The x86 CPU begins execution at physical address 0xFFFFFFF0. There at the end of the address space the BIOS ROM is located. The first instruction the CPU executes from the ROM is far jump which causes the CS segment to be reloaded so the next instruction is executed from within the physical region 0x000F0000 - 0x000FFFFF.

What causes the ROM to respond on both regions? Is there some special address decoding logic on PC? I found comment in Bochs source code that states that last 128K of BIOS ROM is mapped to 0xE0000 - 0xFFFFF. However I cannot find more info about this. Clearly this is something PC specific since I have x86 embedded board and such mirroring does not happen there. I can only use near jump.


2 Answers 2


On the PC there's always some address decoding logic involved because there are a few "holes/windows" in the physical address space through which the BIOS ROM and I/O devices (e.g. video card) are accessible instead of the RAM. That's by design, for compatibility reasons, so older programs can still run on newer computers.

As for the initial address at which the CPU starts execution after a reset, if you look at the documentation, you will see that Pentium-class CPUs start with this:

If you follow the normal real-mode addressing scheme, the physical address should be CS.Selector*16+IP, or, with the values substituted, 0xFFFF0. However, the CPU actually calculates the address using CS.Base+(E)IP (in the real and 16/32-bit protected mode, but not in virtual 8086 or 64-bit protected mode), hence the first address that the CPU requests from the memory is going to be 0xFFFFFFF0. Your inability to use far jumps to code within the ROM at that high address may be due to the fact that loading into CS will reset CS.Base to 16 * the new value of CS.Selector. So, jumping to, say, 0xF000:0xFFF0 will transfer control to 0xFFFF0 instead of 0xFFFFFFF0 and unless the ROM is also mapped at that low location in the memory and the code in it is suited for running with CS(.Selector)=0xF000, it's not going to run.

Also, neither the CPU nor the circuitry around it has to support all 32 (or more) address lines if the PC is limited to have at most 16MB (as it was on i80286 and i80386SX) or 4GB (as it was on i80386DX/original i80386 and i80486) or 240-52 bytes (on 64-bit capable Pentium-class CPUs) and if that's the case, if a number of high bits in the physical address space are ignored, execution can be said to effectively start at an address lower than the theoretical maximum - 16, e.g. 0x00FFFFF0 (i80286/i80386SX).

If you need to resolve problems with your board, see its documentation and schematics to find out how the ROM is mapped into the physical address space on it.

  • Thanks. I'm particularly interested in the assertion "unless the ROM is also mapped at that low location". So is it always true for PC/AT compatible architecture that the ROM is mapped at both locations?
    – manison
    Oct 18, 2011 at 11:27
  • 3
    @manison: The CPU requires the first instructions to be at maximum-16, while compatibility requires the rest of the ROM BIOS code to be available below the 1MB point (at least, some parts of it). So, if those first instructions are stored in the same ROM, it must be mapped in 2 distinct locations. But if the first instruction in a specific PC brand is a far jump to somewhere in the ROM (say, 0xF000:0xFFF0), the hardware implementation may instead of providing a second mapping simply respond with the byte sequence of that far jump instruction when the memory from maximum-16 is read. Oct 18, 2011 at 19:06
  • It seems Z80 has a better design, CPU starts at address 0 when starting, Interrupt vectors placed after startup address. May 16, 2012 at 9:46

ROM responds to both regions due to memory aliasing. According to this Dr. Dobbs article written by Pete Dice of Intel:

For legacy option ROMs and BIOS memory ranges, Intel chipsets usually come with memory aliasing capabilities that allow access to memory below 1 MB to be routed to or from DRAM or nonvolatile storage located just under 4 GB. The registers that control this aliasing are typically referred to as Programmable Attribute Maps (PAMs). Manipulation of these registers may be required before, during, and after firmware shadowing. The control over the redirection of memory access varies from chipset to chipset For example, some chipsets allow control over reads and writes, while others allow control over reads only.

Check out the article for more low level details on device memory mapping and memory initialization, configuration, and testing.

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