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I'm working with ELinux kernel on ARM cortex-A8.

I know how the bootloader works and what job it's doing. But i've got a question - why do we need bootloader, why was the bootloader born?

Why we can't directly load the kernel into RAM from flash memory without bootloader? If we load it what will happen? In fact, processor will not support it, but why are we following the procedure?

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"Why we cant directly load the kernel into RAM from flash memory" - that is exactly what bootloader is doing. –  Bartek Banachewicz Mar 21 '13 at 12:50
Bartek is right. DIY and I'm pretty sure it's what we call bootloader. –  Yang Mar 21 '13 at 12:51
Even if the code is run directly from flash on-chip, how are you going to load the flash memory? You probably need some firmware to load the flash... –  Martin James Mar 21 '13 at 13:12
If you know how it works, you should be able to understand why it is needed. –  auselen Mar 21 '13 at 13:57
You dont need a bootloader at all, you CAN simply copy the kernel and root file system into ram, setup a few ATAGS and branch to ram. Booting linux is somewhat trivial. The bootloader is to help with development and debugging, but is not required (so long as you have dram init and other hardware init in some software somewhere, often that is done in the bootloader). –  dwelch Mar 22 '13 at 1:11
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up vote 6 down vote accepted

A boot loader is a computer program that loads the main operating system or runtime environment for the computer after completion of the self-tests.

^ From Wikipedia Article

So basically bootloader is doing just what you wanted - copying data from flash into operating memory. It's really that simple.

If you want to know more about boostrapping the OS, I highly recommend you read the linked article. Boot phase consists, apart from tests, also of checking peripherals and some other things. Skipping them makes sense only on very simple embedded devices, and that's why their bootloaders are even simpler:

Some embedded systems do not require a noticeable boot sequence to begin functioning and when turned on may simply run operational programs that are stored in ROM.

The same source

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While the Wikipedia article is useful, it is focused on PC (in the larger sense) boot loaders. Embedded/ARM/Linux platform have some additional issues. Embedded ARM's CPUs have features to reduce component count; specifically eliminating the ROM/NOR flash that typically holds PC BIOS reduces cost. This portion is most relevant: en.wikipedia.org/wiki/Bootloader#Other_kinds_of_boot_sequences –  artless noise Mar 22 '13 at 14:39
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In the context of Linux, the boot loader is responsible for some predefined tasks. As this question is tagged, I think that ARM booting might be a useful resource. Specifically, the boot loader was/is responsible for setting up an ATAG list that describing the amount of RAM, a kernel command line, and other parameters. One of the most important parameters is the machine type. With device trees, an entire description of the board is passed. This makes a stock ARM Linux impossible to boot with out some code to setup the parameters as described.

The parameters allows one generic Linux to support multiple devices. For instance, an ARM Debian kernel can support hundreds of different board types. Uboot or other boot loader can dynamically determine this information or it can be hard coded for the board.

You might also like to look at bootloader info page here at stack overflow.

A basic system might be able to setup ATAGS and copy NOR flash to SRAM. However, it is usually a little more complex than this. Linux needs RAM setup, so you may have to initialize an SDRAM controller. If you use NAND flash, you have to handle bad blocks and the copy may be a little more complex than memcpy().

Linux often has some latent driver bugs where a driver will assume that a clock is initialized. For instance if Uboot always initializes an Ethernet clock for a particular machine, the Linux Ethernet driver may have neglected to setup this clock. This can be especially true with clock trees.

Some systems require boot image formats that are not supported by Linux; for example a special header which can initialize hardware immediately; like configuring the devices to read initial code from. Additionally, often there is hardware that should be configured immediately; a boot loader can do this quickly whereas the normal structure of Linux may delay this significantly resulting in I/O conflicts, etc.

From a pragmatic perspective, it is simpler to use a boot loader. However, there is nothing to prevent you from altering Linux's source to boot directly from it; although it maybe like pasting the boot loader code directly to the start of Linux.

See Also: Coreboot, Uboot, and Wikipedia's comparison. Barebox is a lesser known, but well structured and modern boot loader for the ARM. RedBoot is also used in some ARM systems; RedBoot partitions are supported in the kernel tree.

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The primary bootloader is usually built in into the silicon and performs the load of the first USER code that will be run in the system.

The bootloader exists because there is no standardized protocol for loading the first code, since it is chip dependent. Sometimes the code can be loaded through a serial port, a flash memory, or even a hard drive. It is bootloader function to locate it.

Once the user code is loaded and running, the bootloader is no longer used and the correctness of the system execution is user responsibility.

In the embedded linux chain, the primary bootloader will setup and run the Uboot. Then Uboot will find the linux kernel and load it.

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