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Part II. Common Tasks
Chapter 8. Configuring the FreeBSD Kernel
Configuring the FreeBSD Kernel
Synopsis
The kernel is the core of the FreeBSD operating system. It is responsible for managing memory, enforcing security controls, networking, disk access, and much more. While much of FreeBSD is dynamically configurable, it is still occasionally necessary to configure and compile a custom kernel.
After reading this chapter, you will know:
When to build a custom kernel.
How to take a hardware inventory.
How to customize a kernel configuration file.
How to use the kernel configuration file to create and build a new kernel.
How to install the new kernel.
How to troubleshoot if things go wrong.
All of the commands listed in the examples in this chapter should be executed as `root`.
Why Build a Custom Kernel?
Traditionally, FreeBSD used a monolithic kernel. The kernel was one large program, supported a fixed list of devices, and in order to change the kernel's behavior, one had to compile and then reboot into a new kernel.
Today, most of the functionality in the FreeBSD kernel is contained in modules which can be dynamically loaded and unloaded from the kernel as necessary. This allows the running kernel to adapt immediately to new hardware and for new functionality to be brought into the kernel. This is known as a modular kernel.
Occasionally, it is still necessary to perform static kernel configuration. Sometimes the needed functionality is so tied to the kernel that it can not be made dynamically loadable. Some security environments prevent the loading and unloading of kernel modules and require that only needed functionality is statically compiled into the kernel.
Building a custom kernel is often a rite of passage for advanced BSD users. This process, while time consuming, can provide benefits to the FreeBSD system. Unlike the [.filename]#GENERIC# kernel, which must support a wide range of hardware, a custom kernel can be stripped down to only provide support for that computer's hardware. This has a number of benefits, such as:
Faster boot time. Since the kernel will only probe the hardware on the system, the time it takes the system to boot can decrease.
Lower memory usage. A custom kernel often uses less memory than the [.filename]#GENERIC# kernel by omitting unused features and device drivers. This is important because the kernel code remains resident in physical memory at all times, preventing that memory from being used by applications. For this reason, a custom kernel is useful on a system with a small amount of RAM.