
	# env set loadaddr_copro 0xC1000000

	Load binary from bootfs partition (number 4) on SDCard (mmc 0)
	# ext4load mmc 0:4 ${loadaddr_copro} ${name_copro}
	=> ${filesize} updated with the size of the loaded file

	Start M4 firmware with remote proc command
	# rproc init
	# rproc load ${dev_copro} ${loadaddr_copro} ${filesize}
	# rproc start ${dev_copro}

	B/ Automatically by using FIT feature and generic DISTRO bootcmd

	see examples in this directory :

	Generate FIT including kernel + device tree + M4 firmware
	with cfg with M4 boot
	$> mkimage -f fit_copro_kernel_dtb.its fit_copro_kernel_dtb.itb

	Then using DISTRO configuration file: see extlinux.conf to select
	the correct configuration
	=> stm32mp157c-ev1-m4
	=> stm32mp157c-dk2-m4