1 / 38

OS Memory Addressing

OS Memory Addressing. Architecture. CPU Processing units Caches Interrupt controllers MMU Memory Interconnect North bridge South bridge PCI, etc. PC Architecture. Address Spaces. Translation from logical to physical addresses. 2 N. Address space 1. 2 N. Process 1. 0.

joella
Télécharger la présentation

OS Memory Addressing

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. OS Memory Addressing

  2. Architecture • CPU • Processing units • Caches • Interrupt controllers • MMU • Memory • Interconnect • North bridge • South bridge • PCI, etc

  3. PC Architecture

  4. Address Spaces • Translation from logical to physical addresses 2N Address space 1 2N Process 1 0 Process 3 2N Address space 3 Process 2 0 OS 2N Address space 2 0 0 Physical Address space Virtual/Logical Address spaces

  5. Hardware Support • Two operating modes • Privileged (protected, kernel) mode: OS context • Result of OS invocation (system call, interrupt, exception) • Allows execution of privileged instructions • Allows access to all of memory (sort of) • User Mode: Process context • Only access resources (memory) in its context (address space) • Segmentation (Logical addressing) • Base register: Start location for address space • Limit register: Size of segment making up address space

  6. Implementation • Translation on every memory access in user process • Compare logical address to limit register • If logical address is greater, ERROR • Physical Address = base register + logical address

  7. Managing Processes w/ Base and Limits • Context Switch • Add base and limit registers to process context • Context Switch steps • Change to privileged mode • Save base and limit registers of old process • Load base and limit registers of new process • Change to user mode and jump to new process • Protection Requirement • User process can not change base and limit • User process can not run in privileged mode • What if base and limit registers don’t change during context switch?

  8. Pros and Cons of Segmentation • Advantages • Supports dynamic relocation of address spaces • Supports protection across multiple address spaces • Cheap: Few registers and little logic • Fast: Add and Compare is easy • Disadvantages • Each process must be allocated contiguously in real memory • Fragmentation: Cannot allocate a new process • Must allocate memory that may not be used • No Sharing: Cannot share limited memory regions

  9. Using Segments • Divide address space into logical segments • Each logical segment can be in separate part of physical memory • Separate base and limit for each segment (+ protection bits) • Read and write bits for each segment • How to designate segment? • Use part of logical address • Top bits of logical address select segment • Low bits of logical address select offset within segment • Implicitly by type of memory reference • Code vs. Data segments • Special registers

  10. Segment Table • Segment Table: Base and limit for every segment in process • Translation: Indirection -> Table lookup before Add and Compare 0x3800 Seg 2 0x3000 Where is: 0x0240 0x1108 0x265c 0x3002 0x2a00 Seg 1 0x2000 0x1000 Caveat: Assume segments are selected via the logical address. NOT A REAL SYSTEM Seg 0 0x0000 Physical Logical

  11. Pros and Cons of Segmentation • Advantages • Different protection for different segments • E.g Code segment is read only • Enables sharing of selected segments • Easier to relocate segments than entire address space • Enables sparse allocation of address space • Disadvantages • Still expensive/difficult to allocate contiguous memory to segments • Fragmentation: Wasted memory • Next approach: Paging • Allocation is easier • Reduces fragmentation

  12. Example • Rep movs • See Architecture Manual

  13. x86 Segments • CS = Code Segment • DS = Data Segment • SS = Stack Segment • ES, FS, GS = Auxiliary segments • Explicit or implicitly specified by instructions • Accessed via special registers • 16 bit “Selectors” • Identify the segment to the hardware MMU • Functionality depends on CPU operating mode

  14. Memory Map • Early PC’s depended on BIOS for hardware interactions • Standard library • Implemented as Real Mode code • (16 bit instructions) • Hardwired directly into memory • All x86 CPUs start execution at 0xffff0 • Where is that? • 1MB of available memory • On a 16 bit architecture?

  15. Real Mode (16 bits) • Segment registers act as base address • 16 bits • Segment size = 64K (216) • Translation: • Physical Addr = (segaddr << 4) + logical addr • x86 init values: • CS: 0xf000 • IP: 0xfff0 • Goal when in Real Mode: • Get Out of Real Mode • First thing OS does is transition to Protected (32 bit) mode

  16. 32 bit Memory Map • 32 bit addresses • Up to 4GB (232) • Top of memory used by hardware again • “Who would ever need more than 3GB of memory?” • BIOS is still there • Why? • Is it still useful?

  17. Protected Mode (32 bits) • Segment information now stored as a table • GDT (Global Descriptor Table) • Where is the GDT? • Array of segment descriptions (base, limit, flags) • Segment registers now indicate array index • Segment registers select segment descriptor • CS points to Code Segment descriptor in GDT • Still 16 bits • How does Linux use segments? • Check architecture manuals

  18. Linear address calculation

  19. Segment descriptors

  20. Segmentation Registers

  21. Paging • Memory divided into fixed-sized pages • Typical page size: 512-16k bytes Address space 1 Address space 2 Free Page Address space 3 Free Page Free Page Virtual Memory Physical Memory

  22. Page Translation • How are virtual addresses translated to physical addresses • Upper bits of address designate page number 12 Bits 20 Bits 4K Pages Page Number Page Offset Virtual Address Page Table Page Base Address Page Offset Physical Address • No comparison or addition: Table lookup and bit substitution • 1 page table per process: One entry per page in address space • Base address of each page in physical memory • Read/Write protection bits • How many entries in page table?

  23. Page Table Example • Mapping of virtual addresses to physical memory Address space 1 0x3000 0x2000 4KB Pages 0x1000 0x0000 Page Table for process 1 Free Page Free Page Free Page Physical Memory

  24. Advantages of Paging • Fast to allocate and free • Alloc: Keep free list of pages and grab first page in list • No searching by first-fit, best-fit • Free: Add page to free list • No inserting by address or size • Easy to swap-out memory to disk • Page size matches disk block size • Can swap-out only necessary pages • Easy to swap-in pages back from disk

  25. Disadvantages of Paging • Additional memory reference -> Inefficient • Page table too large to store as registers in MMU • Page tables kept in main memory • MMU stores only base address of page table • Storage for page tables may be substantial • Simple page table -> Require entry for all pages in address space • Even if actual pages are not allocated • Solution: Hierarchical page tables • Increase granularity of page table entries • Internal fragmentation: Page size does not match allocation size • How much memory is wasted (on average) per process? • Wasted memory grows with larger pages

  26. Paging with Large Address Spaces • Mapping of logical addresses to physical memory • Page table for process Free Page Free Page Physical Memory How are entries skipped?

  27. Combine paging and segmentation • Structure • Segments correspond to logical units: code, data, stack • Segments very in size and are often large • Each segment contains one or more (fixed-size) pages • But no longer needs to be contiguous • Multiple ways to combine them: • System 370: Each segment got own page tables Seg # (4 bits) Page # (8 bits) Page offset (12 bits) Why 12 Bits? • x86: First calculate segment offset then do page table lookup • logical address -> linear address -> physical address

  28. Segments + Pages Advantages • Advantages of Segments • Supports large memory regions • Single entry can cover all memory • Translation is fast and cheap • Advantages of Paging • Memory does not have to exist (on demand) • Can remap memory without copying • Advantages of both • Can use protection of segments without preallocating memory • Other advantages?

  29. Protected Mode + Paging • Segmentation -> Paging -> Physical address • Every address in a page table points to a physical address • Virtual addresses are only an INDEX into page tables • Page size: 4KB • Data and page table pages • Page table page? • 1024 entries per page table page • 2 Level Page Tables • Page tables set via CR3 (What is this?) • Top Level: Entire 4GB of virtual address space • 2nd level: 4MB of virtual address space • Large Pages • Contiguous mappings of virtual addresses to physical addresses

  30. Page Table formats

  31. Paging Translation

  32. Long Mode (64 bits) • Segments no longer used • Present but must be set to a flat model • Addresses now 64 bits • But pages are still 4KB • Page table hierarchy now has 4 levels • Check architecture manuals • Page table pages now only include 512 entries • Last level page table only covers 2MB of addresses

  33. Early Memory (un)managementA history of the x86 • Simple layout with a single segment per process • Early batch monitors • Personal computers • Disadvantages • Only one process can run at a time • Process can destroy OS 2N OS OS resides in High memory User Process Process has memory 0 to OS break 0

  34. Goals for Multiprogramming • Sharing • Several processes coexist in main memory • Transparency • Processes not aware memory is shared • Run regardless of number and/or locations of processes • Protection • Cannot corrupt OS or other processes • Privacy: Cannot read data of other processes • Efficiency should not be severely degraded • Purpose of sharing is to increase efficiency • CPU and memory resources not wasted

  35. Static Relocation • Transparency == Relocation • Processes can run anywhere in memory • Can’t predict in advance • Modify addresses statically (ala linking) • when process is loaded • Advantages • Allow multiple processes to run • Requires no hardware support 2N OS Process 3 Process 2 Process 1 0

  36. Disadvantages of Static Relocation • Process allocation must be contiguous • Fragmentation: May not be able to allocate new process • What Kind? • Processes may not be able to increase address space • Can’t move process after it has been placed • No Protection: • Destroy other processes and/or OS 2N OS Process 3 Process 2 Process 1 0

  37. Dynamic Relocation • Translate address dynamically at every reference Memory Logical Addresses Physical Addresses MMU CPU • Program-generated address translated to hardware address • Program addresses: Logical or virtual addresses • Hardware addresses: Physical or real addresses • Address space: View of memory for each process

  38. Managing Processes with Segments • Process Creation • Find contiguous space for each segment • Fill in each base and limit value in segment table • Additional memory allocation when no contiguous space • Compact memory (move all segments, update bases) • Swap one or more segments to disk • Context Switch • Include segment table in process context • Process Exit • Free segments

More Related