I am answering some problems related to virtual memory and would like some help in clarifying or confirming my understanding on how this stuff is done.
The questions are as follows:
Given a byte-addressable system with 32 bit words, a virtual address space of 4 gigabytes, a physical address space of 1 gigabyte, and a page size of 4 kilobytes. There is an assumption that page table entries are rounded up to 4 bytes.
a) What is the size of the page table in bytes?
b) Now assume that a 4-way set-associative translation lookaside buffer is implemented, with a total of 256 address translations. Calculate the size of its tag and index fields.
My answers are as follows:
The size of the page table is equal to the number of entries in the page table multiplied by the size of the entries.
The number of entries in the page table is equal to the memory size divided by the page size: 2^32/2^12=2^20.
The size of the entries is equal to the word size minus the bits used for the number of entries in the page table: 32-20=12.
Hence, the page table size is: (2^20) * 12 bits = 12582912 bits = 1572864 bytes
However, I found this (under the heading of "Page Table Size"), which uses basically identical numbers.
Page Table Size = ((virtual address space size)/(page size)) * (page table entry size) = (4 GB/4 KB) * 4 B = 4 MB
Which answer is correct?
I am unsure of how to calculate part B. I believe that the Tag is calculated by adding the number of blocks, plus the offset, plus the index. This is a 4 way set associative, so there are 4 blocks in each set. The index is 8 bits because the base index size is 10 bits and is decreased by 2, also because it is a 4 way set associative. However, I am unaware of how to calculate the offset, which is needed to help calculate the tag.
Any help would be much appreciated.