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aa813c24d5
The hack to find the number of sectors turns out to be sensitive to the host kernel. This is a workaround until we find something in /proc or /sys that has the same info in a more accessible way. Signed-off-by: Christopher Hall <hsw@openmoko.com> |
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.. | ||
include | ||
src | ||
tools | ||
6410-partition-sd.sh | ||
build | ||
config.mk | ||
dfu-qi | ||
gta02-qi.ocd | ||
Makefile | ||
openocd-openmoko-debug-6410.cfg | ||
README |
Qi == Qi (named by Alan Cox on Openmoko kernel list) is a minimal bootloader that "breathes life" into Linux. Its goal is to stay close to the minimum needed to "load" and then "boot" Linux -- no boot menus, additional peripheral init or private states. What's wrong with U-Boot, they keep telling people to not reinvent the wheel? ============================================================================= U-Boot is gradually becoming a simplified knockoff of Linux. After using it a while, it became clear we were cutting and pasting drivers into U-Boot from Linux, cutting them down and not having a plan to maintain the U-Boot versions as the Linux ones were changed. We decided that we would use full Linux for things that Linux is good at and only have the bootloader do the device init that is absolutely required before Linux can be pulled into memory and started. In practice since we had a working U-Boot implementation it meant cutting that right down to the bone (start.S mainly for s3c2442) and then building it up from scratch optimized to just do load and boot. Samsung - specific boot sequence ================================ Right now Qi supports Samsung "steppingstone" scheme devices, but in fact it's the same in processors like iMX31 that there is a small area of SRAM that is prepped with NAND content via ROM on the device. There's nothing that stops Qi use on processors without steppingstone, although the ATAG stuff assumes we deal with ARM based processor. Per-CPU Qi ========== Qi has a concept of a single bootloader binary created per CPU type. The different devices that use that CPU are all supported in the same binary. At runtime after the common init is done, Qi asks each supported device code in turn if it recognizes the device as being handled by it, the first one to reply that it knows the device gets to control the rest of the process. Consequently, there is NO build-time configuration file as found on U-Boot except a make env var that sets the CPU type being built, eg: make CPU=s3c6410 Booting Heuristics ================== Qi has one or more ways to fetch a kernel depending on the device it finds it is running on, for example on GTA02 it can use NAND and SD card devices. It goes through these device-specific storage devices in order and tries to boot the first viable kernel it finds, usually /boot/uImage.bin. The kernel commandline used is associated with the storage device, this allows the correct root= line to be arrived at without any work. The inability to set the Qi kernel commandline externally is deliberate, two otherwise identical devices differing by the kernel commandline or other "environment" is not good. A whole class of bugs and support issues around private bootloader state are therefore avoided. If no kernel image can be found, Qi falls back to doing a memory test. Initrd support ============== Initrd or initramfs in separate file is supported to be loaded at given memory address in addition to kernel image. The ATAGs are issued accordingly. Functional Differences from U-Boot on GTA02 =========================================== - Backlight is not enabled until Linux starts after a few seconds - kernel loglevel is set to NOT output gobs of text to the screen - On GTA02 will ALWAYS boot from uSD if first partition is ext2 and contains /boot/uImage.bin, otherwise boots from NAND - On GTA03 will ALWAYS boot from uSD second partition if /boot/uImage.bin is present otherwise try the third / backup partition - No startup splash screen - Way faster - There is no concept of "staying in the bootloader". The bootloader exits to Linux as fast as possible, that's all it does. - USB is not started until Linux starts around 5 seconds after boot, there is no DFU.