I primarily come from an x86 system background where BIOS (Firmware) is responsible for loading a bootloader (like GRUB) from PowerON which in turn loads the OS. I now have been reading the equivalent boot sequence on ARM systems and it seems there are articles on the web making references to two terms: bootrom and bootloader.

Some articles mention that from PowerON the bootloader (like u-boot) is the first thing that gets executed whereas some articles say that from PowerON, a bootrom (usually flashed on processor's internal ROM) gets executed first which in turn loads the bootloader (like uboot) which then loads the OS.

Can anybody provide some clarification on bootrom vs bootloader? Also, I would like to know a name of a popular bootrom that is typically used in ARM systems.

  • 1
    See Why do we need a bootloader... ROM and Flash are devices that hold a boot loader or the software. See the bootloader tag wiki. A bootrom doesn't need to be integrated in a chip; that is the latest fad. Certainly boot flash can be integrated in the CPU. The first code to run is usually the bootstrap loader; this is typically the bootrom as Igor notes. It depends on definition. Commented Mar 27, 2013 at 18:07

2 Answers 2


Here's how I understand the terms.


Bootrom (or Boot ROM) is a small piece of mask ROM or write-protected flash embedded inside the processor chip. It contains the very first code which is executed by the processor on power-on or reset. Depending on the configuration of some strap pins or internal fuses it may decide from where to load the next part of the code to be executed and how or whether to verify it for correctness or validity. Sometimes it may contain additional functionality, possibly usable by user code during or after booting. Some examples:

  • iPhone boot ROM. Embedded in the mask ROM and can't be modified. Loads the next stage boot loader from flash or USB (in DFU mode) and verifies its signature using built-in RSA implementation. Also provides accelerated decryption functions for the next stage bootloader.

  • TI's OMAP4 boot ROM. Can load user code from flash (NOR, NAND, OneNAND), external memory, SD/MMC, USB or UART. Boot order and options are set by strap (SYSBOOT) pins. Provides some functionality for later stages (cache/TLB management etc.)

  • NXP's LPCxxxx series Boot ROM. Placed in a hidden portion of the internal flash which is mapped at 0 on power-on. Implements CRP (code read protection), ISP (In-System Programming) which allows to upload and flash new code over UART. If a valid user code is in flash (needs to have proper checksum), maps it to 0 and jumps to it. A part of bootrom remains mapped to provide IAP (In-Application Programming) and some other services.


Bootloader is responsible for finding and loading the final OS or firmware which is supposed to run on the chip. One main difference from bootrom is that it's usually in writable flash and can be replaced or upgraded.

Sometimes bootrom can perform the job of the bootloader. For example, OMAP's bootrom is complex enough (it can parse FAT32!) that you can probably have it load and start a Linux kernel directly.

However, in many cases a separate bootloader is used, either because the bootrom is not capable enough (or absent), or because extra flexibility is needed. It can be very simple (load kernel from a fixed flash location in RAM and jump to it), or can be much more complicated. For example, U-Boot is a like a mini-OS by itself - it has a console, some commands, allows you break the boot process and e.g. modify the kernel command line arguments or even load the kernel from a different location (SD/MMC or USB), run some tests and so on.

Bootloaders are usually used when you have a more or less complex OS which may need some set up before it can be started. Smaller microcontrollers like NXP's LPC series usually use a monolithic firmware so they can get by without it (however, there may be custom bootloaders for them too).

On the very simplest chips there may be no boot ROM or boot loader at all - they just try to fetch and execute instructions from a fixed startup address. In fact, most x86 chips to this day work like this - they just start executing code at FFFFFFF0 with the expectation that the chipset has mapped the BIOS flash chip there. Here, you can say that BIOS is the bootloader (though it also provides services to the OS, similar to bootrom).

  • 1
    +1, Especially the first sentence; answers depend on who/when/where you talk to someone. I think the trend to ROM's built in to the CPU is security related. Unix's init can be looked at as a bootloader or boot-task for instance; the perspective is what is being booted. Bootstrap is the origin of boot in these terms. Commented Mar 27, 2013 at 18:51
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    The trend for SoCs to have mask-PROM with the boot-ROM is not necessarily driven by security but rather reducing the 'glue' components required around the SoC device: even reading NAND Flash devices is non-trivial and the devices are not directly addressed, so the alternative would to use a small NOR flash device for this purpose. Indeed, some phones are actually built like this. This OMAP4's booting arrangement allows booting from NAND and MMC with no glue - both handing directly of device IO pins.
    – marko
    Commented Mar 27, 2013 at 19:06
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    @Marko I meant as oppose to built-in NOR flash, as you say. Many chips had this and that made it easy for a customer to flash code via JTAG, etc for their design. The flash cells are slightly bigger than ROM, but I don't think that stopped them. When the SOC's started to do code verification, the vendor can't do this in silicon and have to have code libraries. As this remains static for all customers, they transitioned to ROMs. In truth, it is probably less glue, more flexibility and more security not just one item. Commented Mar 27, 2013 at 21:50
  • wonderful article.I now understand the clarity. Just to add one point here. Bootrom is a small piece of swcode provided by chip vendors.
    – vkulkarni
    Commented Oct 18, 2013 at 10:29
  • Hi @Igor , one question, Is Boot-ROM code is written in Assembly language? or is it also possible to write using VHDL/Verilog? Commented Feb 2, 2016 at 9:08

ARM CPUs can have flash ROM i.e. the chip mask includes some code to load the BIOS. A lot has been said about the GPU doing MOST of the boot sequence but I have my reservations. Does the GPU run ARM code? No. So, in the face of the official version of the boot sequence, I see from the original GPU data, 32K is copied into L2 cache (since DRAM hasn't been switched on) and from that point, the CPU runs code to load the BIOS from the SDRAM. No Trustzone settings are enabled in the boot sequence. That allows a bare-metal coder (embedded systems) to use the vast majority of the CPU FlashROM as vector tables so you can poll the Hardware and set up vectors as required. The TZ stuff has no useful properties since The Smurf Suite proves that it isn't secure. But if you use that space for vectors, if someone reflashes, the OS dies.

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