Difference between revisions of "OS: Pengertian Kernel Modul"

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(New page: Sumber: http://en.wikipedia.org/wiki/Kernel_module In computing, a '''loadable kernel module''' (or '''LKM''') is an object file that contains code to extend the running [[kern...)
 
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Sumber: http://en.wikipedia.org/wiki/Kernel_module
 
Sumber: http://en.wikipedia.org/wiki/Kernel_module
  
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Dalam dunia komputasi, '''Loadable Kernel Module''' (atau'''LKM''') adalah sebuah [[object file]] yang berisi code yang memperluas fungsi [[kernel]] yang berjalan, atau biasa disebut ''base kernel'', dari sebuah [[sistem operasi]]. LKM biasanya digunakan untuk dukungan bagi [[hardware]] baru atau [[filesystem]] baru, atau menambahkan [[system call]]. Saat fungsi yang diberikan oleh LKM tidak lagi dibutuhkan, kita dapat meng-unload LKM tersebut untuk membebaskan [[memory]] maupun sumber daya lainnya.
  
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Sebagia besar sistem [[Unix-like]] yang baru dan [[Microsoft Windows]] mendukung loadable kernel modules, meskipun mereka akan menggunakan nama lain, seperti '''kernel loadable module''' ('''kld''') di [[FreeBSD]], '''kernel extension''' ('''kext''') di [[OS X]] dan '''kernel-mode driver''' di Windows NT. Dia juga sering dikenali sebagai '''Kernel Loadable Module''' (atau '''KLM'''), atau hanya '''Kernel Module''' ('''KMOD''').
  
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== Keuntungan ==
  
In [[computing]], a '''loadable kernel module''' (or '''LKM''') is an [[object file]] that contains code to extend the running [[kernel (computer science)|kernel]], or so-called ''base kernel'', of an [[operating system]]. LKMs are typically used to add support for new [[computer hardware|hardware]] and/or [[filesystem]]s, or for adding [[system call]]s. When the functionality provided by a LKM is no longer required, it can be unloaded in order to free [[computer storage|memory]] and other resources.
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Without loadable kernel modules, an operating system would have to include all possible anticipated functionality already compiled directly into the base kernel. Much of that functionality would reside in memory without being used, wasting memory, and would require that users rebuild and [[booting|reboot]] the base kernel every time they require new functionality. Most operating systems supporting loadable kernel modules will include modules to support most desired functionality.
  
Most current [[Unix-like]] systems and [[Microsoft Windows]] support loadable kernel modules, although they might use a different name for them, such as '''kernel loadable module''' ('''kld''') in [[FreeBSD]], '''kernel extension''' ('''kext''') in [[OS X]] and '''kernel-mode driver''' in Windows NT. They are also known as '''Kernel Loadable Modules''' (or '''KLM'''), and simply as '''Kernel Modules''' ('''KMOD''').
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== Kerugian ==
 
 
== Advantages ==
 
Without loadable kernel modules, an operating system would have to include all possible anticipated functionality already compiled directly into the base kernel. Much of that functionality would reside in memory without being used, wasting memory, and would require that users rebuild and [[booting|reboot]] the base kernel every time they require new functionality. Most operating systems supporting loadable kernel modules will include modules to support most desired functionality.
 
  
== Disadvantages ==
 
 
One minor criticism of preferring a modular kernel over a static kernel is the so-called ''[[Fragmentation (computer)|Fragmentation]] Penalty''.
 
One minor criticism of preferring a modular kernel over a static kernel is the so-called ''[[Fragmentation (computer)|Fragmentation]] Penalty''.
 
The ''base kernel'' is always unpacked into ''real'' contiguous [[Random-access memory|memory]] by its setup routines; so, the base kernel code is never fragmented. Once the system is in a state where modules may be inserted—for example, once the [[filesystem]]s have been [[Mount (computing)|mount]]ed that contain the modules—it is probable that any new kernel code insertion will cause the kernel to become fragmented, thereby introducing a minor performance penalty.
 
The ''base kernel'' is always unpacked into ''real'' contiguous [[Random-access memory|memory]] by its setup routines; so, the base kernel code is never fragmented. Once the system is in a state where modules may be inserted—for example, once the [[filesystem]]s have been [[Mount (computing)|mount]]ed that contain the modules—it is probable that any new kernel code insertion will cause the kernel to become fragmented, thereby introducing a minor performance penalty.
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</source>
 
</source>
  
The string comparison code used by the kernel at the time tried to determine whether the module was GPLed stopped when it reached a null character (<tt>\0</tt>), so it would be fooled into thinking that the module was declaring its license to be just "GPL".
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The string comparison code used by the kernel at the time tried to determine whether the module was GPLed stopped when it reached a null character (<tt>\0</tt>), so it would be fooled into thinking that the module was declar
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ing its license to be just "GPL".
  
 
=== FreeBSD ===
 
=== FreeBSD ===

Revision as of 11:12, 13 April 2014

Sumber: http://en.wikipedia.org/wiki/Kernel_module

Dalam dunia komputasi, Loadable Kernel Module (atauLKM) adalah sebuah object file yang berisi code yang memperluas fungsi kernel yang berjalan, atau biasa disebut base kernel, dari sebuah sistem operasi. LKM biasanya digunakan untuk dukungan bagi hardware baru atau filesystem baru, atau menambahkan system call. Saat fungsi yang diberikan oleh LKM tidak lagi dibutuhkan, kita dapat meng-unload LKM tersebut untuk membebaskan memory maupun sumber daya lainnya.

Sebagia besar sistem Unix-like yang baru dan Microsoft Windows mendukung loadable kernel modules, meskipun mereka akan menggunakan nama lain, seperti kernel loadable module (kld) di FreeBSD, kernel extension (kext) di OS X dan kernel-mode driver di Windows NT. Dia juga sering dikenali sebagai Kernel Loadable Module (atau KLM), atau hanya Kernel Module (KMOD).

Keuntungan

Without loadable kernel modules, an operating system would have to include all possible anticipated functionality already compiled directly into the base kernel. Much of that functionality would reside in memory without being used, wasting memory, and would require that users rebuild and reboot the base kernel every time they require new functionality. Most operating systems supporting loadable kernel modules will include modules to support most desired functionality.

Kerugian

One minor criticism of preferring a modular kernel over a static kernel is the so-called Fragmentation Penalty. The base kernel is always unpacked into real contiguous memory by its setup routines; so, the base kernel code is never fragmented. Once the system is in a state where modules may be inserted—for example, once the filesystems have been mounted that contain the modules—it is probable that any new kernel code insertion will cause the kernel to become fragmented, thereby introducing a minor performance penalty.

Implementations in different operating systems

Linux

Loadable kernel modules in Linux are loaded (and unloaded) by the modprobe command. They are located in /lib/modules and have had the extension .ko ("kernel object") since version 2.6 (previous versions used the .o extension). The lsmod command lists the loaded kernel modules. In emergency cases, when the system fails to boot due to e.g. broken modules, specific modules can be enabled or disabled by modifying the kernel boot parameters list (for example, if using GRUB, by pressing 'e' in the GRUB start menu, then editing the kernel parameter line).

License issues

In the opinion of Linux maintainers, LKM are derived works of the kernel. The Linux maintainers tolerate the distribution of proprietary modules,Template:Citation needed but allow symbols to be marked as only available to GNU General Public License (GPL) modules.

Loading a proprietary or non-GPL-compatible LKM will set a 'taint' flag in the running kernel—meaning that any problems or bugs experienced will be less likely to be investigated by the maintainers. LKMs effectively become part of the running kernel, so can corrupt kernel data structures and produce bugs that may not be able to be investigated if the module is indeed proprietary.

Linuxant controversy

In 2004, Linuxant—a consulting company that releases proprietary device drivers as loadable kernel modules—attempted to bypass GPLONLY symbol restrictions by abusing a NULL terminator in their MODULE_LICENSE:

<source lang="text"> MODULE_LICENSE("GPL\0for files in the \"GPL\" directory; for others, only LICENSE file applies"); </source>

The string comparison code used by the kernel at the time tried to determine whether the module was GPLed stopped when it reached a null character (\0), so it would be fooled into thinking that the module was declar ing its license to be just "GPL".

FreeBSD

Kernel modules for FreeBSD are stored within /boot/kernel/ for modules distributed with the OS, or usually /boot/modules/ for modules installed from FreeBSD ports or FreeBSD packages, or for proprietary or otherwise binary-only modules. FreeBSD kernel modules usually have the extension .ko. Once the machine has booted, they may be loaded with the kldload command, unloaded with kldunload, and listed with kldstat. Modules can also be loaded from the loader before the kernel starts, either automatically (through /boot/loader.conf) or by hand.

OS X

Some loadable kernel modules in OS X can be loaded automatically. Loadable kernel modules can also be loaded by the kextload command. They can be listed by the kextstat command. Loadable kernel modules are located in application bundles with the extension .kext. Modules supplied with the operating system are stored in the /System/Library/Extensions directory; modules supplied by third parties are in various other directories.

Binary compatibility

Linux does not provide a stable API or ABI for kernel modules. This means that there are differences in internal structure and function between different kernel versions, which can cause compatibility problems. In an attempt to combat those problems, symbol versioning data is placed within the .modinfo section of loadable ELF modules. This versioning information can be compared with that of the running kernel before loading a module; if the versions are incompatible, the module will not be loaded.

Other operating systems, such as Solaris, FreeBSD, OS X, and Windows keep the kernel API and ABI relatively stable, thus avoiding this problem. For example, FreeBSD kernel modules compiled against kernel version 6.0 will work without recompilation on any other FreeBSD 6.x version, e.g. 6.4. However, they are not compatible with other major versions and must be recompiled for use with FreeBSD 7.x, as API and ABI compatibility is maintained only within a branch.

Security

While loadable kernel modules are a convenient method of modifying the running kernel, this can be abused by attackers on a compromised system to prevent detection of their processes or files, allowing them to maintain control over the system. Many rootkits make use of LKMs in this way. Note that on most operating systems modules do not help privilege elevation in any way, as elevated privilege is required to load a LKM; they merely make it easier for the attacker to hide the break-in.

Linux

Linux allows disabling module loading via sysctl option /proc/sys/kernel/modules_disabled. An initramfs system may load specific modules needed for a machine at boot and then disable module loading. This makes the security very similar to a monolithic kernel. If an attacker can change the initramfs, they can change the kernel binary.

OS X

On OS X, a loadable kernel module in a kernel extension bundle can be loaded by non-root users if the OSBundleAllowUserLoad property is set to True in the bundle's property list. However, if any of the files in the bundle, including the executable code file, are not owned by root and group wheel, or are writable by the group or "other", the attempt to load the kernel loadable module will fail.

External links


Referensi