4.13. Freescale i.MX¶
Freescale i.MX is traditionally very well supported under barebox. Depending on the SoC, there are different Boot Modes supported. Older SoCs up to i.MX31 support only the external Boot Mode. Newer SoCs can be configured for internal or external Boot Mode with the internal boot mode being the more popular mode. The i.MX23 and i.MX28, also known as i.MXs, are special. These SoCs have a completely different boot mechanism, see Freescale MXS instead.
4.13.1. Internal Boot Mode¶
The Internal Boot Mode is supported on:
i.MX25
i.MX35
i.MX50
i.MX51
i.MX53
i.MX6
i.MX7
i.MX8M
With the Internal Boot Mode, the images contain a header which describes
where the binary shall be loaded and started. These headers also contain
a so-called DCD table which consists of register/value pairs. These are
executed by the Boot ROM and are used to configure the SDRAM. In barebox,
the i.MX images are generated with the scripts/imx/imx-image
tool.
Normally it’s not necessary to call this tool manually, it is executed
automatically at the end of the build process.
Required entries for an i.MX image in images/Makefile.imx
are for example:
pblb-$(CONFIG_MACH_MYBOARD) += start_imx6dl_myboard
CFG_start_imx6dl_myboard.pblb.imximg = $(board)/myboard/flash-header-imx6dl-myboard.imxcfg
FILE_barebox-imx6dl-myboard.img = start_imx6dl_myboard.pblb.imximg
image-$(CONFIG_MACH_MYBOARD) += barebox-imx6dl-myboard.img
The first line defines the entry function of the pre-bootloader.
This function must be defined in the board’s lowlevel.c
.
The second line describes the flash header to be used for the image, which is
then compiled into an imximg file.
The prebootloader is then added to the final barebox image.
The images generated by the build process can be directly written to an SD card:
# with Multi Image support:
cat images/barebox-freescale-imx51-babbage.img > /dev/sdd
# otherwise:
cat barebox-flash-image > /dev/sdd
The above will overwrite the MBR (and consequently the partition table) on the destination SD card. To preserve the MBR while writing the rest of the image to the card, use:
dd if=images/barebox-freescale-imx51-babbage.img of=/dev/sdd bs=1024 skip=1 seek=1
Note that MaskROM on i.MX8M expects the image to start at the +33KiB mark, so the following command has to be used instead:
dd if=images/barebox-nxp-imx8mq-evk.img of=/dev/sdd bs=1024 skip=33 seek=33
Or, in case of NAND:
dd if=images/barebox-nxp-imx8mq-evk.img of=/dev/nand bs=1024 skip=33 seek=1
The images can also always be started as second stage on the target:
barebox@Board Name:/ bootm /mnt/tftp/barebox-freescale-imx51-babbage.img
4.13.1.1. BootROM Reboot mode codes (bmode)¶
For selected SoCs, barebox supports communicating an alternative boot medium that the BootROM should select after a warm reset:
barebox@FSL i.MX8MM EVK board:/ devinfo gpr.reboot_mode
Driver: syscon-reboot-mode
Bus: platform
Parent: 30390000.reset-controller@30390000.of
Parameters:
next: normal (type: enum) (values: "normal", "serial")
prev: normal (type: enum) (values: "normal", "serial")
Device node: /soc@0/bus@30000000/reset-controller@30390000/reboot-mode
reboot-mode {
compatible = "barebox,syscon-reboot-mode";
offset = <0x94 0x98>;
mask = <0xffffffff 0x40000000>;
mode-normal = <0x0 0x0>;
mode-serial = <0x10 0x40000000>;
};
barebox@FSL i.MX8MM EVK board:/ gpr.reboot_mode.next=serial reset -w
The example above will cause barebox to jump back into serial download mode on an i.MX8MM by writing 0x10 into the SRC_GPR9 register (offset 0x30390094) and 0x40000000 into the SRC_GPR10 register (offset 0x30390098), and then issuing a warm reset.
Different SoCs may have more possible reboot modes available.
Look for documentation of the SRC_SBMR and SRC_GPR registers in the
Reference Manual of your SoC; the values for the mode-*
properties often
correspond directly to the boot fusemap settings.
See the section on Reboot modes for general information.
4.13.1.2. High Assurance Boot¶
HAB is an NXP ROM code feature which is able to authenticate software in external memory at boot time. This is done by verifying signatures as defined in the Command Sequence File (CSF) as compiled into the i.MX boot header.
barebox supports generating signed images, signed USB images suitable for imx-usb-loader and encrypted images.
In contrast to normal (unsigned) images booting signed images via imx-usb-loader on i.MX6 (but not in i.MX8M) requires special images: DCD data is invalidated (DCD pointer set to zero), the image is then signed and afterwards the DCD pointer is set to the DCD data again (practically making the signature invalid). This works because the imx-usb-loader transmits the DCD table setup prior to the actual image to set up the RAM in order to load the barebox image. Now the DCD pointer is set to zero (making the signature valid again) and the image is loaded and verified by the ROM code.
Note that the device-specific Data Encryption Key (DEK) blob needs to be appended to the image after the build process for appropriately encrypted images.
In order to generate these special image types barebox is equipped with
corresponding static pattern rules in images/Makefile.imx
.
Unlike the typical imximg
file extension the following ones are used for
these cases:
simximg
: generate signed imageusimximg
: generate signed USB image (i.MX6-specific)esimximg
: generate encrypted and signed image
The imx-image tool is then automatically called with the appropriate flags during image creation. This again calls Freescale’s Code Signing Tool (CST) which must be installed in the path or given via the environment variable “CST”.
Assuming CONFIG_HAB
and CONFIG_HABV4
are enabled the necessary
keys/certificates are expected in these config variables (assuming HABv4):
CONFIG_HABV4_TABLE_BIN
CONFIG_HABV4_CSF_CRT_PEM
CONFIG_HABV4_IMG_CRT_PEM
A CSF template is located in
include/mach/imx/habv4-imx*-gencsf.h
which is preprocessed
by barebox.
It must be included in the board’s flash header, e.g. for i.MX6:
#include <mach/imx/habv4-imx6-gencsf.h>
Analogous to HABv4 options and a template exist for HABv3.
To verify HAB working as intended, install the barebox-*-s.img
onto the
boot medium and trigger a power-on reset. barebox will read the HAB log on
startup and report any errors it finds. A good unfused boot looks like this:
HABv4: Status: Operation completed successfully (0xf0)
HABv4: Config: Non-secure IC (0xf0)
HABv4: State: Non-secure state (0x66)
HABv4: No HAB Failure Events Found!
To have the bootrom verify the barebox binary, the SRK hash needs to be burnt
into the fuses. As fuses can’t be unburnt, the hab
command should be used
instead of direct device access to not risk writing unrelated fuses:
barebox$ hab -p -s SRK_1_2_3_4_fuse.bin
Afterwards, images signed with a different key will trigger errors at barebox startup, but system will still be able to boot to shell.
To have the BootROM refuse booting differently signed images, the SRK_LOCK
fuse needs to be burnt:
barebox$ hab -p -l
On next startup, barebox will report that the system is now locked:
HABv4: Status: Operation completed successfully (0xf0)
HABv4: Config: Secure IC (0xcc)
HABv4: State: Trusted state (0x99)
HABv4: No HAB Failure Events Found!
This can also be seen with the hab -i
command:
Current SRK hash: <some non-zero value>
secure mode
Similarly, on supported SoCs, the bootrom -l
command will indicate that
device is closed. Example output after booting via imx-usb-loader
:
[e0] Internal use
[11] Boot mode is Boot from Serial Download
[23] Secure config is Closed
[41] FUSE_SEL_VALUE Fuse is blown
[d0] Enters serial download processing
[a0] Image authentication result: PASS (0x000000f0) @3506438144 ticks
[00] End of list
4.13.1.2.1. Secure Boot on i.MX6¶
For most boards, the secure boot process on i.MX6 consist of the following image constellation:
0x0 +---------------------------------+
| Barebox Header |
0x400 +---------------------------------+ -
| i.MX IVT Header | |
| Boot Data +--+ |
| CSF Pointer +--|-+ | Signed Area
+---------------------------------+ | | |
| Device Configuration Data (DCD) | | | |
0x1000 +---------------------------------+ | | |
| Barebox Prebootloader (PBL) |<-+ | |
+---------------------------------+ | |
| Piggydata (Main Barebox Binary) | | |
+---------------------------------+ | -
| Command Sequence File (CSF) |<---+
+---------------------------------+
Here the Command Sequence File signs the complete Header, PBL and piggy data file. This ensures that the whole barebox binary is authenticated. This is possible since the DDR RAM is configured using the DCD and the whole DDR memory area can be used to load data onto the device for authentication. The boot ROM loads the CSF area and barebox into memory and uses the CSF to verify the complete barebox binary.
Boards which do require a boot via SRAM, need changes akin to the implementation for i.MX8MQ described in the next chapter.
4.13.1.2.2. Secure Boot on i.MX8MQ¶
For i.MX8MQ the image has the following design:
0x0 +---------------------------------+
| Barebox Header |
+---------------------------------+
| i.MX IVT Header |
| HDMI Firmware (Signed by NXP) |
+---------------------------------+ -
| i.MX IVT Header | |
| Boot Data +--+ |
| CSF Pointer +--|-+ |
+---------------------------------+ | | | Signed Area
| Device Configuration Data (DCD) | | | |
+---------------------------------+ | | |
| Barebox Prebootloader (PBL) |<-+ | |
| Piggydata Hash (SHA256) +----|-+ |
+---------------------------------+ | | -
| Command Sequence File (CSF) |<---+ |
+---------------------------------+ | -
| Piggydata (Main Barebox Binary) |<-----+ | Hashed Area
+---------------------------------+ -
In contrast to i.MX6, for the i.MX8MQ the piggydata can not be signed together with the PBL binary. The DDR memory is initialized during the start of the PBL, previous to this no access to the DDR memory is possible. Since the Tightly Coupled Memory used for early startup on i.MX8MQ has only 256Kib, the whole barebox can’t be loaded and verified at once, since the complete barebox with firmware has a size of ~500Kib.
The bootrom loads the HDMI firmware unconditionally, since it is signed by NXP. Afterwards the Prebootloader (PBL) is loaded into SRAM and the bootrom proceeds to verify the PBL according to the Command Sequence File (CSF). The verified PBL initializes the ARM Trusted Firmware (TF-A) and DDR RAM. It subsequently loads the piggydata from the boot media and calculates the sha256sum of the piggydata. This is compared to the sha256sum built into the PBL during compile time, the PBL will only continue to boot if the sha256sum matches the builtin sha256sum.
4.13.1.3. Using GPT on i.MX¶
For i.MX SoCs that place a vendor specific header at the +1KiB mark of a
boot medium, special care needs to be taken when partitioning that medium
with GPT. In order to make room for the i.MX boot header, the GPT Partition
Entry Array needs to be moved from its typical location, LBA 2, to an
offset past vendor specific information. One way to do this would be
to use the -j
or --adjust-main-table
option of sgdisk
. For
example, the following sequence
sgdisk -Z <block device>
sgdisk -o -j 2048 -n 1:8192:+100M <block device>
will create a single GPT partition starting at LBA 8192 and would
place the Partition Entry Array starting at LBA 2048, which should leave
enough room for the Barebox/i.MX boot header. Once that is done, the dd
command above can be used to place Barebox on the same medium.
4.13.1.4. Information about the imx-image
tool¶
The imx-image tool can be used to generate imximages from raw binaries. It requires an configuration file describing how to setup the SDRAM on a particular board. This mainly consists of a poke table. The recognized options in this file are:
Header:
|
|
|
The address the binary is uploaded to |
|
The offset of the image header in the image. This should be:
|
Memory manipulation:
|
write |
|
write |
|
write |
|
set set bits in |
|
clear set bits in |
|
do nothing (just waste time) |
<width>
can be one of 8, 16 or 32.
Checking conditions:
|
Poll until condition becomes true.
with
|
Some notes about the mentioned conditions.
until_all_bits_clear
waits until(*addr & mask) == 0
is true
until_all_bits_set
waits until(*addr & mask) == mask
is true
until_any_bit_clear
waits until(*addr & mask) != mask
is true
until_any_bit_set
waits until(*addr & mask) != 0
is true.
4.13.1.5. USB Boot¶
Most boards can be explicitly configured for USB Boot Mode or fall back
to USB Boot when no other medium can be found. The barebox repository
contains a USB upload tool. As it depends on the libusb development headers,
it is not built by default. Enable it explicitly in make menuconfig
and install the libusb development package. On Debian, this can be done
with apt-get install libusb-dev
. After compilation, the tool can be used
with only the image name as argument:
scripts/imx/imx-usb-loader images/barebox-freescale-imx51-babbage.img
4.13.1.6. FlexSPI Boot¶
FlexSPI boot is currently supported on: i.MX8MM, i.MX8MN and i.MX8MP.
To generate FlexSPI/QSPI image(s) the board flash header file must specify:
flexspi_ivtofs
and flexspi_fcfbofs
.
It is recommended to do this via the include/mach/imx/flexspi-imx8m*-cfg.h
header files.
#include <mach/imx/flexspi-imx8mp-cfg.h>
There are two different headers, one for the i.MX8MM and one for the i.MX8MP/N. It’s important to use the correct one because the BootROM expects the IVT and flash configuration block (FCB) on different offsets.
Barebox doesn’t generate a separate FlexSPI image instead the same image used for SD/MMC/USB is extended to support FlexSPI boot. This is done by adding a 2nd IVT header and the required FCB at the required boot offsets.
Barebox also support High Assurance Boot images for QSPI boot mediums. This
feature must be enabled via the CONFIG_HABV4_QSPI
option. The below figures
show a fully featured MMC/SD/USB/FlexSPI image with enabled HAB support for the
i.MX8M family.
i.MX8MM layout:
0x0 +------------------------------------------+
| Barebox Header |
header_gap +------------------------------------------+
| FlexSPI Flash Configuration Block (FCFB) |
header_gap + 0x400 +------------------------------------------+ ---
| i.MX MMC/SD/USB IVT Header | |
| Boot Data +--. |
| CSF Pointer +--|--. |
header_gap + 0x1000 +------------------------------------------+ | | --- |
| i.MX FlexSPI IVT Header | | | | | Signed Area
| Boot Data +--+ | | | MMC/SD/
| CSF Pointer +--|--|--. | Signed Area | USB
header_gap + 0x2000 +------------------------------------------+ | | | | FlexSPI |
| Barebox Prebootloader (PBL) |<-´ | | | |
| Piggydata Hash (SHA256) | | | | |
+------------------------------------------+ | | --- ---
| Command Sequence File (CSF) Slot-0 |<----´ |
+------------------------------------------+ |
| Command Sequence File (CSF) Slot-1 |<-------´
+------------------------------------------+ ---
| Piggydata (Main Barebox Binary) | | Hashed Area
+------------------------------------------+ ---
i.MX8MP/N layout:
0x0 +------------------------------------------+
| Barebox Header |
header_gap +------------------------------------------+ ---
| i.MX MMC/SD/USB IVT Header | |
| Boot Data +--. |
| CSF Pointer +--|--. |
header_gap + 0x400 +------------------------------------------+ | | |
| FlexSPI Flash Configuration Block (FCFB) | | | | Signed Area
header_gap + 0x1000 +------------------------------------------+ | | --- | MMC/SD/
| i.MX FlexSPI IVT Header | | | | | USB
| Boot Data +--+ | | |
| CSF Pointer +--|--|--. | Signed Area |
header_gap + 0x2000 +------------------------------------------+ | | | | FlexSPI |
| Barebox Prebootloader (PBL) |<-´ | | | |
| Piggydata Hash (SHA256) | | | | |
+------------------------------------------+ | | --- ---
| Command Sequence File (CSF) Slot-0 |<----´ |
+------------------------------------------+ |
| Command Sequence File (CSF) Slot-1 |<-------´
+------------------------------------------+ ---
| Piggydata (Main Barebox Binary) | | Hashed Area
+------------------------------------------+ ---
At the moment header_gap
is always 32K for all supported devices.
4.13.2. External Boot Mode¶
The External Boot Mode is supported by the older i.MX SoCs:
i.MX1
i.MX21
i.MX27
i.MX31
i.MX35
The External Boot Mode supports booting only from NOR and NAND flash. On NOR flash, the binary is started directly on its physical address in memory. Booting from NAND flash is more complicated. The NAND flash controller copies the first 2kb of the image to the NAND Controller’s internal SRAM. This initial binary portion then has to:
Set up the SDRAM
Copy the initial binary to SDRAM to make the internal SRAM in the NAND flash controller free for use for the controller
Copy the whole barebox image to SDRAM
Start the image
It is possible to write the image directly to NAND. However, since NAND flash can have bad blocks which must be skipped during writing the image and also by the initial loader, it is recommended to use the barebox_update - update barebox to persistent media command for writing to NAND flash.
4.13.3. i.MX boards¶
Not all supported boards have a description here. Many newer boards also do
not have individual defconfig files, they are covered by imx_v7_defconfig
or multi_v5_v6_defconfig
instead.
- 4.13.3.1. Amazon Kindle 3 “Kindle Keyboard” Model No. D00901
- 4.13.3.2. Amazon Kindle 4/5 (Wi-Fi/No-Touch, Touch and Paperwhite)
- 4.13.3.3. Digi CC-IMX6UL-SBC-PRO
- 4.13.3.4. element14 WaRP7
- 4.13.3.5. Embest RIoTboard
- 4.13.3.6. Embest MarS Board
- 4.13.3.7. Boot Configuration
- 4.13.3.8. Eukrea CPUIMX27
- 4.13.3.9. Garz+Fricke Cupid
- 4.13.3.10. Garz+Fricke Vincell LT
- 4.13.3.11. Ka-Ro TX25
- 4.13.3.12. Ka-Ro TX6x
- 4.13.3.13. Meerkat 96
- 4.13.3.14. NXP i.MX6ULL EVK Evaluation Board
- 4.13.3.15. Boot Configuration
- 4.13.3.16. NXP i.MX8MM EVK Evaluation Board
- 4.13.3.17. DDR Configuration Code
- 4.13.3.18. Build barebox
- 4.13.3.19. Start barebox
- 4.13.3.20. Installing barebox
- 4.13.3.21. NXP i.MX8MN EVK Evaluation Board
- 4.13.3.22. Build barebox
- 4.13.3.23. Installing barebox
- 4.13.3.24. NXP i.MX8MP-EVK board
- 4.13.3.25. Installing barebox
- 4.13.3.26. NXP i.MX8MQ EVK Evaluation Board
- 4.13.3.27. DDR Configuration Code
- 4.13.3.28. Build Barebox
- 4.13.3.29. Boot Configuration
- 4.13.3.30. Phytec phyCARD-i.MX27
- 4.13.3.31. Phytec phyCORE-i.MX27
- 4.13.3.32. Phytec phyCORE-i.MX31 CPU module PCM-037
- 4.13.3.33. Phytec phyCORE-i.MX35
- 4.13.3.34. Protonic Holland PRT8MM board
- 4.13.3.35. Synertronixx SCB9328
- 4.13.3.36. Variscite DT8MCustomBoard with DART-MX8M-PLUS SOM
- 4.13.3.37. Wandboard
- 4.13.3.38. ZII i.MX6 RDU2 Boards
- 4.13.3.39. ZII i.MX7D Based Boards
- 4.13.3.40. ZII i.MX8MQ Based Boards
- 4.13.3.41. ZII VF610 Based Boards