1. Give the methods that are used in page table and TLB for searching the accessing pages. Compare the differences on the searches between these two hardwares and give reasons why TLB will help the search of the pages.
ANS:
For large page table , more feasible if keep it in main memory and use a page-table base register (PTBR) points to the page table and page-table length register (PRLR) indicates size of the page table .
In this scheme every data / instruction access requires two memory accesses . One for the page table and one for the data / instruction .
This problem can be solved by the use of a special fast-lookup hardware cache called translation look-aside buffers (TLBs) .
When presented with an item , it is compared with all keys simultaneously in the TLB .
If the page number is found in the TLB , its frame number is immediately available and used to access memory .
If the page number is not in the TLB , a memory reference to the page table must be made .
TLB is updated for next reference .
2. What is the purpose of paging the page table?
ANS:
Set up a page table to translate logical to physical addresses.
Avoid to external fragmentation and memory blocks of different sizes .
3. Consider a 32bit address space with 2K bytes page size, assuming that each entry consists of 4 bytes, how much memory are required for the page table for each process? Explain your reason.
ANS:
232/211=221 , so a page table may consist of up to 2 million (221) entries .
221*4=223 , requires 8 megabytes (223) page table for each process .
4. Compare the main memory organization schemes of contiguous-memory allocation, pure segmentation, and pure paging with respect to the following issues:
a. external fragmentation
b. internal fragmentation
c. ability to share code across processes
ANS:
a. External fragmentation Contiguous allocation with fixed size partitions does not suffer from external fragmentation, but contiguous allocation with variable sized partitions does. Pure paging does not suffer from external fragmentation, since partitions and pages are fixed in size. Segmentation does suffer from external fragmentation.
b. Internal fragmentation Segmentation and variable-sized partitions do not suffer from internal fragmentation, since by definition, a segment/partition is exactly as large as it needs to be. However, contiguous allocation with fixed-size partitions and paging both may suffer from internal fragmentation when partitions and pages are not completely filled.
c. Ability to share code across processes Contiguous allocation provides no support for code sharing. In segmentation, as long as the segments of a process do not mix text and data, we can easily share code between processes. We simply adjust the segment tables of each process to point to the same segment of code in memory. For security reasons, however, it would probably be desirable to have some method of preventing processes from modifying code, since doing so would allow one process to change the code executed by another. In pure paging, code can be shared across processes simply by sharing page frames. To do this, adjust the page tables of the two processes so that their different logical pages map to the same physical page frame. However, we do need to make certain that no page frame contains any data, which should not be shared. We could accomplish this by, for example, padding the last page of the text segment of the process with no-op machine language instructions.