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Morgan Kaufmann Publishers Memory Hierarchy: Virtual Memory

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1 Morgan Kaufmann Publishers Memory Hierarchy: Virtual Memory
13 January, 2019 Lecture 4.4 Memory Hierarchy: Virtual Memory Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

2 Learning Objectives Translate virtual addresses to physical addresses with page table Use TLB to facilitate the address translation Identify various events TLB hit/miss Page table hit/miss Page table miss -> page fault 2

3 Coverage Textbook: Chapter 5.7 3

4 Morgan Kaufmann Publishers
13 January, 2019 Virtual Memory §5.7 Virtual Memory A memory management technique developed for multitasking computer architectures Virtualize various forms of data storage Allow a program to be designed as there is only one type of memory, i.e., “virtual” memory Each program runs on its own virtual address space Use main memory as a “cache” for secondary (disk) storage Allow efficient and safe sharing of memory among multiple programs Provide the ability to easily run programs larger than the size of physical memory Simplify the process of loading a program for execution by code relocation Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 4 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

5 Two Programs Sharing Physical Memory
A program’s address space is divided into pages (fixed size) The starting location of each page (either in main memory or in secondary memory) is contained in the program’s page table Program 1 virtual address space main memory Program 2 virtual address space “cache” of hard drive

6 Address Translation A virtual address is translated to a physical address Virtual Address (VA) Virtual page number Page offset Translation Page offset Physical page number Physical Address (PA) So each memory request first requires an address translation from the virtual space to the physical space A virtual memory miss (i.e., when the page is not in physical memory) is called a page fault The page size is 212 = 4KB, the number of physical pages allowed in memory is 218, the physical address space is 1GB and the virtual address space is 4GB

7 Morgan Kaufmann Publishers
13 January, 2019 Page Fault Penalty On page fault, the page must be fetched from disk Takes millions of clock cycles Handled by OS code Try to minimize page fault rate Fully associative placement A physical page can be placed at any place in the main memory Smart replacement algorithms Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 7 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

8 Morgan Kaufmann Publishers
13 January, 2019 Page Tables Stores placement information Array of page table entries, indexed by virtual page number Page table register in CPU points to page table in physical memory If page is present in memory Page table entry stores the physical page number Plus other status bits (referenced, dirty, …) If page is not present Page table entry can refer to location in swap space on disk Swap space: the space on the disk reserved for the full virtual memory space of a process Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 8 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

9 Address Translation Mechanisms
Virtual page # Offset Physical page # Offset Physical page base addr V 1 Page table register The page table together with the program counter and the registers specifies the state of a program – usually called a process The operating system simply loads the page table register to point to the page table of the process it wants to make active (and loads the register file and the program counter) Main memory Page Table (in main memory) Disk storage

10 Translation Using a Page Table
Morgan Kaufmann Publishers 13 January, 2019 Translation Using a Page Table Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 10 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

11 Replacement and Writes
Morgan Kaufmann Publishers 13 January, 2019 Replacement and Writes To reduce page fault rate, prefer least-recently used (LRU) replacement Reference bit (aka use bit) in PTE set to 1 on access to page Periodically cleared to 0 by OS A page with reference bit = 0 has not been used recently Disk writes take millions of cycles Replace a page at once, not individual locations Use write-back Write through is impractical Dirty bit in PTE set when page is written Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 11 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

12 Virtual Addressing with a Cache
Thus it takes an extra memory access to translate a VA to a PA CPU Trans- lation Cache Main Memory VA PA miss hit data This makes memory (cache) accesses very expensive (if every access was really two accesses) The hardware fix is to use a Translation Lookaside Buffer (TLB) – a small cache that keeps track of recently used address mappings to avoid having to do a page table lookup

13 Fast Translation Using a TLB
Morgan Kaufmann Publishers 13 January, 2019 Fast Translation Using a TLB Address translation would appear to require extra memory references One to access the PTE Then the actual memory access Check cache first But access to page tables has good locality So use a fast cache of PTEs within the CPU Called a Translation Look-aside Buffer (TLB) Typical: 16–512 PTEs, 0.5–1 cycle for hit, 10–100 cycles for miss, 0.01%–1% miss rate Misses could be handled by hardware or software Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 13 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

14 Making Address Translation Fast
1 Tag Physical page base addr V TLB Virtual page # Physical page base addr V 1 Page table register Main memory Page Table (in physical memory) Disk storage

15 Fast Translation Using a TLB
Morgan Kaufmann Publishers 13 January, 2019 Fast Translation Using a TLB Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 15 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

16 Translation Lookaside Buffers (TLBs)
Just like any other cache, the TLB can be organized as fully associative, set associative, or direct mapped V Tag Physical Page # Dirty Ref Access TLB access time is typically smaller than cache access time (because TLBs are much smaller than caches) TLBs are typically not more than 512 entries even on high end machines

17 Morgan Kaufmann Publishers
13 January, 2019 TLB Misses If page is in memory Load the PTE from page table to TLB and retry Could be handled in hardware Can get complex for more complicated page table structures Or handled in software Raise a special exception, with optimized handler If page is not in memory (page fault) OS handles fetching the page and updating the page table Then restart the faulting instruction Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 17 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

18 Morgan Kaufmann Publishers
13 January, 2019 TLB Miss Handler TLB miss indicates two possibilities Page present, but PTE not in TLB Handler copies PTE from memory to TLB Then restarts instruction Page not present in main memory Page fault will occur Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 18 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

19 Morgan Kaufmann Publishers
13 January, 2019 Page Fault Handler Use virtual address to find PTE Locate page on disk Choose page to replace if necessary If the chosen page is dirty, write to disk first Read page into memory and update page table Make process runnable again Restart from faulting instruction Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 19 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

20 TLB and Cache Interaction
Morgan Kaufmann Publishers 13 January, 2019 TLB and Cache Interaction If cache tag uses physical address Need to translate before cache lookup Alternative: use virtual address tag Complications due to aliasing Different virtual addresses for shared physical address Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 20 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

21 TLB Event Combinations
Page Table Cache Possible? Under what circumstances? Hit Miss Miss/ Yes – what we want! Yes – although the page table is not checked if the TLB hits Yes – TLB miss, PA in page table Yes – TLB miss, PA in page table, but data not in cache Yes – page fault Impossible – TLB translation not possible if page is not present in memory Impossible – data not allowed in cache if page is not in memory

22 Morgan Kaufmann Publishers
13 January, 2019 Memory Protection Different tasks can share parts of their virtual address spaces But need to protect against errant access Requires OS assistance Hardware support for OS protection Privileged supervisor mode (aka kernel mode) Privileged instructions Page tables and other state information only accessible in supervisor mode System call exception (e.g., syscall in MIPS) Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 22 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

23 Morgan Kaufmann Publishers
13 January, 2019 Concluding Remarks Fast memories are small, large memories are slow We really want fast, large memories  Caching gives this illusion  Principle of locality Programs use a small part of their memory space frequently Memory hierarchy L1 cache  L2 cache  …  DRAM memory  disk Memory system design is critical for multiprocessors §5.16 Concluding Remarks Chapter 5 — Large and Fast: Exploiting Memory Hierarchy — 23 Chapter 5 — Large and Fast: Exploiting Memory Hierarchy

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