Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was reading about how Virtual Memory and Memory management works in an Operating System. I understood how each process has its own contiguous logical address space. This address space need not be contiguous in physical memory. For this purpose, paging is used. The page tables are used to do the mapping from logical address to a physical address. The logical address is divided in two parts, first part gives the logical page number, which using the page table is translated to the physical page number, and the second part is offset into that page. Thus the contents from memory are retrieved.
Virtual memory is an extension of this, where all the pages need not be in main memory, and can be brought there through page faults.

Using my understanding I solved the 4th question on this page: www.ics.uci.edu/~bic/courses/JaverOS/ch8-ex.pdf

I got my answers wrong, and I have no clue what the right answers are. This is the way I did it:

From the diagram in the question, Page table for Process P1 will look like this according to me:

So when process P1 makes a reference to 0 i.e is 0000 in 4 bit binary, we divide 
it as 00|00. 
Thus logical page no = 00 and offset = 00.
From the page table, we can see 0 is mapped to 4th physical frame. 
Offset is also 00 here. So I get the 0th entry(offset) in the 4th frame. 
The content at this memory location(i.e Frame No. 4, offset 0) is 0.

Why is this wrong? Can anyone help?

share|improve this question
If someone wants to down-vote the question, please indicate why in the comment! –  rgamber Mar 2 '12 at 22:43
Your English is really hard to read, I had a hard time seeing what your answer was (and you're not giving a complete answer). Maybe try to work on that first. –  Tobu Mar 2 '12 at 23:01
Sorry, English is not my first language. I have tried to rephrase the question. I would really appreciate an answer for this as I am studying for my exam, and cannot continue with unclear concepts. –  rgamber Mar 2 '12 at 23:17
Oh wow, I had the same professor at UCI. –  Babak Naffas Mar 6 '12 at 23:49
@Babak Gosh, I hope you kept the exam material. –  Tobu Mar 6 '12 at 23:52

2 Answers 2

up vote 2 down vote accepted

I'll start with virtual address 8, it should illustrate things better.

8 = 2×4 + 0. The physical address is stored at offset 0 of page 2 of the process. We look up the second page. For P1, page 2's address is stored at PA 4 + 2, and it is 28. We look up the contents of PA 28, and get value 0. For P2, page 2's address is stored at PA 12 + 2, it is 24, the contents of PA 24 are 5.

Now with virtual address 15, which illustrates the exceptional cases.

15 = 3×4 + 3. The physical address is stored at offset 3 of the process's page 3. For P1, page 3's address is stored at PA 4 + 3, which contains -2. The sign bit indicates the page is outside physical memory, which means there will be a hard page fault (a situation the OS handles exceptionally, but not an error). For P2, page 3's address is stored at PA 12 + 3, which some special mechanism (a poison value, an external frame table?) tells us is invalid. This is an error, and gets reported as a segmentation fault.

One last example with VA 7 and P1 to explain offsets:

7 = 1×4 + 3. The physical address is stored at offset 3 of P1's page 1. Page 1 is at PA 8, offset 3 of page 1 is at PA 8+3.

share|improve this answer
Thanks for the detailed explanation! I have a doubt though. I thought a page table was supposed to map between a logical page, and it's physical location. For eg. When VA = 8, logical page is 2 as you said. The physical page then would be 4+2=6. Shouldn't I look in page 6 at offset 0 then? Where am I understanding wrong? –  rgamber Mar 3 '12 at 17:27
Virtual addresses are dereferenced twice. 4+2 is the physical address of the physical address of P1's second page. Your reasoning seems to ignore the memory contents of P1's page table. –  Tobu Mar 3 '12 at 17:43
Oh, the Virtual Adresses being dereferenced twice was not clearly mentioned in my book. Thanks. I was indeed ignoring the memory contents in a page table. So now, what if for VA=8, the content at 6 was 39 instead of 28, and the page offset was 2. Then would I be taking 29 as the base address of the frame, and offset by 2 i.e read contents at 31 as the final answer?I really appreciate your help. –  rgamber Mar 3 '12 at 18:06
I am still confused here, in which case will the page offset, i.e. the last two bits of the reference be used then? Ef. for VA = 15, if the content for P1 was valid, say it was 27, then? –  rgamber Mar 6 '12 at 21:47
@rgamber the last two bits would be used as an offset into the page. The physical address would be 27+3. 27 is a less likely value because it is unaligned (the page tables of P1 and P2 only contain multiples of 4). –  Tobu Mar 6 '12 at 23:26

I'm assuming the diagram shows the physical memory and physical addresses on the left. It wouldn't make sense to let p1 and p2 directly access their own and each other's page tables.

Given that, for virtual address 0 you fetch -45 from page frame 1 for p1 and 0 from page frame 3 for p2.

For VA = 1 you fetch 8 and -12 respectively.

For VA = 4 you fetch nothing because that's outside of the defined page tables for p1 and p2 (that is how I interpret "The size of each page and page table is 4" and "The page table of p1 begins at address 4; the page table of p2 begins at address 12."; if my interpretation is wrong, then the problem statement is incorrect as well). Ditto for the rest of the VAs because they're greater than or equal to 4 and fall outside the defined page tables too.

You can then work out the final answers from here.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.