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CSCC69: Operating Systems

CSCC69: Operating Systems. Assignment 2 Some slides are borrowed from CSCC69 offered in winter 2012. Virtual Memory. Allowing a program to be designed as though there is only one kind of memory, "virtual" memory, which behaves like directly addressable read/write memory (RAM) .

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CSCC69: Operating Systems

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  1. CSCC69: Operating Systems Assignment 2 Some slides are borrowed from CSCC69 offered in winter 2012

  2. Virtual Memory • Allowing a program to be designed as though there is only one kind of memory, "virtual" memory, which behaves like directly addressable read/write memory (RAM). • Need to manage what is in memory (TLB, page table, coremap) • Swap pages on request

  3. Virtual Memory • Translation Look aside Buffer (TLB): is a cache that memory management hardware uses to improve virtual address translation speed. • The search key is the virtual address and the search result is a physical address.

  4. Virtual Memory • TLB hit: if the requested address is present in the TLB; the retrieved physical address can be used to access memory. • TLB miss: if the requested address is not in the TLB; the translation proceeds by looking up the page table.

  5. TLB Miss • When a page is requested but not in memory? • Page fault • When there is no more space in main memory to bring in pages? • Replace, evict

  6. Core Map • The core map is a table containing an entry for every physical page frame in the system. • For each page frame, a core map entry keeps track of: • Is the page frame allocated or free? • Which address space is using this page? • Which virtual page number within space? • Plus possibly other flags, such as whether the page is currently locked in memory for I/O purposes.

  7. Swap Space • Swap space is used when the amount of physical memory (RAM) is full. • If the system needs more memory resources and the RAM is full, inactive pages in memory are moved to the swap space. • Swap space is located on hard drives, which have a slower access time than physical memory.

  8. OS 161 Page Tables • OS/161 paging uses virtual memory objects • structvm_object defined in src/kern/include/vmprivate.h • A VM object defines a region of an address space • Contains a base virtual address and an array of pages • Redzone- A possible guard band against other vm_objects structvm_object { structlpage_array *vmo_lpages; vaddr_tvmo_base; size_tvmo_lower_redzone; };

  9. OS 161 Page Tables • Each VM object has an array of logical pages (lpages), one for each virtual page in the region • lpagestores where the page is in physical memory (lp_paddr), and where the page is stored in swap when not in main memory (lp_swapaddr) • If the page is not in RAM, lp_paddr is INVALID_PADDR. • If no swap has been allocated, lp_swapaddr is INVALID_SWAPADDR. • Low bits of lp_addr used to hold flags (DIRTY, PINNED) • Read comments in src/kern/include/vmprivate.h structlpage { volatile paddr_tlp_paddr; off_tlp_swapaddr; structspinlock lp_spinlock; };

  10. Lpage Operations • lpage_create - creates an lpage object. • lpage_destroy- deallocates an lpage, releases any RAM or swap pages involved • lpage_lock/unlock - for exclusive access to an lpage • lpage_copy- clones an lpage, including the contents • lpage_zerofill- materializes an lpage and zero-fill it

  11. Coremap • Logical pages are nice, but we ultimately need to work with physical memory • Need to keep track of physical pages • Coremapcontains an entry perphysical page frame to indicate its status

  12. Coremap • Inverted page table: Maps pages in memory to their virtual addresses • It allows you to use the physical address to find the logical page that inhabits it (NULL if empty) • Has bit flags that indicate if pages are kernel pages, pinned (busy), etc. structcoremap_entry { structlpage *cm_lpage; /* logical page we hold, or NULL */ ... /*flags*/ };

  13. Coremap Functions • coremap_alloc_one_page(lp, pin): called when a page is needed. None free? Call do_page_replace • coremap_{pin, unpin}: pin/unpin a page • page_replace: returns number of the page to be evicted • Replacement algorithm • do_evict: performs the page eviction • do_page_replace: starting point for page replacements

  14. Coremap_entry vs. lpage • Each lpage entry is a logical piece of memory • That memory may be in memory • It may also be in swap (on disk) • Each lpage points to the location of its data • The coremap maps physical memory to virtual • When you need physical memory, consult the coremap to see what memory is free • Each entry points to an lpage.

  15. Coremap_entry vs. lpage

  16. MIPS TLB Entry • src/kern/arch/mips/include/tlb.h • TLB keeps track of mapping from virtual to physical pages • High-order word • Virtual page number for lookup (TLBHI_VPAGE) : 20 bits (mask 0xffff000) • Also has 6 bits for PID; 6 bits unused in OS/161 • Low-order word • Physical page number (TLBLO_PPAGE) : 20 bits • Also has 4 status bits, and 8 unused bits • Eg: V for “valid”, D for “dirty” (“writable”/”referenced”)

  17. TLB functions • Can be found: • src/kern/arch/mips/include/tlb.h • tlb_write • tlb_read • Tlb_probe

  18. Address Translation Process

  19. MIPS TLB • In our case the TLB is software-managed (by the OS) • On memory read/write, checks the entries in the TLB in parallel: • Entry is found - TLB hit • Entry not found - TLB miss • Causes EX_TLBL for loads (reads) • Causes EX_TLBS for stores (writes) • Protection fault - trying to write to read-only memory causes EX_MOD (modify)

  20. TLB Exceptions • vm_fault() is called from mips_trap insrc/kern/arch/mips/locore/trap.cfor any TLB exception • Different types of VM_FAULT_* are passed on • vm_fault() in src/kern/include/vm.h and src/kern/arch/mips/vm/vm.c • vm_fault() calls as_fault() in src/kern/vm/addrspace.c and kern/include/addrspace.h • Eventually gets to lpage_fault() in src/kern/vm/lpage.c(this is where you come in) • On a TLB miss: • Look up the page in the page table • Implemented in src/kern/vm/addrspace.c: as_fault() • Choose an entry in the TLB to replace it • Insrc/kern/arch/mips/vm/coremap.c: tlb_replace() • Update TLB entry with PTE from page table • Insrc/kern/arch/mips/vm/coremap.c: mmu_map()

  21. Page Faults – High Level

  22. Page Faults • Minor fault: TLB does not contain a requested PTE (but it is in memory) • Find the Page Table Entry for it and insert the new mapping into the TLB and the coremap • See coremap.c for a function you can use! (mmu_map) • Major fault: the desired page is not in main memory (it’s either in swap space, or hasn’t been created yet) • How do we know if it’s a major fault? • lp_paddrfield of the lpagestruct will tell you • lp_paddris INVALID_PADDR if the page is not in memory

  23. Page Faults • Major fault: desired page is not in memory • Page hasn’t been created yet • A new page is allocated to the process and initialized (zero-filled) in src/kern/vm/addrspace.c: as_fault() • Page is in swap • We need to swap the page into memory from swap space • Need a page of physical memory for the page • look at lpage_copy for ideas • Set lp_*addr to INVALID_* when appropriate - to indicate page is not in main memory or swap

  24. Assignment 2 • Implement paging by writing the following functions: • lpage_fault--- handles a page fault • lpage_evict--- evicts an lpage from physical memory • page_replace--- implements page replacement policy • sequential replacement • random replacement • Much of the system is already provided

  25. Page Eviction • lpage_evict – evict an lpage from physical memory • Evicts the contents of the page at lp_paddr by writing it to lp_swapaddr on the swap device (if it is dirty), and mark lp_paddrinvalid • Called by do_evict (in coremap.c) when a physical page is chosen for eviction

  26. Page Replacement • Updating the victim’s PTE to show that it is in swap • swap functions src/kern/vm/swap.c • Copying it to disk (iff it is dirty) • Evicting (invalidating) victim’s PTE from the TLB • Loading the new page into memory • Updating the new page’s PTE and inserting it into the TLB

  27. Synchronization • OS161 assumes that lpages, vm_objects and address spaces are not shared. • But one thread may access an lpage belonging to another thread, in order to evict a page • Thus you need not use locks when accessing address spaces and vm_objects, but lpages do need synchronization • Bit lock is used to save space (see lpage_lock/lpage_unlock)

  28. Synchronization • global_paging_lock, limits number of pages pinned at any one time • swaplock: used by swap_alloc, swap_free, swap_reserve, swap_unreserve • cm_pinnedlocks pages that are in transit. • one bit lock per lpage • Lock Ordering (i.e you should acquire in this order): • global_paging_lockBEFORE coremap pages BEFORElpages

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