config(5) - NetBSD Manual Pages

CONFIG(5)                 NetBSD File Formats Manual                 CONFIG(5)


NAME
config -- kernel configuration file syntax
DESCRIPTION
The kernel configuration file specifies the way the kernel should be com- piled by the rest of the toolchain. It is processed by config(1) to pro- duce a number of files that will allow the user to compile a possibly customised kernel. One compilation can issue several kernel binaries, with different root and dump devices configurations, or with full debug- ging information. This manual page is intended to serve as a complete reference of all aspects of the syntax used in the many files processed by config(1). The novice user will prefer looking at the examples given in config.samples(5) in order to understand better how the default configu- ration can be changed, and how all of its elements interact with each other. The kernel configuration file actually contains the description of all the options, drivers and source files involved in the kernel compilation, and the logic that binds them. The machine statement, usually found in the std.${MACHINE} file, hides this from the user by automatically including all the descriptive files spread all around the kernel source tree, the main one being conf/files. Thus, the kernel configuration file contains two parts: the description of the compilation options, and the selection of those options. However, it begins with a small preamble that controls a couple of options of config(1), and a few statements belong to any of the two sections. The user controls the options selection part, which is located in a file commonly referenced as the main configuration file or simply the kernel configuration file. The developer is responsible for describing the options in the relevant files from the kernel source tree. Statements are separated by new-line characters. However, new-line char- acters can appear in the middle of a given statement, with the value of a space character. OBJECTS AND NAMES config(1) is a rather complicated piece of software that tries to comply with any configuration the user might think of. Quite a few different objects are manipulated through the kernel configuration file, therefore some definitions are needed. Options and attributes The basic objects driving the kernel compilation are options, and are called attributes in some contexts. An attribute usually refers to a feature a given piece of hardware might have. However, the scope of an attribute is rather wide and can just be a place holder to group some source files together. There is a special class of attribute, named interface attribute, which represents a hook that allows a device to attach to (i.e., be a child of) another device. An interface attribute has a (possibly empty) list of locators to match the actual location of a device. For example, on a PCI bus, devices are located by a device number that is fixed by the wiring of the motherboard. Additionally, each of those devices can appear through several interfaces named functions. A single PCI device entity is a unique function number of a given device from the considered PCI bus. Therefore, the locators for a pci(4) device are dev (for device), and function. A locator can either be a single integer value, or an array of integer values. It can have a default value, in which case it can be wildcarded with a ``?'' in the options selection section of the configuration file. A single locator definition can take one of the following forms: 1. locator 2. locator = value 3. locator[length] 4. locator[length] = {value, ...} The variants that specify a default value can be enclosed into square brackets, in which case the locator will not have to be specified later in the options selection section of the configuration file. In the options selection section, the locators are specified when declar- ing an instance as a space-separated list of ``<locator> <value>'' where value can be the ``?'' wildcard if the locator allows it. Devices, instances and attachments The main benefit of the kernel configuration file is to allow the user to avoid compiling some drivers, and wire down the configuration of some others. We have already seen that devices attach to each other through interface attributes, but not everything can attach to anything. Fur- thermore, the user has the ability to define precise instances for the devices. An instance is simply the reality of a device when it is probed and attached by the kernel. Each driver has a name for its devices. It is called the base device name and is found as base in this documentation. An instance is the con- catenation of a device name and a number. In the kernel configuration file, instances can sometimes be wildcarded (i.e., the number is replaced by a ``*'' or a ``?'') in order to match all the possible instances of a device. The usual ``*'' becomes a ``?'' when the instance name is used as an attachment name. In the options selection part of the kernel configura- tion files, an attachment is an interface attribute concatenated with a number or the wildcard ``?''. Pseudo-devices Some components of the kernel behave like a device although they don't have any actual reality in the hardware. For example, this is the case for special network devices, such as tun(4) and tap(4). They are inte- grated in the kernel as pseudo-devices, and can have several instances and even children, just like normal devices. Dependencies The options description part of the kernel configuration file contains all the logic that ties the source files together, and it is done first through writing down dependencies between config(1) objects. In this documentation, the syntax for dependencies is a comma-separated list of options and attributes. For example, the use of an Ethernet network card requires the source files that handle the specificities of that protocol. Therefore, all Ethernet network card drivers depend on the ether attribute. Conditions Finally, source file selection is possible through the help of condition- als, referred to as condition later in this documentation. The syntax for those conditions uses well-known operators ( ``&'', ``|'' and ``!'') to combine options and attributes. CONTEXT NEUTRAL STATEMENTS version yyyymmdd Indicates the syntax version used by the rest of the file, or until the next version statement. The argument is an ISO date. A given config(1) binary might only be compatible with a limited range of version numbers. include path Includes a file. The path is relative to the top of the kernel source tree, or the inner-most defined prefix. cinclude path Conditionally includes a file. Contrary to include, it will not produce an error if the file does not exist. The argument obeys the same rules as for include. prefix [path] If path is given, it pushes a new prefix for include and cinclude. prefix statements act like a stack, and an empty path argument has the latest prefix popped out. The path argument is either absolute or rela- tive to the current defined prefix, which defaults to the top of the ker- nel source tree. ifdef attribute ifndef attribute elifdef attribute elifndef attribute else endif Conditionally interprets portions of the current file. Those statements depend on whether or not the given attribute has been previously defined, through define or any other statement that implicitely defines attributes such as device. PREAMBLE In addition to include, cinclude, and prefix, the preamble may contain the following optional statements: build path Defines the build directory for the compilation of the kernel. It replaces the default of ../compile/<config-file> and is superseded by the -b parameter of config(1). source path Defines the directory in which the source of the kernel lives. It replaces the default of ../../../.. and is superseded by the -s parameter of config(1). OPTIONS DESCRIPTION The user will not usually have to use descriptive statements, as they are meant for the developer to tie a given piece of code to the rest of the kernel. However, third parties may provide sources to add to the kernel compilation, and the logic that binds them to the NetBSD kernel will have to be added to the user-edited configuration file. devclass class Defines a special attribute, named device class. A given device cannot belong to more than one device class. config(1) translates that property by the rule that a device cannot depend on more than one device class, and will properly fill the configuration information file it generates according to that value. defflag [file] option [option [...]] [: dependencies] Defines a boolean option, that can either be selected or be un-selected by the user with the options statement. The optional file argument names a header file that will contain the C pre-processor definition for the option. If no file name is given, it will default to opt_<option>.h. config(1) will always create the header file, but if the user choose not to select the option, it will be empty. Several options can be combined in one header file, for convenience. The header file is created in the compilation directory, making them directly accessible by source files. defparam [file] option [= value] [:= lint-value] [option [...]] [: dependencies] Behaves like defflag, except the defined option must have a value. Such options are not typed: they can have either a numeric or a string value. If a value is specified, it is treated as a default, and the option is always defined in the corresponding header file. If a lint-value is specified, config(1) will use it as a value when generating a lint con- figuration with -L, and ignore it in all other cases. deffs name [name [...]] Defines a file-system name. It is no more than a regular option, as defined by defflag, but it allows the user to select the file-systems to be compiled in the kernel with the file-system statement instead of the options statement. obsolete defflag [file] option [option [...]] obsolete defparam [file] option [option [...]] Those two statements are identical and mark the listed option names as obsolete. If the user selects one of the listed options in the kernel configuration file, config(1) will emit a warning and ignore the option. The optional file argument should match the original definition of the option. define attribute [{locators}] [: dependencies] Defines an attribute. The locators list is optional, and can be empty. If the pair of brackets are present, the locator list is defined and the declared attribute becomes an interface attribute, on which devices can attach. maxpartitions number Defines the maximum number of partitions the disklabels for the consid- ered architecture can hold. This statement cannot be repeated and should only appear in the std.${ARCH} file. maxusers min default max Indicates the range of values that will later be accepted by config(1) for the maxusers statement in the options selection part of the configu- ration file. In case the user doesn't include a maxusers statement in the configuration file, the value default is used instead. device base [{locators}] [: dependencies] Declares a device of name base. The optional list of locators, which can also be empty, indicates the device can have children attached directly to it. Internally, that means base becomes an interface attribute. For every device the user selects, config(1) will add the matching CFDRIVER_DECL() statement to ioconf.c. However, it is the responsibility of the developer to add the relevant CFATTACH_DECL() line to the source of the device's driver. attach base at attr [, attr [, ...]] [with name] [: dependencies] All devices must have at least one declared attachment. Otherwise, they will never be found in the autoconf(9) process. The attributes on which an instance of device base can attach must be interface attributes, or root in case the device is at the top-level, which is usually the case of e.g., mainbus(4). The instances of device base will later attach to one interface attribute from the specified list. Different attach definitions must use different names using the with option. It is then possible to use the associated name as a conditional element in a file statement. defpseudo base [: dependencies] Declares a pseudo-device. Those devices don't need an attachment to be declared, they will always be attached if they were selected by the user. defpseudodev base [{locators}] [: dependencies] Declares a pseudo-device. Those devices don't need an attachment to be declared, they will always be attached if they were selected by the user. This declaration should be used if the pseudodevice uses autoconf(9) functions to manage its instances or attach children. As for normal devices, an optional list of locators can be defined, which implies an interface attribute named base, allowing the pseudo-device to have chil- dren. Interface attributes can also be defined in the dependencies list. file path [condition] [needs-count] [needs-flag] [compile with rule] Adds a source file to the list of files to be compiled into the kernel, if the conditions are met. The needs-count option indicates that the source file requires the number of all the countable objects it depends on (through the conditions) to be defined. It is usually used for pseudo-devices whose number can be specified by the user in the pseudo-device statement. Countable objects are devices and pseudo- devices. For the former, the count is the number of declared instances. For the latter, it is the number specified by the user, defaulting to 1. The needs-flag options requires that a flag indicating the selection of an attribute to be created, but the precise number isn't needed. This is useful for source files that only partly depend on the attribute, and thus need to add pre-processor statements for it. needs-count and needs-flag both produce a header file for each of the considered attributes. The name of that file is <attribute>.h. It con- tains one pre-processor definition of NATTRIBUTE set to 0 if the attribute was not selected by the user, or to the number of instances of the device in the needs-count case, or to 1 in all the other cases. The rule argument specifies the make(1) rule that will be used to compile the source file. If it is not given, the default rule for the type of the file will be used. For a given file, there can be more than one file statement, but not from the same configuration source file, and all later statements can only specify a rule argument, and no conditions or flags. This is useful when a file needs special consideration from one particu- lar architecture. object path [condition] Adds an object file to the list of objects to be linked into the kernel, if the conditions are met. This is most useful for third parties provid- ing binary-only components. device-major base [char number] [block number] [condition] Associates a major device number with the device base. A device can be a character device, a block device, or both, and can have different numbers for each. The condition indicates when the relevant line should be added to ioconf.c, and works just like the file statement. makeoptions condition name+=value [, condition name+=value] Appends to a definition in the generated Makefile. OPTIONS SELECTION machine machine [arch [subarch [...]]] The machine statement should appear first in the kernel configuration file, with the exception of context-neutral statements. It makes config(1) include, in that order, the following files: 1. conf/files 2. arch/${ARCH}/conf/files.${ARCH} if defined 3. arch/${SUBARCH}/conf/files.${SUBARCH} for each defined sub- architecture 4. arch/${MACHINE}/conf/files.${MACHINE} It also defines an attribute for the machine, the arch and each of the subarch. package path Simpler version of: prefix PATH include FILE prefix ident string Defines the indentification string of the kernel. This statement is optional, and the name of the main configuration file will be used as a default value. no ident Deletes any pre-existing indentification string of the kernel. maxusers number Despite its name, this statement does not limit the maximum number of users on the system. There is no such limit, actually. However, some kernel structures need to be adjusted to accommodate with more users, and the maxusers parameter is used for example to compute the maximum number of opened files, and the maximum number of processes, which itself is used to adjust a few other parameters. options name [= value] [, name [= value], ...] Selects the option name, affecting it a value if the options requires it (see the defflag and defparam statements). If the option has not been declared in the options description part of the kernel configuration machinery, it will be added as a pre-processor definition when source files are compiled. no options name [, name [, ...]] Un-selects the option name. If option name has not been previously selected, the statement produces an error. file-system name [, name [, ...]] Adds support for all the listed file-systems. no file-system name [, name [, ...]] Removes support for all the listed file-systems. config name root on device [type fs] [dumps on device] Adds name to the list of kernel binaries to compile from the configura- tion file, using the specified root and dump devices information. Any of the device and fs parameters can be wildcarded with ``?'' to let the kernel automatically discover those values. The device can also be specified as a quoted specification string. The kernel interprets this string like the console input when prompting for a root device. E.g. "wedge:NAME" specifies a named disk wedge. At least one config statement must appear in the configuration file. no config name Removes name from the list of kernel binaries to compile from the config- uration file. instance at attachment [locator specification] Configures an instance of a device attaching at a specific location in the device tree. All parameters can be wildcarded, with a ``*'' for instance, and a ``?'' for attachment and the locators. no instance [at attachment] Removes the previously configured instances of a device that exactly match the given specification. If two instances differ only by their locators, both are removed. If no attachment is specified, all matching instances are removed. If instance is a bare device name, all the previously defined instances of that device, regardless of the numbers or wildcard, are removed. no device at attachment Removes all previously configured instances that attach to the specified attachment. If attachment ends with a ``*'', all instances attaching to all the variants of attachment are removed. pseudo-device device [number] Adds support for the specified pseudo-device. The parameter number is passed to the initialisation function of the pseudo-device, usually to indicate how many instances should be created. It defaults to 1, and some pseudo-devices ignore that parameter. no pseudo-device name Removes support for the specified pseudo-device. makeoptions name=value [, name+=value [, ...]] Adds or appends to a definition in the generated Makefile. A definition cannot be overriden, it must be removed before it can be added again. no makeoptions name [, name [, ...]] Removes one or more definitions from the generated Makefile. select name Adds the specified attribute and its dependencies. no select name Removes the specified attribute and all the attributes which depend on it.
FILES
The files are relative to the kernel source top directory (e.g., /usr/src/sys). arch/${MACHINE}/conf/std.${MACHINE} Standard configuration for the given architecture. This file should always be included. arch/${MACHINE}/conf/GENERIC Standard options selection file for the given architecture. Users should always start changing their main kernel configuration file by editing a copy of this file. conf/files Main options description file.
EXAMPLES
config.samples(5) uses several examples to cover all the practical aspects of writing or modifying a kernel configuration file.
SEE ALSO
config(1), options(4), config.samples(5), config(9) NetBSD 7.1.1 October 30, 2014 NetBSD 7.1.1

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