1. Memory Management
CSE451
Andrew Whitaker

2. Big Picture The OS is responsible for resource management
Up till now, we’ve focused on how multiple programs share the CPU
Now: how do multiple programs share memory?
Firefox
Word
javac

3. Goals of Memory Management
Provide a convenient foundation for programmers, compilers, linkers
Hide memory sharing
Via virtual addressing
Hide memory scarcity
Via virtual memory
Provide isolation between processes

4. Problem: Memory Relocation
A program
3 MB
Firefox
Word
javac
PacMan
0 MB
Firefox
Word
javac
PacMan

5. Virtual Addressing
Programmer sees a virtual address space, which always starts at zero
Hardware/OS map virtual addresses to physical
0MB
1MB
0MB
1MB
0MB
1MB
Virtual
Addresses
Firefox
Word
PacMan
Physical
Addresses
PacMan
Firefox
Word

6. Memory Management: Factors to Consider
Workload characteristics
Batch systems, Internet systems, interactive systems
Level of hardware support
Base &
Limit
registers
No HW
support
Paging,
Segmentation,
TLBs

7. Strategy #1: Swapping Only one program occupies memory at once
On a context switch:
Save old program’s memory to disk
Load next program’s memory from disk
Either eagerly or lazily
Advantage: very simple
Disadvantage: disk is exceedingly slow!

8. Why Use Swapping? No Hardware Support Long-lived batch jobs
MIT’s CTSS operating system (1961) was built this way
Memory was so small that only one job would fit!
Long-lived batch jobs
Job switching costs become insignificant as the quantum grows large

9. How Slow is Swapping?

10. Strategy #2: Fixed partitions
Physical memory is broken up into fixed partitions
All partitions are the same size
Partitions never change
Advantages
Simple

11. Disadvantages of Fixed Partitions
Internal fragmentation: memory in a partition not used by its owning process isn’t available to other processes
Partition size problem: no one size is appropriate for all processes
Tradeoff between fragmentation and accommodating large programs

12. Implementing Fixed Partitions
Requires hardware-supported base and limit registers
physical memory
partition 0
limit register
base register 2K 2K
P3’s base: 6K
partition 1 4K
partition 2 6K
yes
partition 3
<? +
offset 8K
virtual address
partition 4 no
10K
raise
protection fault
partition 5

13. Strategy #3: Variable Partitions
Obvious next step: physical memory is broken up into variable-sized partitions
Advantage: no internal fragmentation
Simply allocate partition size to be just big enough for process
Problems
We must know in advance the program size
External fragmentation
As we load and unload jobs, holes are left scattered throughout physical memory

14. Mechanics of Variable Partitions
physical memory
partition 0
limit register
base register
P3’s size
P3’s base
partition 1
partition 2
yes
<? +
offset
partition 3
virtual address no
partition 4
raise
protection fault

15. Dealing with External Fragmentation
Swap a program out
Re-load it, adjacent to another
Adjust its base register
“Lather, rinse, repeat”
Ugh
partition 0
partition 0
partition 1
partition 1
partition 2
partition 2
partition 3
partition 4
partition 3
partition 4

16. physical address space
Strategy #4: Paging
Use fixed-size units of memory (called pages) for both virtual and physical memory
virtual address space
physical address space
page 0
frame 0
page 1
frame 1
page 2
frame 2
page 3 … …
frame Y
page X

17. Paging Advantages Paging reduces internal fragmentation
Paging eliminates external fragmentation
Disadvantages?
Reduce internal fragmentation by making fixed-size chunks relatively small (as opposed to large, fixed parittions)
External fragmentationis eliminated becaues the pages are all the same size
Another advantage: we can gradually grow / shrink the memory allocated to a process
A major disadvantage is that we have more infomration to keep track of, and this approach requires more hardware support

18. Address translation
A virtual address has two parts: virtual page number and offset
Address translation only applies to the virtual page number
Virtual page number (VPN) is index into a page table
Page table entry contains page frame number (PFN)
Physical address is PFN::offset
virtual page #
offset

19. Page Tables Managed by the OS
Map a virtual page number (VPN) to a page frame number (PFN)
VPN is simply an index into the page table
One page table entry (PTE) per page in virtual address space
i.e., one PTE per VPN

20. Mechanics of address translation
virtual address
virtual page #
offset
physical memory
page
frame 0
page table
page
frame 1
physical address
page
frame 2
page frame #
page frame #
offset
page
frame 3 …
page
frame Y

21. Example of address translation
Assume 32 bit addresses
assume page size is 4KB (4096 bytes, or 212 bytes)
VPN is 20 bits long (220 VPNs), offset is 12 bits long
Let’s translate virtual address 0x
VPN is 0x13325, and offset is 0x328
assume page table entry 0x13325 contains value 0x03004
page frame number is 0x03004
VPN 0x13325 maps to PFN 0x03004
physical address = PFN::offset = 0x

22. Page Table Entries (PTEs)1 1 1 2 20 V R M
prot
page frame number
PTE’s control address mappings
The page frame number indicates the physical page
The valid bit says whether or not the PTE can be used
says whether or not a virtual address is valid
The referenced bit says whether the page has been accessed recently
The modified bit says whether or not the page is dirty
it is set when a write to the page has occurred
The protection bits control which operations are allowed
read, write, execute

23. Paging Issues (Stay Tuned…)
How to make it fast?
Accessing the page table on each memory reference is not workable
How to deal with memory scarcity
Virtual memory
How do we control the memory overhead of page tables?
Need one PTE per page in virtual address space
32 bit AS with 4KB pages = 220 PTEs = 1,048,576 PTEs
4 bytes/PTE = 4MB per page table
OS’s typically have separate page tables per process
25 processes = 100MB of page tables

24. Strategy #5: Segmentation
Instead of a flat address space, programmers see a collection of segments
Virtual address = segment #, offset
heap
stack
main()
Shared
library
segment #
offset

25. Why Segments? Facilitates sharing and re-use
Unlike a page, a segment is a logical entity
Segments can have arbitrary size

26. Hardware support
Segmentation is a generalization of variable-sized partitions
Variable sized partitions: 1 segment per process
Segmentation: N segments per process
So, we need multiple base/limit pairs
These are stored in a segment table
Segments named by segment #, used as index into table
A virtual address is <segment #, offset>
Offset of virtual address added to base address of segment to yield physical address

27. Segment lookups <? + segment 0 segment 1 segment 2 yes segment 3 no
segment table
base
limit
physical memory
segment 0
segment #
offset
segment 1
virtual address
segment 2
yes
<? +
segment 3 no
segment 4
raise
protection fault

28. Pros and cons Yes, it’s “logical” and it facilitates sharing and reuse
But it has all the horror of a variable partition system
e.g., external fragmentation

29. Intel x86: Combining segmentation and paging
Use segments to manage logical units
Use pages to partition segments into fixed-size chunks
Each segment has its own page table
There is a page table per segment, rather than per user address space
Memory allocation becomes easy once again
no contiguous allocation, no external fragmentation
Segment #
Page #
Offset within page
Offset within segment

30. Who Uses This? Nobody :-) Linux primarily uses:
Only supported by x86, so portability is a problem
Linux primarily uses:
1 kernel code segment, 1 kernel data segment
1 user code segment, 1 user data segment