Demand paging
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In computer operating systems, demand paging is a simple method of implementing virtual memory. In a system that uses demand paging, the operating system copies a page into physical memory only if an attempt is made to access it (i.e., if a page fault occurs). It follows that a process begins execution with none of its pages in physical memory, and many page faults will occur until most of a process's working set of pages is located in physical memory. This is an example of lazy loading techniques.
Advantages of demand paging:
- Does not load the pages that are never accessed, so saves the memory for other programs and increases the degree of multiprogramming.
- Less loading latency at the program startup.
- Less disk overhead because of fewer page reads.
- Pages will be shared by multiple programs until they are modified by one of them, so a technique called copy on write will be used to save more resources.
- Ability to run large programs on the machine, even though it does not have sufficient memory to run the program. This method is better than an old technique called overlays.
- Does not need extra hardware support than what paging needs, since protection fault can be used to get page fault.
Disadvantages:
- Individual programs face extra latency when they access a page for the first time. So prepaging, a method of remembering which pages a process used when it last executed and preloading few of them, is used to improve performance.
- Memory management with page replacement algorithms become slightly more complex.
In unix systems such as Linux, demand paging is accomplished by the means of the mmap() system call. It is also used when executing new programs. The operating system maps the executable file (and its dependent libraries) into the address space of the newly executing program, without actually allocating any physical RAM for the contents of those files. When the mappings are read-only and shared, the program may actually run literally from the disk cache.
[edit] See also
[edit] References
- Tanenbaum, Andrew S. Operating Systems: Design and Implementation (Second Edition). New Jersey: Prentice-Hall 1997.