Post on 03-Feb-2022
transcript
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Bitwise OperatorsSymbol Operation Usage Precedence Assoc
~ bitwise NOT ~x 4 r-to-l<< left shift x << y 8 l-to-r>> right shift x >> y 8 l-to-r& bitwise AND x & y 11 l-to-r^ bitwise XOR x ^ y 12 l-to-r| bitwise OR x | y 13 l-to-r
Operate on variables bit-by-bit.• Like LC-3 AND and NOT instructions.
Shift operations are logical (not arithmetic).Operate on values -- neither operand is changed.
fread and fwriteBinary files are read and written using fread() and fwrite()
size_t fread(void *ptr, size_t size, size_t nmemb, FILE *stream)
size_t fwrite(void *ptr, size_t size, size_t nmemb, FILE *stream)
The function fread() reads nmemb objects, each size bytes long, from thestream pointed to by stream, storing them at the location given by ptr.The function fwrite() writes nmemb objects, each size bytes long, to thestream pointed to by stream, obtaining them from the location given by ptrBoth functions advance the file position indicator for the stream by thenumber of bytes read or written. They return the number of objects read orwritten. If an error occurs, or the end-of-file is reached, the return value is ashort object count (or zero).
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Example showing using of fread() and fwrite() to read andwrite blocks of binary data
#include <stdio.h>
int main()
{
int row, column; FILE *my_stream; int close_error; char my_filename[] = "my_numbers.dat"; size_t object_size = sizeof(int): size_t object_count = 25; size_t op_return;
Example cont’dint my_array[5][5] = { 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50 }; printf ("Initial values of array:\n"); for (row = 0; row <= 4; row++) { for (column = 0; column <=4; column++)
printf ("%d ", my_array[row][column]); printf ("\n"); }
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my_stream = fopen (my_filename, "w"); op_return = fwrite (&my_array, object_size, object_count, my_stream); if (op_return != object_count) printf ("Error writing data to file.\n"); else printf ("Successfully wrote data to file.\n");
/* Close stream; skip error-checking for brevity of example */ fclose (my_stream); printf ("Zeroing array...\n"); for (row = 0; row <= 4; row++) for (column = 0; column <=4; column++) {
my_array[row][column] = 0; printf ("%d ", my_array[row][column]);
} printf ("\n"); }
Example cont’d
printf ("Now reading data back in...\n");my_stream = fopen (my_filename, "r"); op_return = fread (&my_array, object_size, object_count, my_stream); if (op_return != object_count) { printf ("Error reading data from file.\n"); } else printf ("Successfully read data from file.\n"); for (row = 0; row <= 4; row++) for (column = 0; column <=4; column++) {
printf ("%d ", my_array[row][column]); printf ("\n"); } /* Close stream; skip error-checking for brevity of example */ fclose (my_stream); return 0;}
Example cont’d
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From C Programs to Processes:Linking, Loading, & Virtual Memory
TopicsTopics Static linking Object files Static libraries Dynamic linking of shared libraries Loading executables Processes Virtual Memory
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A Simplistic Program TranslationScheme
Problems:• Efficiency: small change requires complete recompilation• Modularity: hard to share common functions (e.g. printf)
Solution:• Static linker (or linker)
Translator
m.c
p
ASCII source file
Binary executable object file(memory image on disk)
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A Better Scheme Using a Linker
Linker (ld)
Translators
m.c
m.o
Translators
a.c
a.o
p
Separately compiledrelocatable object files
Executable object file (contains codeand data for all functions defined in m.cand a.c)
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Translating the Example ProgramCompiler driverCompiler driver coordinates all steps in the translation coordinates all steps in the translation
and linking process.and linking process. Typically included with each compilation system (e.g., gcc) Invokes preprocessor (cpp), compiler (cc1), assembler (as),
and linker (ld). Passes command line arguments to appropriate phases
Example: create executable Example: create executable pp from from m.cm.c and and a.ca.c::bass> gcc -O2 -v -o p m.c a.c cpp [args] m.c /tmp/cca07630.i cc1 /tmp/cca07630.i m.c -O2 [args] -o /tmp/cca07630.s as [args] -o /tmp/cca076301.o /tmp/cca07630.s <similar process for a.c>ld -o p [system obj files] /tmp/cca076301.o /tmp/cca076302.o bass>
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What Does a Linker Do?Merges object filesMerges object files
Merges multiple relocatable (.o) object files into a single executableobject file that can loaded and executed by the loader.
Resolves external referencesResolves external references As part of the merging process, resolves external references.
External reference: reference to a symbol defined in another object file.
Relocates symbolsRelocates symbols Relocates symbols from their relative locations in the .o files to
new absolute positions in the executable. Updates all references to these symbols to reflect their new
positions. References can be in either code or data
» code: a(); /* reference to symbol a */» data: int *xp=&x; /* reference to symbol x */
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Why Linkers?ModularityModularity
Program can be written as a collection of smaller sourcefiles, rather than one monolithic mass.
Can build libraries of common functions (more on this later) e.g., Math library, standard C library
EfficiencyEfficiency Time:
Change one source file, compile, and then relink. No need to recompile other source files.
Space: Libraries of common functions can be aggregated into a single
file... Yet executable files and running memory images contain only
code for the functions they actually use.
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Executable and Linkable Format(ELF)
Standard binary format for object filesStandard binary format for object filesDerives from AT&T System V UnixDerives from AT&T System V Unix
Later adopted by BSD Unix variants and Linux
One unified format forOne unified format for Relocatable object files (.o), Executable object files Shared object files (.so)
Generic name: ELF binariesGeneric name: ELF binariesBetter support for shared libraries than old Better support for shared libraries than old a.outa.out formats. formats.
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ELF Object File FormatElf headerElf header
Magic number, type (.o, exec, .so),machine, byte ordering, etc.
Program header tableProgram header table Page size, virtual addresses memory
segments (sections), segment sizes.
.text.text section section Code
.data.data section section Initialized (static) data
..bssbss section section Uninitialized (static) data Has section header but occupies no space
ELF header
Program header table(required for executables)
.text section
.data section
.bss section
.symtab
.rel.txt
.rel.data
.debug
Section header table(required for relocatables)
0
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ELF Object File Format (cont)..symtabsymtab section section
Symbol table Procedure and static variable names Section names and locations
..rel.textrel.text section section Relocation info for .text section Addresses of instructions that will need to
be modified in the executable Instructions for modifying.
..rel.datarel.data section section Relocation info for .data section Addresses of pointer data that will need to
be modified in the merged executable.debug.debug section section
Info for symbolic debugging (gcc -g)
ELF header
Program header table(required for executables)
.text section
.data section
.bss section
.symtab
.rel.text
.rel.data
.debug
Section header table(required for relocatables)
0
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Example C Program
int e=7; int main() { int r = a(); exit(0); }
m.c a.cextern int e; int *ep=&e;int x=15; int y; int a() { return *ep+x+y; }
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Merging Relocatable Object Filesinto an Executable Object File
main()m.o
int *ep = &e
a()
a.o
int e = 7
headers
main()
a()
0system code
int *ep = &e
int e = 7
system data
more system code
int x = 15int y
system data
int x = 15
Relocatable Object Files Executable Object File
.text
.text
.data
.text
.data
.text
.data
.bss .symtab.debug
.data
uninitialized data .bss
system code
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Relocating Symbols and ResolvingExternal References
Symbols are lexical entities that name functions and variables. Each symbol has a value (typically a memory address). Code consists of symbol definitions and references. References can be either local or external.
int e=7; int main() { int r = a(); exit(0); }
m.c a.cextern int e; int *ep=&e;int x=15; int y; int a() { return *ep+x+y; }
Def of localsymbol e
Ref to external symbol exit(defined in libc.so)
Ref toexternalsymbol e
Def oflocal symbol ep
Defs oflocalsymbolsx and y
Refs of localsymbols ep,x,y
Def oflocal symbol a
Ref to external symbol a
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m.o Relocation InfoDisassembly of section .text: 00000000 <main>: 00000000 <main>: 0: 55 pushl %ebp 1: 89 e5 movl %esp,%ebp 3: e8 fc ff ff ff call 4 <main+0x4> 4: R_386_PC32 a 8: 6a 00 pushl $0x0 a: e8 fc ff ff ff call b <main+0xb> b: R_386_PC32 exit f: 90 nop
Disassembly of section .data: 00000000 <e>: 0: 07 00 00 00
source: objdump
int e=7; int main() { int r = a(); exit(0); }
m.c
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a.o Relocation Info (.text)a.cextern int e; int *ep=&e;int x=15; int y; int a() { return *ep+x+y; }
Disassembly of section .text:
00000000 <a>: 0: 55 pushl %ebp 1: 8b 15 00 00 00 movl 0x0,%edx 6: 00 3: R_386_32 ep 7: a1 00 00 00 00 movl 0x0,%eax 8: R_386_32 x c: 89 e5 movl %esp,%ebp e: 03 02 addl (%edx),%eax 10: 89 ec movl %ebp,%esp 12: 03 05 00 00 00 addl 0x0,%eax 17: 00 14: R_386_32 y 18: 5d popl %ebp 19: c3 ret
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a.o Relocation Info (.data)a.cextern int e; int *ep=&e;int x=15; int y; int a() { return *ep+x+y; }
Disassembly of section .data:
00000000 <ep>: 0: 00 00 00 00
0: R_386_32 e 00000004 <x>: 4: 0f 00 00 00
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Executable After Relocation andExternal Reference Resolution (.text)
08048530 <main>: 8048530: 55 pushl %ebp 8048531: 89 e5 movl %esp,%ebp 8048533: e8 08 00 00 00 call 8048540 <a> 8048538: 6a 00 pushl $0x0 804853a: e8 35 ff ff ff call 8048474 <_init+0x94> 804853f: 90 nop 08048540 <a>: 8048540: 55 pushl %ebp 8048541: 8b 15 1c a0 04 movl 0x804a01c,%edx 8048546: 08 8048547: a1 20 a0 04 08 movl 0x804a020,%eax 804854c: 89 e5 movl %esp,%ebp 804854e: 03 02 addl (%edx),%eax 8048550: 89 ec movl %ebp,%esp 8048552: 03 05 d0 a3 04 addl 0x804a3d0,%eax 8048557: 08 8048558: 5d popl %ebp 8048559: c3 ret
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Executable After Relocation andExternal Reference Resolution(.data)
Disassembly of section .data:
0804a018 <e>: 804a018: 07 00 00 00
0804a01c <ep>: 804a01c: 18 a0 04 08
0804a020 <x>: 804a020: 0f 00 00 00
int e=7; int main() { int r = a(); exit(0); }
m.c
a.cextern int e; int *ep=&e;int x=15; int y; int a() { return *ep+x+y; }
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Packaging Commonly UsedFunctionsHow to package functions commonly used by programmers?How to package functions commonly used by programmers?
Math, I/O, memory management, string manipulation, etc.
Awkward, given the linker framework so far:Awkward, given the linker framework so far: Option 1: Put all functions in a single source file
Programmers link big object file into their programs Space and time inefficient
Option 2: Put each function in a separate source file Programmers explicitly link appropriate binaries into their programs More efficient, but burdensome on the programmer
Solution: Solution: static librariesstatic libraries (. (.aa archive filesarchive files)) Concatenate related relocatable object files into a single file with an
index (called an archive). Enhance linker so that it tries to resolve unresolved external
references by looking for the symbols in one or more archives. If an archive member file resolves reference, link into executable.
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Static Libraries (archives)
Translator
p1.c
p1.o
Translator
p2.c
p2.o libc.astatic library (archive) ofrelocatable object filesconcatenated into one file.
executable object file (only contains codeand data for libc functions that are calledfrom p1.c and p2.c)
Further improves modularity and efficiency by packagingcommonly used functions [e.g., C standard library (libc),math library (libm)]
Linker selectively only the .o files in the archive that areactually needed by the program.
Linker (ld)
p
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Creating Static Libraries
Translator
atoi.c
atoi.o
Translator
printf.c
printf.o
libc.a
Archiver (ar)
... Translator
random.c
random.o
ar rs libc.a \ atoi.o printf.o … random.o
Archiver allows incremental updates:• Recompile function that changes and replace .o file inarchive.
C standard library
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Commonly Used Librarieslibc.alibc.a (the C standard library) (the C standard library)
8 MB archive of 900 object files. I/O, memory allocation, signal handling, string handling, data and
time, random numbers, integer mathlibm.alibm.a (the C math library) (the C math library)
1 MB archive of 226 object files. floating point math (sin, cos, tan, log, exp, sqrt, …)
% ar -t /usr/lib/libc.a | sort …fork.o … fprintf.o fpu_control.o fputc.o freopen.o fscanf.o fseek.o fstab.o …
% ar -t /usr/lib/libm.a | sort …e_acos.o e_acosf.o e_acosh.o e_acoshf.o e_acoshl.o e_acosl.o e_asin.o e_asinf.o e_asinl.o …
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Using Static LibrariesLinkerLinker’’s algorithm for resolving external references:s algorithm for resolving external references:
Scan .o files and .a files in the command line order. During the scan, keep a list of the current unresolved
references. As each new .o or .a file obj is encountered, try to resolve
each unresolved reference in the list against the symbols inobj.
If any entries in the unresolved list at end of scan, then error.
Problem:Problem: Command line order matters! Moral: put libraries at the end of the command line.
bass> gcc -L. libtest.o -lmine bass> gcc -L. -lmine libtest.o libtest.o: In function `main': libtest.o(.text+0x4): undefined reference to `libfun'
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Loading Executable Binaries
ELF header
Program header table(required for executables)
.text section
.data section
.bss section
.symtab
.rel.text
.rel.data
.debug
Section header table(required for relocatables)
0
.text segment(r/o)
.data segment(initialized r/w)
.bss segment(uninitialized r/w)
Executable object file for example program p
Process image
0x08048494
init and shared libsegments
0x080483e0
Virtual addr
0x0804a010
0x0804a3b0
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Shared LibrariesStatic libraries have the following disadvantages:Static libraries have the following disadvantages:
Potential for duplicating lots of common code in the executablefiles on a filesystem. e.g., every C program needs the standard C library
Potential for duplicating lots of code in the virtual memory space ofmany processes.
Minor bug fixes of system libraries require each application toexplicitly relink
Solution:Solution: Shared libraries (dynamic link libraries, DLLs) whose members are
dynamically loaded into memory and linked into an application atrun-time. Dynamic linking can occur when executable is first loaded and run.
» Common case for Linux, handled automatically by ld-linux.so. Dynamic linking can also occur after program has begun.
» In Linux, this is done explicitly by user with dlopen().» Basis for High-Performance Web Servers.
Shared library routines can be shared by multiple processes.
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Dynamically Linked Shared Libraries
libc.so functions called by m.cand a.c are loaded, linked, and(potentially) shared amongprocesses.
Shared library of dynamicallyrelocatable object files
Translators(cc1, as)
m.c
m.o
Translators(cc1,as)
a.c
a.o
libc.so
Linker (ld)
p
Loader/Dynamic Linker(ld-linux.so)
Fully linked executablep’ (in memory)
Partially linked executablep(on disk)
P’
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The Complete Picture
Translator
m.c
m.o
Translator
a.c
a.o
libc.so
Static Linker (ld)
p
Loader/Dynamic Linker(ld-linux.so)
libwhatever.a
p’
libm.so
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Next Step: LoadingA loader is a system program that copies the code andA loader is a system program that copies the code and
data in the executable object file from disk intodata in the executable object file from disk intomemory, and then runs the program by jumping tomemory, and then runs the program by jumping toits first instruction.its first instruction.
Copying a program into memory and then running it isCopying a program into memory and then running it isknown as known as loadingloading
A running program is called a A running program is called a processprocessOn modern computer systems, there are manyOn modern computer systems, there are many
processes running at the same timeprocesses running at the same timeHow does this work? I.e., how does the CPU executeHow does this work? I.e., how does the CPU execute
instructions for multiple processes at the same time?instructions for multiple processes at the same time?How is the memory on the computer shared betweenHow is the memory on the computer shared between
the running processes?the running processes?
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Private Address SpacesEach process has its own private address space.Each process has its own private address space.
kernel virtual memory(code, data, heap, stack)
memory mapped region forshared libraries
run-time heap(managed by malloc)
user stack(created at runtime)
unused0
%esp (stack pointer)
memoryinvisible touser code
brk
0xc0000000
0x08048000
0x40000000
read/write segment(.data, .bss)
read-only segment(.init, .text, .rodata)
loaded from the executable file
0xffffffff
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Linux Memory LayoutStackStack
Runtime stack (8MB limit)
HeapHeap Dynamically allocated storage When call malloc, calloc, new
DLLsDLLs Dynamically Linked Libraries Library routines (e.g., printf, malloc) Linked into object code when first executed
DataData Statically allocated data E.g., arrays & strings declared in code
TextText Executable machine instructions Read-only
Upper2 hexdigits ofaddress
Red Hatv. 6.2~1920MBmemorylimit
FF
BF
7F
3F
C0
80
40
00
Stack
DLLs
TextData
Heap
Heap
08
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Linux Memory AllocationLinked
BF
7F
3F
80
40
00
Stack
DLLs
TextData
08
SomeHeap
BF
7F
3F
80
40
00
Stack
DLLs
TextData
Heap
08
MoreHeap
BF
7F
3F
80
40
00
Stack
DLLs
TextDataHeap
Heap
08
InitiallyBF
7F
3F
80
40
00
Stack
TextData
08
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ProcessesDef: A Def: A processprocess is an instance of a running program. is an instance of a running program.
One of the most profound ideas in computer science. Not the same as “program” or “processor”
Process provides each program with two keyProcess provides each program with two keyabstractions:abstractions: Logical control flow
Each program seems to have exclusive use of the CPU. Private address space
Each program seems to have exclusive use of main memory.
How are these Illusions maintained?How are these Illusions maintained? Process executions interleaved (multitasking) Address spaces managed by virtual memory system
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Logical Control Flows
Time
Process A Process B Process C
Each process has its own logical control flow
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Context Switching in Multi-taskedOperating Systems
Processes are managed by a shared chunk of OS codeProcesses are managed by a shared chunk of OS codecalled the called the kernelkernel Important: the kernel is not a separate process, but rather
runs as part of some user process
Control flow passes from one process to another via aControl flow passes from one process to another via acontext switch.context switch.
Process Acode
Process Bcode
user code
kernel code
user code
kernel code
user code
Timecontext switch
context switch
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Private Address SpacesEach process has its own private address space.Each process has its own private address space.
kernel virtual memory(code, data, heap, stack)
memory mapped region forshared libraries
run-time heap(managed by malloc)
user stack(created at runtime)
unused0
%esp (stack pointer)
memoryinvisible touser code
brk
0xc0000000
0x08048000
0x40000000
read/write segment(.data, .bss)
read-only segment(.init, .text, .rodata)
loaded from the executable file
0xffffffff
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Memory Allocation for ProcessesEach process has its own private address spaceEach process has its own private address spaceRange of Memory Addresses for a CPU with a 32-bitRange of Memory Addresses for a CPU with a 32-bit
address: 0 address: 0 –– 2 23232 -1 (4 GB!!) -1 (4 GB!!)Referred to as Address SpaceReferred to as Address SpaceHow can multiple processes be allocated memory at theHow can multiple processes be allocated memory at the
same time?same time?Size of address space of even one process willSize of address space of even one process willtypically exceed size of physical memory!typically exceed size of physical memory!
On many systems, there can be hundreds of On many systems, there can be hundreds ofprocesses running at the same time!processes running at the same time!
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The Solution: Virtual MemoryVirtual memory: an abstraction for main memoryVirtual memory: an abstraction for main memoryThe idea: Treat main memory (physical memory) as aThe idea: Treat main memory (physical memory) as a
cache for an address space that is stored on diskcache for an address space that is stored on diskOnly the active memory of a running process isOnly the active memory of a running process is
allocated physical memory, with the inactive part ofallocated physical memory, with the inactive part ofthe address space stored on diskthe address space stored on disk
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A System with Physical Memory OnlyExamples:Examples:
most Cray machines, early PCs, nearly all embeddedsystems, etc.
Addresses generated by the CPU correspond directly to bytes inphysical memory
CPU
0:1:
N-1:
Memory
PhysicalAddresses
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A System with Virtual MemoryExamples:Examples:
workstations, servers, modern PCs, etc.
Address Translation: Hardware converts virtual addresses tophysical addresses via OS-managed lookup table (page table)
CPU
0:1:
N-1:
Memory
0:1:
P-1:
Page Table
Disk
VirtualAddresses Physical
Addresses
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Motivation for Virtual MemoryUse Physical DRAM as a Cache for the DiskUse Physical DRAM as a Cache for the Disk
Address space of a process can exceed physical memory size Sum of address spaces of multiple processes can exceed
physical memory
Simplify Memory ManagementSimplify Memory Management Multiple processes resident in main memory.
Each process with its own address space Only “active” code and data is actually in memory
Allocate more memory to process as needed.
Provide ProtectionProvide Protection One process can’t interfere with another.
because they operate in different address spaces. User process cannot access privileged information
different sections of address spaces have different permissions.
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Motivation #1: DRAM a “Cache” for DiskFull address space is quite large:Full address space is quite large:
32-bit addresses: ~4,000,000,000 (4 billion) bytes 64-bit addresses: ~16,000,000,000,000,000,000 (16 quintillion)
bytes
Disk storage is ~300X cheaper than DRAM storageDisk storage is ~300X cheaper than DRAM storage 80 GB of DRAM: ~ $33,000 80 GB of disk: ~ $110
To access large amounts of data in a cost-effective manner,To access large amounts of data in a cost-effective manner,the bulk of the data must be stored on diskthe bulk of the data must be stored on disk
1GB: ~$200 80 GB: ~$110
4 MB: ~$500
DiskDRAMSRAM
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VM Address Translation: Hit
Processor
HardwareAddr TransMechanism
MainMemorya
a'
physical addressvirtual address part of the on-chipmemory mgmt unit (MMU)
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VM Address Translation: Miss
Processor
HardwareAddr TransMechanism
faulthandler
MainMemory
Secondarymemorya
a'
∅
page fault
physical address OS performsthis transfer(only if miss)
virtual address part of the on-chipmemory mgmt unit (MMU)
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A System with Virtual MemoryExamples:Examples:
workstations, servers, modern PCs, etc.
Address Translation: Hardware converts virtual addresses tophysical addresses via OS-managed lookup table (page table)
CPU
0:1:
N-1:
Memory
0:1:
P-1:
Page Table
Disk
VirtualAddresses Physical
Addresses
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Page Faults (like “Cache Misses”)What if an object is on disk rather than in memory?What if an object is on disk rather than in memory?
Page table entry indicates virtual address not in memory OS exception handler invoked to move data from disk into
memory current process suspends, others can resume OS has full control over placement, etc.
CPU
Memory
Page Table
Disk
VirtualAddresses Physical
Addresses
CPU
Memory
Page Table
Disk
VirtualAddresses Physical
Addresses
Before fault After fault
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Servicing a Page FaultProcessor Signals ControllerProcessor Signals Controller
Read block of length Pstarting at disk address X andstore starting at memoryaddress Y
Read OccursRead Occurs Direct Memory Access (DMA) Under control of I/O controller
I / O Controller SignalsI / O Controller SignalsCompletionCompletion Interrupt processor OS resumes suspended
process
diskDiskdiskDisk
Memory-I/O bus
Processor
Cache
MemoryI/O
controller
Reg
(2) DMATransfer
(1) Initiate Block Read
(3) ReadDone
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Motivation #2: Memory ManagementMultiple processes can reside in physical memory.Multiple processes can reside in physical memory.How do we resolve address conflicts?How do we resolve address conflicts?
what if two processes access something at the sameaddress?
kernel virtual memory
Memory mapped region forshared libraries
runtime heap (via malloc)
program text (.text)initialized data (.data)
uninitialized data (.bss)
stack
forbidden0
%esp
memory invisible to user code
the “brk” ptr
Linux/x86processmemoryimage
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VirtualAddressSpace forProcess 1:
PhysicalAddressSpace(DRAM)
VP 1VP 2
PP 2Address Translation0
0
N-1
0
N-1M-1
VP 1VP 2
PP 7
PP 10
(e.g., read/onlylibrary code)
Solution: Separate Virt. Addr. Spaces Virtual and physical address spaces divided into equal-sized
blocks blocks are called “pages” (both virtual and physical)
Each process has its own virtual address space operating system controls how virtual pages as assigned to
physical memory
...
...
VirtualAddressSpace forProcess 2:
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Motivation #3: ProtectionPage table entry contains access rights informationPage table entry contains access rights information
hardware enforces this protection (trap into OS if violationoccurs) Page Tables
Process i:
Physical AddrRead? Write? PP 9Yes No
PP 4Yes Yes
XXXXXXX No No
VP 0:
VP 1:
VP 2:•••
••••••
Process j:
0:1:
N-1:
Memory
Physical AddrRead? Write? PP 6Yes Yes
PP 9Yes No
XXXXXXX No No•••
••••••
VP 0:
VP 1:
VP 2:
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Concluding RemarksProcesses and Virtual Memory are two of the greatProcesses and Virtual Memory are two of the great
ideas in computer scienceideas in computer scienceCS 471 (Operating Systems) will cover these conceptsCS 471 (Operating Systems) will cover these concepts
in detailin detailCS 365 (Computer Architecture) discusses memoryCS 365 (Computer Architecture) discusses memory
management and virtual memorymanagement and virtual memory
Next lecture: Writing programs thatNext lecture: Writing programs that Create and manipulate processes Send and receive “signals”