Reading intel x86 Manual and other sources, i did not understand the difference between DPL (Descriptor privilege level) and RPL (Requested privilege level). Why is there necessity to have both? Thank you so much

1 Answer 1


Good question.

CPL vs. DPL vs. RPL

To make this simpler, let's first just consider CPL and DPL:

  • The CPL is your current privilege level.
  • The DPL is the privilege level of a segment. It defines the minimum1 privilege level required to access the segment.
  • Privilege levels range from 0-3; lower numbers are more privileged
  • So: To access a segment, CPL must be less than or equal to the DPL of the segment

RPL is a privilege level associated with a segment selector. A segment selector is just a 16-bit value that references a segment. Every memory access (implicitly2 or otherwise) uses a segment selector as part of the access.

When accessing a segment, there are actually two checks that must be performed. Access to the segment is only allowed if both of the following are true:

  • CPL <= DPL
  • RPL <= DPL

So even if CPL is sufficiently privileged to access a segment, the access will still be denied if the segment selector that references that segment is not sufficiently privileged.

The motivation behind RPL

What's the purpose of this? Well, the reasoning is a bit dated now, but the Intel documentation offers a scenario that goes something like this:

  • Suppose the operating system provides a system call that accepts a logical address (segment selector + offset) from the caller and writes to that address
  • Normal applications run with a CPL of 3; system calls run with a CPL of 0
  • Let's say some segment (we'll call it X) has a DPL of 0

An application would ordinarily not be able to access the memory in segment X (because CPL > DPL). But depending on how the system call was implemented, an application might be able to invoke the system call with a parameter of an address within segment X. Then, because the system call is privileged, it would be able to write to segment X on behalf of the application. This could introduce a privilege escalation vulnerability into the operating system.

To mitigate this, the official recommendation is that when a privileged routine accepts a segment selector provided by unprivileged code, it should first set the RPL of the segment selector to match that of the unprivileged code3. This way, the operating system would not be able to make any accesses to that segment that the unprivileged caller would not already be able to make. This helps enforce the boundary between the operating system and applications.

Then and now

Segment protection was introduced with the 286, before paging existed in the x86 family of processors. Back then, segmentation was the only way to restrict access to kernel memory from a user-mode context. RPL provided a convenient way to enforce this restriction when passing pointers across different privilege levels.

Modern operating systems use paging to restrict access to memory, which removes the need for segmentation. Since we don't need segmentation, we can use a flat memory model, which means segment registers CS, DS, SS, and ES all have a base of zero and extend through the entire address space. In fact, in 64-bit "long mode", a flat memory model is enforced, regardless of the contents of those four segment registers. Segments are still used sometimes (for example, Windows uses FS and GS to point to the Thread Information Block and 0x23 and 0x33 to switch between 32- and 64-bit code, and Linux is similar), but you just don't go passing segments around anymore. So RPL is mostly an unused leftover from older times.

RPL: Was it ever necessary?

You asked why it was a necessity to have both DPL and RPL. Even in the context of the 286, it wasn't actually a necessity to have RPL. Considering the above scenario, a privileged procedure could always just retrieve the DPL of the provided segment via the LAR instruction, compare this to the privilege of the caller, and preemptively bail out if the caller's privilege is insufficient to access the segment. However, setting the RPL, in my opinion, is a more elegant and simpler way of managing segment accesses across different privilege levels.

To learn more about privilege levels, check out Volume 3 of Intel's software developer manuals, particularly the sections titled "Privilege Levels" and "Checking Caller Access Privileges".

1 Technically, the DPL can have different meanings depending on what type of segment or gate is being accessed. For the sake of simplicity, everything I describe applies to data segments specifically. Check the Intel docs for more information
2 For example, the instruction pointer implicitly uses the segment selector stored in CS when fetching instructions; most types of data accesses implicitly use the segment selector stored in DS, etc.
3 See the ARPL instruction (16-bit/32-bit protected mode only)

  • 2
    Note that arpl is not encodable in 64bit mode. Opcode 63 is repurposed to movsxd r64, r/m32. This goes along with segment functionality in generally in 64bit mode being drastically simplified. Apr 14, 2016 at 20:44
  • @Peter Cordes True, I updated my answer to mention this. And that, more generally speaking, the applicability of segment protection is limited in modern operating systems. +1 Apr 25, 2016 at 21:51
  • Nice update, but making 64bit mode backwards work like 32bit mode isn't the major goal. It's similarity of implementation that's the issue. Just like they could have fixed a lot of the bad decisions with instruction encoding (setcc r/m8 instead of r/m32 being one of my pet peeves), they kept things as similar as possible so they could share as many transistors as possible in the decoders and execution units. Apr 25, 2016 at 21:59
  • @PeterCordes Ahh, the comment about backwards compatibility was meant to explain why it remains a part of protected mode, not long mode. I'll remove that clause so it's clearer Apr 25, 2016 at 22:59
  • So how do x64 avoid write to segment X if segment no longer exist? Or do they check form of address?
    – l4m2
    Nov 19, 2021 at 12:16

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