[FreeBSD] Resource Services

2024. 7. 15. 19:44ใ†ComputerScience/FreeBSD

 

 

 

3.7 Resource Services

All systems have limits imposed by their hardware architecture and configuration to ensure reasonable operation and to keep users from accidentally (or maliciously) creating resource shortages. (์˜ค์˜ค.. ๋ชจ๋“  ์‹œ์Šคํ…œ์€ ํ•œ๊ณ„๋ฅผ ๊ฐ€์ง„๋‹ค by ์•ˆ์ •์„ฑ)

At a minimum, the hardware limits must be imposed on processes that run on the system. It is usually desirable to limit processes further, below these hardware-imposed limits. The system measures resource utilization and allows limits to be imposed on consumption either at or below the hardware-imposed limits. (ํ•˜๋“œ์›จ์–ด ์ œ์•ฝ์„ ๊ณ ๋ คํ•˜์—ฌ, ์‹œ์Šคํ…œ์˜ ์ž์›์„ ํ™œ์šฉํ•˜๋„๋ก OS๊ฐ€ ์ปจํŠธ๋กคํ•œ๋‹ค๋Š” ์˜๋ฏธ)

 

 

 

Process Priorities

The default scheduling policy in the FreeBSD system is managed by the share scheduler that gives CPU scheduling priority to processes that have not used CPU time recently. This priority scheme tends to favor processes that execute for only short periods of time - for example, interactive processes. The priority selected for each process is maintained internally by the kernel. The calculation of the priority is affected by the per-process nice variable. Positive nice values mean that the process is willing to receive less than its share of the processor. Negative values of nice mean that the process wants more than its share of the processor. Most processes run with the default nice value of zero, asking neither higher nor lower access to the processor.

 

It is possible to determine or change the nice currently assigned to a process, to a process group, or to the processes of a specified user. Many factors other than nice affect scheduling, including the amount of CPU time that the process has used recently, the amount of memory that the process has used recently, and the current load on the system. (nice ๋ณ€์ˆ˜ ๊ฐ’ ์ด์™ธ์—๋„ ๋‹ค์–‘ํ•œ ์š”์ธ๋“ค์ด ์Šค์ผ€์ฅด๋ง์— ํ™œ์šฉ๋จ) 

 

In addition to the share scheduler described here, the FreeBSD system also has a real-time scheduler available. The real-time scheduler allows processes to precisely control their order of execution (์ˆœ์„œ๊ฐ€ ์ค‘์š”ํ•œ ๊ฒฝ์šฐ) and the amount of time given to each process. The details of the share and real-time scheduling algorithms are described in Section 4.4.

 

 

 

Resource Utilization

As a process executes, it uses system resources such as the CPU and memory. The kernel tracks the resources used by each process and compiles statistics describing this usage. The statistics managed by the kernel are available to a process while the latter is executing. When a process terminates, the statistics are made available to its parent via the wait family of system calls. 

 

The resources used by a process are returned by the system call getrusage. The resources used by the current process, or by all the terminated children of the current process, may be requested.

The following information is included:

• The amount of user and system time used by the process

• The memory utilization of the process

• The paging and disk I/O activity of the process

• The number of voluntary and involuntary context switches taken by the process

• The amount of interprocess communication (IPC) done by the process

 

The resource-usage information is collected at locations throughout the kernel. The CPU time is collected by the statclock() function, which is called either by the system clock in hardclock(), or, if an alternate clock is available, by the alternate-clock interrupt process. The kernel scheduler calculates memory utilization by sampling the amount of memory that an active process is using at the same time that it is recomputing process priorities. The vm_fault() routine recalculates the paging activity each time that it starts a disk transfer to fulfill a paging request (see Section 6.11). The I/O activity statistics are collected each time that the process has to start a transfer to fulfill a file or device I/O request, as well as when the general system statistics are calculated. The IPC communication activity is updated each time that information is sent or received.

 

 

 

Resource Limits

The kernel also supports limiting certain per-process resources. These resources include the following: 

(ํ”„๋กœ์„ธ์Šค์˜ ์ž์› ์‚ฌ์šฉ์— ์ œํ•œ์„ ๊ฑฐ๋Š” ๊ฒƒ) 

• The maximum amount of CPU time that can be accumulated

• The maximum bytes that a process can request be locked into memory

• The maximum size of a process’s data segment

• The maximum size of a process’s stack segment

• The maximum amount of private physical memory that a process may have at any given moment

• The maximum amount of private or shared physical memory that a process may have at any given moment

• The maximum amount of physical memory that a process may have dedicated to socket buffers

• The maximum size of a file that can be created by a process

• The maximum size of a core file that can be created by a process

• The maximum number of simultaneous open files for a process

• The maximum number of simultaneous processes allowed to a user

 

For each resource controlled by the kernel, two limits are maintained: a soft limit and a hard limit.

All users can alter the soft limit within the range of 0 to the corresponding hard limit. All users can (irreversibly) lower the hard limit, but only the superuser can raise the hard limit. If a process exceeds certain soft limits, a signal is delivered to the process to notify it that a resource limit has been exceeded. Normally, this signal causes the process to terminate, but the process may either catch or ignore the signal. If the process ignores the signal and fails to release resources that it already holds, further attempts to obtain more resources will result in errors. 

 

Resource limits are generally enforced at or near the locations that the resource statistics are collected. The CPU time limit is enforced in the process context-switching function. The stack and data-segment limits are enforced by a return of allocation failure once those limits have been reached. The file-size limit is enforced by the filesystem.

 

 

 

Filesystem Quotas

In addition to limits on the size of individual files, the kernel optionally enforces limits on the total amount of space that a user or group can use on a filesystem. (ํŒŒ์ผ์‹œ์Šคํ…œ ํ• ๋‹น๋Ÿ‰์— ๋Œ€ํ•œ ์ œํ•œ) Our discussion of the implementation of these limits is deferred to Section 9.4.

 

 

 

https://www.tecmint.com/set-limits-on-user-processes-using-ulimit-in-linux/

 

 

 

https://linux.die.net/man/5/limits.conf

 

 

 

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