Consider a virtual memory system with a 38-bit virtual byte address, 1KB pages and 512 MB of physical memory. What is the total size of the page table for each process on this machine, assuming that the valid, protection, dirty and use bits take a total of 4 bits, and that all the virtual pages are in use? (assume that disk addresses are not stored in the page table.)
Well, if the question is simply "what is the size of the page table?" irrespective of whether it will fit into physical memory, the answer can be calculated thus:
First physical memory. There are 512K pages of physical memory (512M / 1K). This requires 19 bits to represent each page. Add that to the 4 bits of accounting information and you get 23 bits.
Now virtual memory. With a 38-bit address space and a 10-bit (1K) page size, you need 228 entries in your page table.
Therefore 228 page table entries at 23 bits each is 6,174,015,488 bits or 736M.
That's the maximum size needed for a single-level VM subsystem for each process.
Now obviously that's not going to work if you only have 512M of physical RAM so you have a couple of options.
Let's look a little closer at option 3.
If we allow 32M for the primary paging table and give each entry 4 bytes (32 bits: only 23 are needed but we can round up for efficiency here), this will allow 8,388,608 pages for the secondary page table.
Since each of those secondary page table pages is 1K long (allowing us to store 256 secondary page table entries at 4 bytes each), we can address a total of 2,147,483,648 virtual pages.
This would allow 8,192 fully-loaded (i.e., using their entire 28-bit address space) processes to run side by side, assuming you have a fair chunk of disk space to store the non-resident pages.
Now obviously the primary paging table (and the VM subsystem, and probably a fair chunk of the rest of the OS) has to stay resident at all times. You cannot be allowed to page out one of the primary pages since you may well need that page in order to bring it back in :-)
But that's a resident cost of only 32M of the 512M for the primary paging table, much better than the (at a minimum, for one fully-loaded process) of 736M.
size of the page table= total no of page table entries*size of the page table entry
STEP 1:FINDING THE NO OF ENTRIES IN PAGE TABLE:
so there are 2^28 entries in the page table
STEP2:NO OF FRAMES IN PHYSICAL MEMORY:
so we need