mirror of
https://github.com/u-boot/u-boot.git
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0552e104a5
Since U-Boot tools are being built anyways it's much nicer to use them instead of relying on some of them bein installed on build host (which might easily not be the case). Signed-off-by: Alexey Brodkin <abrodkin@synopsys.com> |
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|---|---|---|
| .. | ||
| clk-lib.c | ||
| clk-lib.h | ||
| config.mk | ||
| env-lib.c | ||
| env-lib.h | ||
| headerize-hsdk.py | ||
| hsdk.c | ||
| Kconfig | ||
| MAINTAINERS | ||
| Makefile | ||
| README | ||
================================================================================
Useful notes on bulding and using of U-Boot on ARC HS Development Kit (AKA HSDK)
================================================================================
BOARD OVERVIEW
The DesignWare ARC HS Development Kit is a ready-to-use platform for rapid
software development on the ARC HS3x family of processors.
For more information please visit:
https://www.synopsys.com/dw/ipdir.php?ds=arc-hs-development-kit
User guide is availalble here:
https://github.com/foss-for-synopsys-dwc-arc-processors/ARC-Development-Systems-Forum/wiki/docs/ARC_HSDK_User_Guide.pdf
It has the following features useful for U-Boot:
* On-board 2-channel FTDI TTL-to-USB converter
- The first channel is used for serial debug port (which makes it possible
to use a serial connection on pretty much any host machine be it
Windows, Linux or Mac).
On Linux machine typucally FTDI serial port would be /dev/ttyUSB0.
There's no HW flow-control and baud-rate is 115200.
- The second channel is used for built-in Digilent USB JTAG probe.
That means no extra hardware is required to access ARC core from a
debugger on development host. Both proprietary MetaWare debugger and
open source OpenOCD + GDB client are supported.
- Also with help of this FTDI chip it is possible to reset entire
board with help of a special `rff-ftdi-reset` utility, see:
https://github.com/foss-for-synopsys-dwc-arc-processors/rff-ftdi-reset
* Micro SD-card slot
- U-Boot expects to see the very first partition on the card formatted as
FAT file-system and uses it for keeping its environment in `uboot.env`
file. Note uboot.env is not just a text file but it is auto-generated
file created by U-Boot on invocation of `saveenv` command.
It contains a checksum which makes this saved environment invalid in
case of maual modification.
- There might be more useful files on that first FAT partition like
Linux kernl image in form of uImage (with or without built-in
initramfs), device tree blob (.dtb) etc.
- Except FAT partition there might be others following the first FAT one
like Ext file-system with rootfs etc.
* 1 Gb Ethernet socket
- U-Boot might get payload from TFTP server. This might be uImage, rootfs
image and anything else.
* 2 MiB of SPI-flash
- SPI-flahs is used as a storage for image of an application auto-executed
by bootROM on power-on. Typically U-Boot gets programmed there but
there might be other uses. But note bootROM expects to find a special
header preceeding application image itself so before flashing anything
make sure required image is prepended. In case of U-Boot this is done
by invocation of `headerize-hsdk.py` with `make bsp-generate` command.
BUILDING U-BOOT
1. Configure U-Boot:
------------------------->8----------------------
make hsdk_defconfig
------------------------->8----------------------
2. To build Elf file (for example to be used with host debugger via JTAG
connection to the target board):
------------------------->8----------------------
make mdbtrick
------------------------->8----------------------
This will produce `u-boot` Elf file.
3. To build artifacts required for U-Boot update in n-board SPI-flash:
------------------------->8----------------------
make bsp-generate
------------------------->8----------------------
This will produce `u-boot.head` and `u-boot-update.scr` which should
be put on the first FAT partition of micro SD-card to be inserted in the
HSDK board.
EXECUTING U-BOOT
1. The HSDK board is supposed to auto-start U-Boot image stored in on-board
SPI-flash on power-on. For that make sure DIP-switches in the corner of
the board are in their default positions: BIM in 1:off, 2:on state
while both BMC and BCS should be in 1:on, 2:on state.
2. Though it is possible to load U-Boot as a simple Elf file via JTAG right
in DDR and start it from the debugger.
2.1. In case of proprietary MetaWare debugger run:
------------------------->8----------------------
mdb -digilent -run -cl u-boot
------------------------->8----------------------
UPDATION U-BOOT IMAGE IN ON-BOARD SPI-FLASH
1. Create `u-boot.head` and `u-boot-update.scr` as discribed above with
`make bsp-generate` command.
2. Copy `u-boot.head` and `u-boot-update.scr` to the first the first FAT
partition of micro SD-card.
3. Connect USB cable from the HSDK board to the developemnt host and
fire-up serial terminal.
3. Insert prepared micro SD-card in the HSDK board, press reset button
and stop auto-execution of existing `bootcmd` pressing any key in serial
terminal and enter the following command:
------------------------->8----------------------
mmc rescan && fatload mmc 0:1 ${loadaddr} u-boot-update.scr && source ${loadaddr}
------------------------->8----------------------
Wait before you see "u-boot update: OK" message.
4. Press RESET button and enjoy updated U-Boot version.