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Historically, the reset_cpu() function had an `addr` parameter which was meant to pass in an address of the reset vector location, where the CPU should reset to. This feature is no longer used anywhere in U-Boot as all reset_cpu() implementations now ignore the passed value. Generic code has been added which always calls reset_cpu() with `0` which means this feature can no longer be used easily anyway. Over time, many implementations seem to have "misunderstood" the existence of this parameter as a way to customize/parameterize the reset (e.g. COLD vs WARM resets). As this is not properly supported, the code will almost always not do what it is intended to (because all call-sites just call reset_cpu() with 0). To avoid confusion and to clean up the codebase from unused left-overs of the past, remove the `addr` parameter entirely. Code which intends to support different kinds of resets should be rewritten as a sysreset driver instead. This transformation was done with the following coccinelle patch: @@ expression argvalue; @@ - reset_cpu(argvalue) + reset_cpu() @@ identifier argname; type argtype; @@ - reset_cpu(argtype argname) + reset_cpu(void) { ... } Signed-off-by: Harald Seiler <hws@denx.de> Reviewed-by: Simon Glass <sjg@chromium.org> |
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.. | ||
config.mk | ||
iot_devkit.c | ||
Kconfig | ||
MAINTAINERS | ||
Makefile | ||
README | ||
u-boot.lds |
================================================================================ Useful notes on bulding and using of U-Boot on ARC IoT Development Kit (AKA IoTDK) ================================================================================ BOARD OVERVIEW The DesignWare ARC IoT Development Kit is a versatile platform that includes the necessary hardware and software to accelerate software development and debugging of sensor fusion, voice recognition and face detection designs. The ARC IoT Development Kit includes a silicon implementation of the ARC Data Fusion IP Subsystem running at 144 MHz on SMIC's 55-nm ultra-low power process, and a rich set of peripherals commonly used in IoT designs such as USB, UART, SPI, I2C, PWM, SDIO and ADCs. The board is shipped with pre-installed U-Boot in non-volatile memory (eFlash) so on power-on user sees U-Boot start header and command line prompt which might be used for U-Boot environment fine-tuning, manual loading and execution of user application binaries etc. The board 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 user applications, data files etc. * USB OTG connector - U-Boot may access USB mass-storage devices attached to this connector. Note only FAT file-system is supported. It might be used for storing user application binaries as well as micro SD-card mentioned above. * The following memories are avaialble on the board: - eFlash: 256 KiB @ 0x0000_0000 A non-volatile memory from which ARC core may execute code directly. Still is is not direcly writable, thus this is not an ordinary RAM. - ICCM: 256 KiB @ 0x2000_0000 Instruction Closely Coupled Memory - fast on-chip memory primary used for code being executed, still data could be placed in this memory too. In that sense it's just a general purpose RAM. - SRAM: 128 KiB @ 0x3000_0000 On-chip SRAM. From user perspective is the same as ICCM above. - DCCM: 128 KiB @ 0x8000_0000 Data Closely Coupled Memory is similar to ICCM with a major difference - ARC core cannot execute code from DCCM. So this is very special RAM only suitable for data. BUILDING U-BOOT 1. Configure U-Boot: ------------------------->8---------------------- make iot_devkit_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 binary image to be put in "ROM": ------------------------->8---------------------- make u-boot.bin ------------------------->8---------------------- EXECUTING U-BOOT 1. The IoTDK board is supposed to auto-start U-Boot image stored in eFlash on power-on. Note it's possible to update that image - follow instructions in user's manual. 2. Though it is possible to load and start U-Boot as a simple Elf file via JTAG right in ICCM. For that it's required to re-configure U-Boot so it gets linked to ICCM address 0x2000_0000 (remember eFlash is not direcly writable). Run U-Boot's configuration utility with "make menuconfig", go to "Boot images" and change "Text Base" from default 0x00000000 to 0x20000000. Exit & save new configuration. Now run "make mdbtrick" to build new Elf. 2.1. In case of proprietary MetaWare debugger run: ------------------------->8---------------------- mdb -digilent u-boot ------------------------->8---------------------- USING U-BOOT Note due to limited memory size it's supposed that user will run binary images of their applications instead of loading Elf files. 1. To load and start application binary from micro SD-card execute the following commands in U-Boot's shell: ------------------------->8---------------------- fatload mmc 0 0x20000000 yourapp.bin go 0x20000000 ------------------------->8---------------------- 2. To load and start application binary from USB mass-storage device execute the following commands in U-Boot's shell: ------------------------->8---------------------- usb start fatload usb 0x20000000 yourapp.bin go 0x20000000 ------------------------->8---------------------- 3. To have a sequence of commands executed on U-Boot start put those commands in "bootcmd" with semicolon between them. For example to get (1) done automatically: ------------------------->8---------------------- setenv bootcmd fatload mmc 0 0x20000000 yourapp.bin\; go 0x20000000 saveenv ------------------------->8---------------------- 4. To reboot the board just run: ------------------------->8---------------------- reset ------------------------->8----------------------