From a software point of view, what is the latency between an instruction that dirties a memory page and when the core actually marks the page dirty in the Page Table Entry (PTE)?

In other words, if an instruction dirties a page, can the very next instruction read the PTE and see the dirty bit set?

I don't care about the actual elapsed cycles, only if there is a software visible window in which the dirty bit is not yet set. I can't seem to find any guarantees in the reference manuals.

3 Answers 3


From the AMD's manual (circa 2005), Volume 2: System Programming:

5.4 Page-Translation-Table Entry Fields ... Dirty (D) Bit. Bit 6. This bit is only present in the lowest level of the page-translation hierarchy. It indicates whether the pagetranslation table or physical page to which this entry points has been written. The D bit is set to 1 by the processor the first time there is a write to the physical page.

Ditto from Intel (circa 2006), Volume 3-A: System Programming Guide, Part 1:

3.7.6 Page-Directory and Page-Table Entries ... Dirty (D) flag, bit 6 Indicates whether a page has been written to when set. (This flag is not used in page-directory entries that point to page tables.) Memory management software typically clears this flag when a page is initially loaded into physical memory. The processor then sets this flag the first time a page is accessed for a write operation.


From the latest Intel manual (vol 3A, System Programming Guide): Automatic Locking The operations on which the processor automatically follows the LOCK semantics are as follows: ... When updating page-directory and page-table entries — When updating page-directory and page-table entries, the processor uses locked cycles to set the accessed and dirty flag in the page-directory and page-table entries.

From the rest of the text in sections 8.1 and 8.2 it follows that once the CPU sets the dirty bit using the locked operation, the other CPUs should start seeing the updated value.

Of course, you may have a race condition in that you first read the dirty bit as 0 on one CPU (or in one of its threads) and later another CPU (or another thread on the same CPU) causes this bit to be set to 1, but that isn't any unusual.

  • 1
    I read the docs too. These don't say if the instruction that causes the core to set the dirty bit is serializing or fencing the instructions behind it. Normally reads can pass writes if there is no data hazard, but this is a really tricky case where the hazard is at a different address (the PTE) from the address of the write itself. I want to know if the the pipeline is checking this case.
    – srking
    Commented Oct 28, 2011 at 16:51
  • @srking: a core always observes its own actions to happen in program order. OoO exec always preserves that illusion. I think the wording implies that store to page + load from PTE on this core would observe the change. From another core, IDK if the page table update happens before or after the actual data; if it's before then you'd definitely see the dirty bit from another core if you saw the value from the data store. (Because they're both at least release strength, and the page table update is effectively seq-cst like lock or) Commented Jan 15, 2020 at 23:20

AMD64 Architecture Programmer’s Manual Volume 2: System Programming (revision 3.22, Sept. 2012)

In general, Dirty bit updates are ordered with respect to other loads and stores, although not necessarily with respect to accesses to WC memory; in particular, they may not cause WC buffers to be flushed. However, to ensure compatibility with future processors, a serializing operation should be inserted before reading the D bit.

(Emphasis mine.)


According to page 2033 of this document, Intel x86 caches information about the page table. The text states that if the dirty bit is cleaned by software, there's a possibility that the CPU still sees it as equal to 1.

Now, for the question: if the CPU caches the dirty bit, there's a possibility that the update to the PTE (page-table-entry) does not take place immediately. It could be delayed by a cache-write-back policy.

Page 1651 of the same document describes the WBINVD instruction, that flushes internal caches. It does not say that this includes all data cached by the CPU.

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