Post on 20-Nov-2014
description
OS Fall’02
Virtual Memory
Operating Systems Fall 2002
OS Fall’02
Paging and Virtual Memory Paging makes virtual memory possible
Logical to physical address mapping is dynamicProcesses can be broken to a number of pages that need not be mapped into a contiguous region of the main memory
=> It is not necessary that all of the process pages be in main memory during execution
OS Fall’02
How does this work? CPU can execute a process as long as
some portion of its address space is mapped onto the physical memory
E.g., next instruction and data addresses are mapped
Once a reference to an unmapped page is generated (page fault):
Put the process into blocking state Read the page from disk into the memoryResume the process
OS Fall’02
Benefits More processes may be maintained
in the main memoryBetter system utilization
The process size is not restricted by the physical memory size: the process memory is virtual
But what is the limit anyway?
OS Fall’02
Why is this practical? Observation: Program branching and
data access patterns are not random Principle of locality: program and
data references tend to cluster=> Only a fraction of the process
virtual address space need to be resident to allow the process to execute for sufficiently long
OS Fall’02
Virtual memory implementation
Efficient run-time address translationHardware support, control data structures
Fetch policyDemand paging: page is brought into the memory only when page-fault occursPre-paging: pages are brought in advance
Page replacement policyWhich page to evict when a page fault occurs?
OS Fall’02
Thrashing A condition when the system is
engaged in moving pages back and forth between memory and disk most of the time
Bad page replacement policy may result in thrashing
Programs with non-local behavior
OS Fall’02
Address translation Virtual address is divided into page
number and offset
Process page table maintains mappings of virtual pages onto physical frames
Each process has its own unique page table
Virtual Address
Page Number Offset
OS Fall’02
Forward-mapped page tables (FMPT)
Page table entry (PTE) structure
Page table is an array of the above
Index is the virtual page number
P M Frame NumberOther Control Bits
Page Table
Frame #
Page #
P: present bitM: modified bit
OS Fall’02
Address Translation using FMPT
Program Paging Main Memory
Virtual address
Register
Page Table
PageFrame
Offset
P#
Frame #
Page Table Ptr
Page # Offset Frame # Offset
+
OS Fall’02
Handling large address spaces One level FMPT is not suitable for
large virtual address spaces32 bit addresses, 4K (212) page size, 232 / 212 = 220 entries ~4 bytes each =>
4Mbytes resident page table per process!What about 64 bit architectures??
Solutions: multi-level FMPTInverted page tables (IPT)
OS Fall’02
Multilevel FMPT Use bits of the virtual address to
index a hierarchy of page tables The leaf is a regular PTE Only the root is required to stay
resident in main memoryOther portions of the hierarchy are subject to paging as regular process pages
OS Fall’02
Two-level FMPTpage number page offset
pi p2 d
10 10 12
OS Fall’02
Two-level FMPT
OS Fall’02
Inverted page table (IPT) A single table with one entry per
physical page Each entry contains the virtual
address currently mapped to a physical page (plus control bits)
Different processes may reference the same virtual address values
Address space identifier (ASID) uniquely identifies the process address space
OS Fall’02
Address translation with IPT Virtual address is first indexed into
the hash anchor table (HAT) The HAT provides a pointer to a
linked list of potential page table entries
The list is searched sequentially for the virtual address (and ASID) match
If no match is found -> page fault
OS Fall’02
Address translation with IPT
Virtual addresspage number offset
hash
+
HAT baseregister
ASID
register
page numberASID
Frame#
IPT
+
IPT baseregister
frame number
HAT
OS Fall’02
Translation Lookaside Buffer (TLB)
With VM accessing a memory location involves at least two intermediate memory accesses
Page table access + memory access
TLB caches recent virtual to physical address mappings
ASID or TLB flash is used to enforce protection
OS Fall’02
TLB internals TLB is associative, high speed memory
Each entry is a pair (tag,value)When presented with an item it is compared to all keys simultaneouslyIf found, the value is returned; otherwise, it is a TLB missExpensive: number of typical TLB entries: 64-1024Do not confuse with memory cache!
OS Fall’02
Address translation with TLB
OS Fall’02
Bits in the PTE: Present (valid) Present (valid) bit
Indicates whether the page is assigned to frame or notInvalid page can be not a part of any memory segmentA reference to an invalid page generates page fault which is handled by the operating system
OS Fall’02
Bits in PTE: modified, used Modified (dirty) bit
Indicates whether the page has been modifiedUnmodified pages need not be written back to the disk when evicted
Used bitIndicates whether the page has been accessed recentlyUsed by the page replacement algorithm
OS Fall’02
Bits in PTE Access permissions bit
indicates whether the page is read-only or read-write
UNIX copy-on-write bitSet whether more than one process shares a pageIf one of the processes writes into the page, a separate copy must first be made for all other processes sharing the pageUseful for optimizing fork()
OS Fall’02
Protection with VM Preventing processes from
accessing other process pages Simple with FMPT
Load the process page table base address into a register upon context switch
ASID with IPT
OS Fall’02
Segmentation with paging Segmentation
simplifies protection and sharing, enforce modularity, but prone to external fragmentation
Paging transparent, eliminates ext. fragmentation, allows for sophisticated memory management
Segmentation and paging can be combined
OS Fall’02
Address translation
Main Memory
PageFrame
Offset
Paging
Page Table
P#
+
Frame # Offset
Seg Table Ptr
+S #
SegmentationProgram
SegmentTable
Seg # Page # Offset
OS Fall’02
Page size considerations Small page size
better approximates localitylarge page tablesinefficient disk transfer
Large page sizeinternal fragmentation
Most modern architectures support a number of different page sizes
a configurable system parameter
OS Fall’02
Next: Page replacement