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The information that tells
make how to recompile a system comes from
reading a data base called the makefile.
Makefiles contain five kinds of things: explicit rules, implicit rules, variable definitions, directives, and comments. Rules, variables, and directives are described at length in later chapters.
objectsas a list of all object files (see section Variables Make Makefiles Simpler).
maketo do something special while reading the makefile. These include:
definedirective, and perhaps within commands (where the shell decides what is a comment). A line containing just a comment (with perhaps spaces before it) is effectively blank, and is ignored.
By default, when
make looks for the makefile, it tries the
following names, in order: `GNUmakefile', `makefile'
Normally you should call your makefile either `makefile' or
`Makefile'. (We recommend `Makefile' because it appears
prominently near the beginning of a directory listing, right near other
important files such as `README'.) The first name checked,
`GNUmakefile', is not recommended for most makefiles. You should
use this name if you have a makefile that is specific to GNU
make, and will not be understood by other versions of
make programs look for `makefile' and
`Makefile', but not `GNUmakefile'.
make finds none of these names, it does not use any makefile.
Then you must specify a goal with a command argument, and
will attempt to figure out how to remake it using only its built-in
implicit rules. See section Using Implicit Rules.
If you want to use a nonstandard name for your makefile, you can specify
the makefile name with the `-f' or `--file' option. The
arguments `-f name' or `--file=name' tell
make to read the file name as the makefile. If you use
more than one `-f' or `--file' option, you can specify several
makefiles. All the makefiles are effectively concatenated in the order
specified. The default makefile names `GNUmakefile',
`makefile' and `Makefile' are not checked automatically if you
specify `-f' or `--file'.
include directive tells
make to suspend reading the
current makefile and read one or more other makefiles before continuing.
The directive is a line in the makefile that looks like this:
filenames can contain shell file name patterns.
Extra spaces are allowed and ignored at the beginning of the line, but
a tab is not allowed. (If the line begins with a tab, it will be
considered a command line.) Whitespace is required between
include and the file names, and between file names; extra
whitespace is ignored there and at the end of the directive. A
comment starting with `#' is allowed at the end of the line. If
the file names contain any variable or function references, they are
expanded. See section How to Use Variables.
For example, if you have three `.mk' files, `a.mk',
`b.mk', and `c.mk', and
$(bar) expands to
bish bash, then the following expression
include foo *.mk $(bar)
is equivalent to
include foo a.mk b.mk c.mk bish bash
make processes an
include directive, it suspends
reading of the containing makefile and reads from each listed file in
turn. When that is finished,
make resumes reading the
makefile in which the directive appears.
One occasion for using
include directives is when several programs,
handled by individual makefiles in various directories, need to use a
common set of variable definitions
(see section Setting Variables) or pattern rules
(see section Defining and Redefining Pattern Rules).
Another such occasion is when you want to generate dependencies from
source files automatically; the dependencies can be put in a file that
is included by the main makefile. This practice is generally cleaner
than that of somehow appending the dependencies to the end of the main
makefile as has been traditionally done with other versions of
make. See section Generating Dependencies Automatically.
If the specified name does not start with a slash, and the file is not found in the current directory, several other directories are searched. First, any directories you have specified with the `-I' or `--include-dir' option are searched (see section Summary of Options). Then the following directories (if they exist) are searched, in this order: `prefix/include' (normally `/usr/local/include') `/usr/gnu/include', `/usr/local/include', `/usr/include'.
If an included makefile cannot be found in any of these directories, a
warning message is generated, but it is not an immediately fatal error;
processing of the makefile containing the
Once it has finished reading makefiles,
make will try to remake
any that are out of date or don't exist.
See section How Makefiles Are Remade.
Only after it has tried to find a way to remake a makefile and failed,
make diagnose the missing makefile as a fatal error.
If you want
make to simply ignore a makefile which does not exist
and cannot be remade, with no error message, use the
directive instead of
include, like this:
This is acts like
include in every way except that there is no
error (not even a warning) if any of the filenames do not exist.
If the environment variable
MAKEFILES is defined,
considers its value as a list of names (separated by whitespace) of
additional makefiles to be read before the others. This works much like
include directive: various directories are searched for those
files (see section Including Other Makefiles). In addition, the
default goal is never taken from one of these makefiles and it is not an
error if the files listed in
MAKEFILES are not found.
The main use of
MAKEFILES is in communication between recursive
make (see section Recursive Use of
make}). It usually is not desirable to set the environment
variable before a top-level invocation of
make, because it is
usually better not to mess with a makefile from outside. However, if
you are running
make without a specific makefile, a makefile in
MAKEFILES can do useful things to help the built-in implicit
rules work better, such as defining search paths (see section Searching Directories for Dependencies).
Some users are tempted to set
MAKEFILES in the environment
automatically on login, and program makefiles to expect this to be done.
This is a very bad idea, because such makefiles will fail to work if run by
anyone else. It is much better to write explicit
in the makefiles. See section Including Other Makefiles.
Sometimes makefiles can be remade from other files, such as RCS or SCCS
files. If a makefile can be remade from other files, you probably want
make to get an up-to-date version of the makefile to read in.
To this end, after reading in all makefiles,
make will consider
each as a goal target and attempt to update it. If a makefile has a
rule which says how to update it (found either in that very makefile or
in another one) or if an implicit rule applies to it (see section Using Implicit Rules), it will be updated if necessary. After
all makefiles have been checked, if any have actually been changed,
make starts with a clean slate and reads all the makefiles over
again. (It will also attempt to update each of them over again, but
normally this will not change them again, since they are already up to
If the makefiles specify a double-colon rule to remake a file with
commands but no dependencies, that file will always be remade
(see section Double-Colon Rules). In the case of makefiles, a makefile that has a
double-colon rule with commands but no dependencies will be remade every
make is run, and then again after
make starts over
and reads the makefiles in again. This would cause an infinite loop:
make would constantly remake the makefile, and never do anything
else. So, to avoid this,
make will not attempt to
remake makefiles which are specified as double-colon targets but have no
If you do not specify any makefiles to be read with `-f' or
make will try the default makefile names;
see section What Name to Give Your Makefile. Unlike
makefiles explicitly requested with `-f' or `--file' options,
make is not certain that these makefiles should exist. However,
if a default makefile does not exist but can be created by running
make rules, you probably want the rules to be run so that the
makefile can be used.
Therefore, if none of the default makefiles exists,
make will try
to make each of them in the same order in which they are searched for
(see section What Name to Give Your Makefile)
until it succeeds in making one, or it runs out of names to try. Note
that it is not an error if
make cannot find or make any makefile;
a makefile is not always necessary.
When you use the `-t' or `--touch' option (see section Instead of Executing the Commands), you would not want to use an out-of-date makefile to decide which targets to touch. So the `-t' option has no effect on updating makefiles; they are really updated even if `-t' is specified. Likewise, `-q' (or `--question') and `-n' (or `--just-print') do not prevent updating of makefiles, because an out-of-date makefile would result in the wrong output for other targets. Thus, `make -f mfile -n foo' will update `mfile', read it in, and then print the commands to update `foo' and its dependencies without running them. The commands printed for `foo' will be those specified in the updated contents of `mfile'.
However, on occasion you might actually wish to prevent updating of even the makefiles. You can do this by specifying the makefiles as goals in the command line as well as specifying them as makefiles. When the makefile name is specified explicitly as a goal, the options `-t' and so on do apply to them.
Thus, `make -f mfile -n mfile foo' would read the makefile `mfile', print the commands needed to update it without actually running them, and then print the commands needed to update `foo' without running them. The commands for `foo' will be those specified by the existing contents of `mfile'.
Sometimes it is useful to have a makefile that is mostly just like
another makefile. You can often use the `include' directive to
include one in the other, and add more targets or variable definitions.
However, if the two makefiles give different commands for the same
make will not let you just do this. But there is another way.
In the containing makefile (the one that wants to include the other),
you can use a match-anything pattern rule to say that to remake any
target that cannot be made from the information in the containing
make should look in another makefile.
See section Defining and Redefining Pattern Rules, for more information on pattern rules.
For example, if you have a makefile called `Makefile' that says how to make the target `foo' (and other targets), you can write a makefile called `GNUmakefile' that contains:
foo: frobnicate > foo %: force @$(MAKE) -f Makefile $@ force: ;
If you say `make foo',
make will find `GNUmakefile',
read it, and see that to make `foo', it needs to run the command
`frobnicate > foo'. If you say `make bar',
find no way to make `bar' in `GNUmakefile', so it will use the
commands from the pattern rule: `make -f Makefile bar'. If
`Makefile' provides a rule for updating `bar',
will apply the rule. And likewise for any other target that
`GNUmakefile' does not say how to make.
The way this works is that the pattern rule has a pattern of just
`%', so it matches any target whatever. The rule specifies a
dependency `force', to guarantee that the commands will be run even
if the target file already exists. We give `force' target empty
commands to prevent
make from searching for an implicit rule to
build it--otherwise it would apply the same match-anything rule to
`force' itself and create a dependency loop!
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