Difference between revisions of "Operating Systems 2019F Lecture 11"
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==Video== | |||
The video from the lecture given on October 9, 2019 [https://homeostasis.scs.carleton.ca/~soma/os-2019f/lectures/comp3000-2019f-lec11-20191009.m4v is now available]. | |||
==Topics== | ==Topics== | ||
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** CPU stack, stack allocation | ** CPU stack, stack allocation | ||
** function calling conventions | ** function calling conventions | ||
==Notes== | |||
<pre> | |||
Lecture 11 | |||
---------- | |||
Assembly language | |||
In UNIX, a process is one or more execution contexts plus an address space | |||
Address space: range of memory, parts that may or may not be allocated | |||
execution context: set of CPU registers, state of a core | |||
- instruction pointer | |||
- stack pointer | |||
- general registers | |||
- condition register | |||
modern systems multiplex the CPU between processes | |||
- saving and restoring CPU registers, switching address spaces | |||
the stack is important because that's how we do the cheap memory | |||
management associated with functions | |||
To call a function, you | |||
- gather arguments <--- pushed onto the stack or put in registers | |||
- save where you are <--- save instruction pointer (IP) to the stack (push) | |||
- run the function <--- call | |||
- continue on <--- function call ret, popping IP from the stack | |||
When a function runs, you | |||
- save registers <--- the caller may care about state of registers, so | |||
push them on stack | |||
- allocate local variables <--- change stack pointer | |||
- do work | |||
- restore registers <--- pop them | |||
- return <--- pop return address (IP of caller) | |||
Make sure you understand push, pop, call, ret | |||
Midterm review, part 1 | |||
---------------------- | |||
How does a shell work? | |||
Key system calls for managing processes | |||
* fork | |||
* execve | |||
* wait (+ exit) | |||
* sigaction | |||
* kill | |||
File I/O | |||
* open/openat | |||
* read | |||
* write | |||
* lseek | |||
* mmap | |||
* close | |||
Directory I/O | |||
* opendir/open | |||
* readdir/getdents64 | |||
* closedir/close | |||
Signals | |||
- messages your process can receive at any time | |||
- when your process has a signal, the signal handler *will be called* | |||
- the instruction pointer will be changed to the signal handler | |||
mmap | |||
- normal file I/O is read/write | |||
- mmap allows us to map file data into a process's address space | |||
- accessing memory is equivalent to doing read/write to file | |||
Couple of key variations | |||
- read-only mmap of file, normaly with PROT_EXEC | |||
* load code (executable, libraries) | |||
* read-only data (no PROT_EXEC) | |||
- read-write mmap, shared, of file | |||
* modifying file on disk | |||
- read-write mmap, private, of file | |||
* copy file to memory, modify memory | |||
- read-write mmap, anonymous, shared | |||
* allocate memory shared between processes | |||
- read-write mmap, anonymous, private | |||
* allocate memory private to process | |||
File permissions, hard links, symbolic links | |||
* file data versus metadata | |||
inodes contain | |||
- file owner, group, perms | |||
- size of file | |||
- modification times | |||
- data or references to other data blocks | |||
hard link is a filename that refers to an inode | |||
lseek | |||
- associated with every open file is a file position | |||
- lseek lets you change it | |||
- lseek past the end of a file and then write - create a "hole" | |||
- all zeros are filled in | |||
- space in between not allocated | |||
</pre> | |||
Latest revision as of 18:05, 9 October 2019
Video
The video from the lecture given on October 9, 2019 is now available.
Topics
- UNIX pipes
- Assembly language, try 2
- CPU registers: general, stack, base, condition
- CPU stack, stack allocation
- function calling conventions
Notes
Lecture 11
----------
Assembly language
In UNIX, a process is one or more execution contexts plus an address space
Address space: range of memory, parts that may or may not be allocated
execution context: set of CPU registers, state of a core
- instruction pointer
- stack pointer
- general registers
- condition register
modern systems multiplex the CPU between processes
- saving and restoring CPU registers, switching address spaces
the stack is important because that's how we do the cheap memory
management associated with functions
To call a function, you
- gather arguments <--- pushed onto the stack or put in registers
- save where you are <--- save instruction pointer (IP) to the stack (push)
- run the function <--- call
- continue on <--- function call ret, popping IP from the stack
When a function runs, you
- save registers <--- the caller may care about state of registers, so
push them on stack
- allocate local variables <--- change stack pointer
- do work
- restore registers <--- pop them
- return <--- pop return address (IP of caller)
Make sure you understand push, pop, call, ret
Midterm review, part 1
----------------------
How does a shell work?
Key system calls for managing processes
* fork
* execve
* wait (+ exit)
* sigaction
* kill
File I/O
* open/openat
* read
* write
* lseek
* mmap
* close
Directory I/O
* opendir/open
* readdir/getdents64
* closedir/close
Signals
- messages your process can receive at any time
- when your process has a signal, the signal handler *will be called*
- the instruction pointer will be changed to the signal handler
mmap
- normal file I/O is read/write
- mmap allows us to map file data into a process's address space
- accessing memory is equivalent to doing read/write to file
Couple of key variations
- read-only mmap of file, normaly with PROT_EXEC
* load code (executable, libraries)
* read-only data (no PROT_EXEC)
- read-write mmap, shared, of file
* modifying file on disk
- read-write mmap, private, of file
* copy file to memory, modify memory
- read-write mmap, anonymous, shared
* allocate memory shared between processes
- read-write mmap, anonymous, private
* allocate memory private to process
File permissions, hard links, symbolic links
* file data versus metadata
inodes contain
- file owner, group, perms
- size of file
- modification times
- data or references to other data blocks
hard link is a filename that refers to an inode
lseek
- associated with every open file is a file position
- lseek lets you change it
- lseek past the end of a file and then write - create a "hole"
- all zeros are filled in
- space in between not allocated