xref: /original-bsd/usr.sbin/config/SMM.doc/2.t (revision a1c2194a)
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%sccs.include.redist.roff%

@(#)2.t 6.3 (Berkeley) 04/17/91

.ds RH "Configuration File Contents
CONFIGURATION FILE CONTENTS

A system configuration must include at least the following pieces of information:

\(bu 3
machine type
\(bu 3
cpu type
\(bu 3
system identification
\(bu 3
timezone
\(bu 3
maximum number of users
\(bu 3
location of the root file system
\(bu 3
available hardware

Config allows multiple system images to be generated from a single configuration description. Each system image is configured for identical hardware, but may have different locations for the root file system and, possibly, other system devices. Machine type

The "machine type" indicates if the system is going to operate on a DEC VAX-11\(dg computer, .FS \(dg DEC, VAX, UNIBUS, MASSBUS and MicroVAX are trademarks of Digital Equipment Corporation. .FE or some other machine on which 4.3BSD operates. The machine type is used to locate certain data files which are machine specific, and also to select rules used in constructing the resultant configuration files. Cpu type

The "cpu type" indicates which, of possibly many, cpu's the system is to operate on. For example, if the system is being configured for a VAX-11, it could be running on a VAX 8600, VAX-11/780, VAX-11/750, VAX-11/730 or MicroVAX II. (Other VAX cpu types, including the 8650, 785 and 725, are configured using the cpu designation for compatible machines introduced earlier.) Specifying more than one cpu type implies that the system should be configured to run on any of the cpu's specified. For some types of machines this is not possible and config will print a diagnostic indicating such. System identification

The "system identification" is a moniker attached to the system, and often the machine on which the system is to run. For example, at Berkeley we have machines named Ernie (Co-VAX), Kim (No-VAX), and so on. The system identifier selected is used to create a global C ``#define'' which may be used to isolate system dependent pieces of code in the kernel. For example, Ernie's Varian driver used to be special cased because its interrupt vectors were wired together. The code in the driver which understood how to handle this non-standard hardware configuration was conditionally compiled in only if the system was for Ernie.

The system identifier ``GENERIC'' is given to a system which will run on any cpu of a particular machine type; it should not otherwise be used for a system identifier. Timezone

The timezone in which the system is to run is used to define the information returned by the gettimeofday\|(2) system call. This value is specified as the number of hours east or west of GMT. Negative numbers indicate a value east of GMT. The timezone specification may also indicate the type of daylight savings time rules to be applied. Maximum number of users

The system allocates many system data structures at boot time based on the maximum number of users the system will support. This number is normally between 8 and 40, depending on the hardware and expected job mix. The rules used to calculate system data structures are discussed in Appendix D. Root file system location

When the system boots it must know the location of the root of the file system tree. This location and the part(s) of the disk(s) to be used for paging and swapping must be specified in order to create a complete configuration description. Config uses many rules to calculate default locations for these items; these are described in Appendix B.

When a generic system is configured, the root file system is left undefined until the system is booted. In this case, the root file system need not be specified, only that the system is a generic system. Hardware devices

When the system boots it goes through an autoconfiguration phase. During this period, the system searches for all those hardware devices which the system builder has indicated might be present. This probing sequence requires certain pieces of information such as register addresses, bus interconnects, etc. A system's hardware may be configured in a very flexible manner or be specified without any flexibility whatsoever. Most people do not configure hardware devices into the system unless they are currently present on the machine, expect them to be present in the near future, or are simply guarding against a hardware failure somewhere else at the site (it is often wise to configure in extra disks in case an emergency requires moving one off a machine which has hardware problems).

The specification of hardware devices usually occupies the majority of the configuration file. As such, a large portion of this document will be spent understanding it. Section 6.3 contains a description of the autoconfiguration process, as it applies to those planning to write, or modify existing, device drivers. Pseudo devices

Several system facilities are configured in a manner like that used for hardware devices although they are not associated with specific hardware. These system options are configured as pseudo-devices . Some pseudo devices allow an optional parameter that sets the limit on the number of instances of the device that are active simultaneously. System options

Other than the mandatory pieces of information described above, it is also possible to include various optional system facilities or to modify system behavior and/or limits. For example, 4.3BSD can be configured to support binary compatibility for programs built under 4.1BSD. Also, optional support is provided for disk quotas and tracing the performance of the virtual memory subsystem. Any optional facilities to be configured into the system are specified in the configuration file. The resultant files generated by config will automatically include the necessary pieces of the system.