=head1 NAME

makepp_functions -- Functions in makepp

=for vc $Id: makepp_functions.pod,v 1.52 2016/09/06 19:59:45 pfeiffer Exp $

=head1 DESCRIPTION

=for genindex '\w+' makepp_functions.pod

B<A:>E<nbsp>L<absolute_filename|/absolute_filename_files>,
  L<absolute_filename_nolink|/absolute_filename_nolink_files>,
  L<abspath|/absolute_filename_files>,
  L<addprefix|/addprefix_prefix_words>,
  L<addsuffix|/addsuffix_suffix_words>,
  L<and|/and_condition1_condition2_condition3>,E<nbsp>
B<B:>E<nbsp>L<basename|/basename_filenames>,E<nbsp>
B<C:>E<nbsp>L<call|/call_variable_words>,E<nbsp>
B<D:>E<nbsp>L<dir|/dir_filenames>,
  L<dir_noslash|/dir_noslash_filename>,E<nbsp>
B<E:>E<nbsp>L<error|/info_text>,E<nbsp>
B<F:>E<nbsp>L<filesubst|/filesubst_pattern_substitute_words>,
  L<filter|/filter_patterns_words>,
  L<filter_out|/filter_out_patterns_words>,
  L<filter_out_dirs|/filter_out_dirs_filenames>,
  L<findfile|/findfile_filename_path>,
  L<find_first_upwards|/find_first_upwards_file1_file2>,
  L<find_program|/find_program_name>,
  L<findstring|/findstring_find_in>,
  L<find_upwards|/find_upwards_filename>,
  L<first_available|/first_available_file1_file2>,
  L<firstword|/firstword_words>,
  L<foreach|/foreach_var_list_text>,E<nbsp>
B<I:>E<nbsp>L<if|/if_string_result_if_string_not_blank_result_if_string_blank>,
  L<iftrue|/if_string_result_if_string_not_blank_result_if_string_blank>,
  L<infer_linker|/infer_linker_file1_file2>,
  L<infer_objects|/infer_objects_file1_file2_pattern>,
  L<info|/info_text>,E<nbsp>
B<J:>E<nbsp>L<join|/join_words1_words2>,E<nbsp>
B<M:>E<nbsp>L<make|/prebuild_targets>,
  L<makemap|/map_words_perlcode>,
  L<makeperl|/perl_perlcode>,
  L<map|/map_words_perlcode>,
  L</mktemp>,E<nbsp>
B<N:>E<nbsp>L<notdir|/notdir_filenames>,E<nbsp>
B<O:>E<nbsp>L<only_generated|/only_generated_filenames>,
  L<only_nontargets|/only_nontargets_filenames>,
  L<only_phony_targets|/only_phony_targets_names>,
  L<only_stale|/only_stale_filenames>,
  L<only_targets|/only_targets_filenames>,
  L<or|/or_condition1_condition2_condition3>,
  L<origin|/origin_variable>,E<nbsp>
B<P:>E<nbsp>L<patsubst|/patsubst_pattern_substitute_words>,
  L<perl|/perl_perlcode>,
  L<phony|/phony_words>,
  L<prebuild|/prebuild_targets>,
  L<print|/print_text>,E<nbsp>
B<R:>E<nbsp>L<realpath|/absolute_filename_nolink_files>,
  L<relative_filename|/relative_filename_file1_file2_file3_slash>,
  L<relative_to|/relative_to_file1_file2_file3_directory>,E<nbsp>
B<S:>E<nbsp>L<shell|/shell_shell_command>,
  L<sort|/sort_word1_word2_word3>,
  L<strip|/strip_string>,
  L<subst|/subst_from_to_text>,
  L<suffix|/suffix_names>,E<nbsp>
B<T:>E<nbsp>L<temporary|/temporary_words>,E<nbsp>
B<W:>E<nbsp>L<warning|/info_text>,
  L<wildcard|/wildcard_pattern>,
  L<word|/word_n_text>,
  L<wordlist|/wordlist_indexlist_words>,
  L<words|/words_text>,E<nbsp>
B<X:>E<nbsp>L<xargs|/xargs_command_arguments_suffix_length>

Any expression of the format C<$(name)>, where C<name> is not the name of a
variable, or S<C<$(name arg1 arg2 arg3)>> is interpreted as a function call.
The name may contain letters, underscores, or hyphens; to avoid confusion, you
may use hyphens or underscores interchangeably, since internally hyphens are
converted to underscores.  Evaluating such an expression simply invokes a Perl
subroutine.  If C<name> is preceded by C<&> it runs the L<builtin
command|makepp_builtins> or script of that name within the makepp process, and
returns the standard output.  This requires perl to be built for PerlIO.  If
the name does not name a function it is transformed to an invocation of
L<call|/call_variable_words>.

As with variables you have a choice of C<$(name ...)> or C<${name ...}>.  If
you want to embed the same parenthesis, it must be paired, the other doesn't
matter: C<$(name ...(){...)> or C<${name ...{}(...}>.  (However for
L<map|/map_words_perlcode> and L<perl|/perl_perlcode> the first closing paren
ends the expression.)  Doubling allows the arguments to span several lines.
The newlines are then treated as spaces, except maybe in C<define>.  There is
also the syntax C<$[name ...]> or C<$[[name ...]]>, which gets evaluated while
reading the makefile, before grokking rules and other constructs.

Makepp has a number of builtin functions which may be useful.  It supports
almost all of GNU make's textual functions (see GNU make's documentation for
details), and some of its own.  You can define Perl subroutines to do whatever
you like.  See the C<sub> statement and the section on L<extending
makepp|makepp_extending> for more details.

=head2 Conditional Functions

=over 4

=item and I<condition1[,condition2[,condition3...]]>

The and function provides a “short-circuiting” AND operation. Each argument is
expanded, in order. If an argument expands to an empty string the processing
stops and the result of the expansion is the empty string. If all arguments
expand to a non-empty string then the result of the expansion is the expansion
of the last argument.

=item if I<string, result-if-string-not-blank[, result-if-string-blank]>

=item iftrue I<string, result-if-string-true[, result-if-string-false]>

An alternative to the C<ifeq>, etc., statements.  If the string is not blank
(i.e., the condition is true), the second argument (the "then" clause) is
returned (after variable expansion); if the string is blank, the third
argument (the "else" clause) is returned.

For example,

    CFLAGS := $(if $(filter gcc egcc, $(CC)), -g -Wall, -g)

defines CFLAGS to be C<-g -Wall> if the variable CC is either C<gcc> or
C<egcc>, and C<-g> otherwise.  (This is what the default build rules do.)

C<iftrue> is similar to C<if>, except that the string C<0> is treated as
blank.

=item or I<condition1[,condition2[,condition3...]]>

The or function provides a “short-circuiting” OR operation. Each argument is
expanded, in order. If an argument expands to a non-empty string the
processing stops and the result of the expansion is that string. If, after all
arguments are expanded, all of them are false (empty), then the result of the
expansion is the empty string.

=back


=head2 File and Filename Functions

=over 4

=item absolute_filename I<files>

=item abspath I<files>

Converts relative filenames into absolutes without F<.> or F<..>.  For
example, S<C<$(absolute_filename xyz.c)>> might return
C</usr/src/our_project/subdir/xyz.c>.

=item absolute_filename_nolink I<files>

=item realpath I<files>

Like L<absolute_filename|/absolute_filename_files>, but ensures that symbolic links
are resolved.

=item basename I<filenames>

The basename is the entire file name (with the directory), minus the text
after and including the last period.  E.g., S<C<$(basename
myfile/version-1.0-module.c)>> is C<myfile/version-1.0-module>

=item dir I<filenames>

Extracts the directory part of each file in the filename list, including the
trailing slash.  Returns C<./> if there is no directory in the filename.

=item dir_noslash I<filename>

Same as S<C<$(dir )>> except that it doesn't return the trailing slash.

=item filesubst I<pattern, substitute, words>

Perform a pattern substitution on file names.	 This differs from patsubst
in that it will perform correctly when alternate names for directories are
given (as long as they precede the percent sign).  For example,

    $(filesubst ./src/%.c, %.o, $(wildcard src/*.c))

will work with filesubst but not with patsubst.

=item filter_out_dirs I<filenames>

Returns all filenames that do not refer to directories.

=item findfile I<filename, path>

Finds a file in the specified path, or in the environment variable PATH
if nothing is specified.  This can be useful for finding binaries or
include files.  For example,

    TCL_INCLUDE := -I$(dir_noslash $(findfile tcl.h, \
 	/usr/local/stow/tcl-8.4.5-nothread/include \
 	/usr/include/tcl8.4 /usr/include/tcl \
 	/net/na1/tcl8.4a3/include /net/na1/tcl8.4a3/include))

This locates the file F<tcl.h> by searching all of the above
directories.  The absolute path to the file is returned.  Then
S<C<$(dir_noslash )>> extracts that directory, and it is put into the
include path.

=item find_program I<name>

Return the first program in the list that can be found in the PATH.
This is useful when there are multiple equivalent programs that may be
used, and you just want to pick one of them.  For example, here is the
default definition of several common variables that makepp supplies if
you do not put one in your makefile:

    CC = $(find_program gcc egcc pgcc c89 cc) # and more, depending on machine
    F77 = $(find_program f77 g77 fort77)
    CXX = $(find_program g++ c++ pg++ cxx CC aCC)

If none of the programs is found, S<C<$(find_program )>> returns the string
not-found, and logs what was not found.  This usually won't result in a
functional makefile, but it will tend to make for better error messages.  For
example, if you do something like this:

    %.o : %.c
 	$(CC) $(inputs) -o $(outputs)

and makepp can't find a C compiler in the list above, it will substitute
not-found.  Otherwise the shell would attempt to execute the source file and
the resulting error message might be really strange.

=item find_upwards I<filename>

Searches for a file of the given name in the directory ., .., ../..,
../../.., etc., until the file is found or the root directory is reached
or the directory is located on a different file system.  (This last
requirement is to prevent problems with automounters or hung network
filesystems.)  If you have a F<RootMakeppfile>, that is also a barrier which
prevents searching higher.

For example, if you have a project with many levels of subdirectories, you
could include this common fragment in all of the makefiles (e.g., by using the
C<include> statement):

    TOP_LEVEL_INCLUDE_DIR := $(find_upwards includes)
 				# Searches for a directory that contains the
 				# includes subdirectory.

    %.o : %.c
 	$(CC) $(CFLAGS) -I$(TOP_LEVEL_INCLUDE_DIR) -c $(input) -o $(output)

Another problem that C<find_upwards> can help solve is locating the
top-level directory of a build.  Often it is useful to define a variable
like this:

    TOP := ../../..

if you have some important information located only in the top-level
directory.  But this is hard to maintain, because the number of C<..> is
different for different levels of the directory tree.  Instead, you can
use C<find_upwards> to locate a file which is known to be present only
in the top level directory.  Suppose, for example, that the file
C<LICENSE> is located only in the top level directory.  Then
you could do this:

    TOP := $(dir_noslash $(find_upwards LICENSE))

S<C<$(find_upwards LICENSE)>> returns the full path of the license file;
S<C<$(dir_noslash ...)>> strips off the filename, returning only the directory.

(Note that the C<include> statement automatically searches upwards for files,
so there is no need to do something like this:

    include $(find_upwards top_level_rules.mk)

Instead, you can just do

    include top_level_rules.mk

and it will work just as well.)

If the file is not found, C<find_upwards> will abort the build with an
error message.

If you specify more than one file, find_upwards will search for the
first one, then the second one, and so on.  In other words,

    $(find_upwards file1 file2)

is equivalent to

    $(find_upwards file1) $(find_upwards file2)

If you want to look for any one of the files, then use
C<find_first_upwards> instead.

=item find_first_upwards I<file1 file2 ...>

This function behaves like C<find_upwards> except that it returns the
first file of any files in the list that it finds.  Specifically,
it checks the current directory for any of the files in the list, and
returns the first file which exists or can be built.  If none of the
files exist or can be built in that directory, it checks F<..>, then
F<../..>, etc., until it reaches either the root directory or a
directory which is located on a different file system.

=item first_available I<file1 file2 ...>

Return the first file in a list that exists or can be built.  This can
be useful for adapting your makefiles to work on several different
machines or networks, where important files may be located in different
places.  For example, here's a line from one of my makefiles:

    TCL_LIB = $(first_available \
 	/usr/local/stow/tcl-8.4.5-nothread/lib/libtcl8.4.so \
 	/usr/lib/libtcl8.4.so /usr/lib/libtcl.so \
 	/net/na1/tcl8.4a3/lib/libtcl8.4.a \
 	/net/na1/tcl8.4a3/lib/libtcl8.4.sl)

This line will check for the Tcl library in all of the above places,
stopping at the first one that it finds.  The link command then includes
$(TCL_LIB) so we get the appropriate Tcl library.

=item infer_linker I<file1 file2 ...>

Given a list of object files first build them if they have not been yet.  Then
find whether they depend on a Fortran, C++ or a C source and return the
corresponding compiler (which better knows how to link than C<ld>).

=item infer_objects I<file1 file2 ..., pattern>

    $(infer_objects object1.o object2.o, *.o)

If you use standard conventions regarding header file names, makepp is capable
of guessing which C<.o> or C<.lo> files need to be linked with your program.
I use this to pick out files from a library directory which contains modules
used in many different programs.  Instead of making a library C<.a> file and
having the linker pick out the relevant modules, makepp can pick out the
relevant modules for you.  This way, only the relevant modules get compiled.

Makepp's algorithm for inferring object dependencies depends on the convention
that the implementation of all classes or functions defined in a header file
C<xyz.h> are compiled into an object file called C<xyz.o> (or C<xyz.lo>).  So
makepp's algorithm for inferring object dependencies starts with one or a few
objects that we know have to be linked into the program.  It looks at which
files were included with C<#include> in those sources (building those sources
if need be), and tries to find corresponding object files for each of the
include files.

S<C<$(infer_objects )>> needs to be mentioned in the dependency list of a
program, like this:

    myprog: $(infer_objects main.o another_object.o, \
 		**/*.o /other/library/dirs/**/*.o)
 	$(CXX) $(inputs) -o $(output) $(LIBS)

The L<C<$(infer_objects)>|makepp_functions/infer_objects_file1_file2_pattern>
function takes two arguments (separated by a comma, as shown).  The first is
one or a few object files that are known to be required (wildcards are
permissible here).  The second is a list of possible objects (normally you
would use a wildcard here) that could be linked in if necessary.  The return
value from this function is a list that contains first all of the objects in
the first argument, and then after those, all additional objects that were
contained in the second argument that are required by the objects in the first
argument.

For example, suppose C<main.o> comes from C<main.cpp>, which includes
C<my_class.h>.
L<C<$(infer_objects)>|makepp_functions/infer_objects_file1_file2_pattern>
looks for files with the name C<my_class.o>.  If exactly one such file is
found, it is added to the list.  (If two object files C<my_class.o> are found
in different directories, a warning message is printed.)  C<infer_objects>
also examines C<my_class.cpp> to see what it includes, and what additional
object files are implied.

=item mktemp

=item mktemp I<prefix>

=item mktemp I<prefix>XXX

=item mktemp /

Returns an unpredictable temporary filename, which does not currently exist.
No name pointing to the same file is returned twice, even with different
relative paths, within one makepp run (except possibly with traditional
recursive make, or if Perl code running within a rule action calls
C<f_mktemp>).  At the end of the makepp run all files returned by this
function are deleted, if they exist (again except for those returned by this
function in Perl code running within a rule).

Any number of upper case C<X>s at the end of the argument are replaced by that
many random letters and digits.  The more there are, the less likely this is
to collide with other processes, so if you give a prefix like "F</tmp/abc.>",
you should have enough C<X>s.  If there is more than one X, the first
character comes from the process id.  If there are none, it is as though there
were ten, which is supposedly enough (8.4e17 possibilities or 3.7e15 on
Windows).  If there is no argument, the prefix defaults to "F<tmp.>" in the
current directory.

Note that you don't want to give such a name as rule targets and dependencies.
The result would be correct, but it would be recreated every time you run
makepp.

=begin comment
  The C<temporary> function may do what you want in this case:

    TMPFILE ;= $(temporary $(mktemp))	# 1 call; "=" would mean 3 calls: 3 files
    A-count: $(TMPFILE)
 	&grep -c /A/ $(input) -o $(output)

    B-count: $(TMPFILE)
 	&grep -c /B/ $(input) -o $(output)

    $(TMPFILE):
 	produce-As-and-Bs >$(output)

=end comment

Also, as it is always different, you should use this in a rule action only if
you use C<:build_check ignore_action>:

    TMPFILE ;= $(mktemp)	# 1 call; "=" would mean 3 calls: 3 files
    A-count B-count: :build_check ignore_action
 	produce-As-and-Bs >$(TMPFILE)
 	&grep -c /A/ $(TMPFILE) -o A-count
 	&grep -c /B/ $(TMPFILE) -o B-count

Or you should export it and let the Shell evaluate it:

    export TMPFILE ;= $(mktemp)
    A-count B-count:
 	produce-As-and-Bs >$$TMPFILE # makepp doesn't see the var value
 	fgrep -c A $$TMPFILE >A-count
 	fgrep -c B $$TMPFILE >B-count

The last form repeats the previous return value, so you can use it in a
pattern rule:

    %.x: %.y
 	&grep foo $(input) -o $(mktemp)
 	&sed bar $(mktemp /) -o $(output) # Operate on the output of &grep

=item notdir I<filenames>

Returns the non-directory portion of the filename(s), i.e., everything after
the last slash if there is one, or the whole filename otherwise.

=item only_generated I<filenames>

Returns only those filenames in the list that were generated by makepp
and not since modified, according to the build info file.

This function is useful in clean target rules (though of course C<makeppclean>
is the preferred variant):

    $(phony clean):
 	&rm -f $(only_generated **/*)

=item only_nontargets I<filenames>

Returns only those filenames in the list that are not targets of any
rule (either explicit or pattern rules).  You may specify a wildcard
(see the S<C<$(wildcard )>> function for more details on makepp's
wildcards).  This can be used for generating a distribution target, for
example:

    .PHONY: distribution

    distribution:
 	&mkdir our_product-$(VERSION)
 	&cp $(filter-out %~, $(only_nontargets *)) our_product-$(VERSION)
 	tar cf - our_product-$(VERSION) | gzip -9c > our_product-$(VERSION).tar.gz


In this case, the C<$(only_nontargets *)> returns every file in the current
directory that is not a target of some rule.  The C<$(filter_out %~, ...)>
removes editor backups.

Similar to C<only_targets> (see above), C<only_nontargets> only knows about
targets that have been defined already.  This is only a problem if you use it
to define variables with the C<:=> assignment; if you use it in the
dependency list or in the body of a rule, all other rules will already
have been seen.

=item only_stale I<filenames>

Returns only those filenames in the list that were generated by makepp
and not since modified, according to the build info file, but are no longer
targets of any rule.

This function is useful for ensuring that there are no dependencies on such
files, without forcing a clean build of all of the targets:

    $(phony flush):
 	&rm -f $(only_stale **/*)

Actually, it's probably better instead to write a script that calls makepp
to generate the list of stale files, and then have that script remove all of
the listed files that aren't currently under source control, just in case a
generated file becomes a source file. Makepp doesn't have such a function
built in because makepp is (and probably ought to remain) agnostic about
source control.

=item only_targets I<filenames>

Returns only those filenames in the list that are actually targets of
some rule (either explicit or pattern rules).  You may specify wildcards
(including makepp's special wildcard, C<**>) in the filenames.  (See the
S<C<$(wildcard )>> function for more details.  This can be used for a
clean target, for example:

    .PHONY: clean

    clean:
 	&rm -f $(only_targets *)

Now if you type S<C<makepp clean>>, it will delete everything it knows how to
build.  But don't create a clean target, use C<makeppclean> instead!

Another place where it may be useful is to avoid including stale F<.o> files
in your build.  For example, if you build a library like this:

    mylib.a: *.o
 	&rm -f $(output)
 	$(AR) cr $(output) $(inputs)

and then you delete some source files but forget to delete the corresponding
F<.o> files, the F<.o> files will still be around.  This means they will still
be incorporated into the library despite the fact that they are not useful any
more.  If you modify your rule like this:

    mylib.a: $(only_targets *.o)
 	&rm -f $(output)
 	$(AR) cr $(output) $(inputs)

then this problem won't occur.

Note that this refers only to files that are known to be targets I<at
the time you invoke> C<only-targets>.  If C<only_targets> appears in the
dependencies or actions of a rule, then all possible targets will be
known because dependencies and actions are not evaluated until the rule
is executed.  However, if you evaluate try to evaluate it earlier in the
makefile with a C<:=> variable like this:

    ALL_TARGETS := $(only_targets *)

    target1: dependency1
 	actions

    target2: dependency2
 	actions

then C<only_targets> will not know about the subsequent rules.

Similarly, C<only_targets> doesn't know about targets produced in
makefiles that are loaded with recursive make.  (But you shouldn't be
using recursive make anyway; use use the C<load_makefile> statement, or
L<implicit makefile loading|makepp_build_algorithm/Implicit loading>
instead.)

=item relative_filename I<file1 file2 file3[, slash]>

Returns the name of those files relative to the current directory (the one the
makefile is in).  This can also be used to clean unnecessary C<./> and other
junk from the path:

    DIR := .
    SUBDIR := ..
    FNAME := $(DIR)/../otherdir/$(SUBDIR)/files
    X := $(relative_filename $(FNAME))

If I<slash> is true (usually C<1>) the returned filenames are guaranteed to
contain a slash by prepending C<./> if necessary, so that you can use it as an
executable name without worrying about the command search path overriding the
directory location.

If the path goes by the root directory, the parent of either your home
directory or the C<$(ROOT)> of your build system, or on Windows a drive's root
(depending on the environment, this also happens for F</cygdrive/c> or F</c>),
an absolute path will be returned instead.

=item relative_to I<file1 file2 file3[, directory]>

Returns the name of those files relative to the specified directory.  This is
typically useful when for whatever reason you have to execute a command from a
different directory (default current directory):

    source_backup.tar:
 	cd .. && tar cf $(relative_to $(output), ..) $(relative_to ., ..)

=item suffix I<names...>

Extracts the suffix of each file name in names. If the file name contains a
period, the suffix is everything starting with the last period. Otherwise, the
suffix is the empty string. This frequently means that the result will be
empty when names is not, and if names contains multiple file names, the result
may contain fewer file names.

For example,

    $(suffix src/foo.c src-1.0/bar.c hacks)

produces the result C<.c .c>.

=item temporary I<words>

Let makepp know that the specified targets may be removed by the rule
that generates them.
Similar to C<phony>, except that makepp expects that a real file of that
name will may be affected by the rule.
A rule is not executed if only its temporary targets are out-of-date.

=item wildcard I<pattern>

Returns the sorted names of all files matching the given pattern which exist,
or those files which do not yet exist but can be built based on the rules that
makepp knows about at the point when it evaluates the expression.  In this
last point it differs from L<rule input wildcards|makepp_rules/Wildcards>,
which apply even to files created by rules found later.

Makepp supports all the usual shell wildcards (C<*>, C<?>, and C<[]>).  It
also has a wildcard C<**> which matches any number of intervening directories.
(This idea was stolen from zsh.)  For example, C<**/*.c> matches all the F<.c>
files in the entire source tree.  C<objects/**/*.o> matches all the F<.o>
files contained anywhere in the subdirectory F<objects> or any of its
subdirectories or any of their subdirectories.  The C<**> wildcard will not
follow soft links to directories at any level, nor will it attempt to enter
directories which exist but cannot be read.  Also files and directories which
exist but cannot be read will not be returned by S<C<$(wildcard )>>.

=back

=head2 String Functions

=over 4

=item addprefix I<prefix, words>

Prepends the prefix string to each of the words.  This is mostly for GNU make
compatibility; using rc-style expansion, this can be done in a more readable
fashion like this:

    MODULES := a b c d
    X_OLD_STYLE := $(addprefix $(OBJDIR)/, $(addsuffix .o, $(MODULES)))
    X_NEW_STYLE := $(OBJDIR)/$(MODULES).o   # Isn't that easier to read?

=item addsuffix I<suffix, words>

Appends the suffix string to each of the words.  This is mostly for GNU make
compatibility; using rc-style expansion, this can be done in a more readable
fashion like this:

    X_OLD_STYLE := $(addsuffix .o, $(MODULES))
    X_NEW_STYLE := $(MODULES).o

=item call I<variable[, words]... X<call>>

The function C<call> is unique in that it can be used to regard I<variable> as
a parameterized function.  You can assign a complex expression to I<variable>
and use C<call> to expand its contents to different values parametrized by
I<words> later on.  In other make systems, a variable that is used mainly for
the purpose to be expanded via C<call>, is called a B<macro>.

During expansion of the macro, the temporary variables B<C<$1>>, B<C<$2>>,
B<C<...>> refer to the arguments given to C<call> during its invocation.  The
variable B<C<$0>> will be expanded to the name of the macro (i.e. I<variable>)
that C<call> is currently expanding.

There is no limit, how many arguments a macro may be C<call>ed with or how many
parameters a macro may expect.  If you pass more arguments to C<call> as the
macro need, all exceeding arguments will be discarded.  If you pass less
arguments than a macro expect, all exceeding parameters collapse into the empty
string.

First a simple example:

    rest = $(wordlist 2, $(words $(1)),$(1))
    list = A B C D E
    butfirst := $(call rest,$(list))

Here, the variable C<$(butfirst)> will contain the list S<C<B C D E>>.

And now for a more complex example to show what is possible:

    rest = $(wordlist 2,$(words $(1)),${1})
    mymap = $(if $2,$(call $1,$(firstword $2)) $(call $0,$1,$(call rest,$2)))
    downcase = ${makeperl lc("$1")}

    UCWORDS = ALL THESE WORDS ARE UPCASE
    DCWORDS := $(call mymap,downcase,$(UCWORDS))

Now C<$(DCWORDS)> contains S<C<all these words are upcase>>.  By the way: it
makes no difference, whether we access the arguments via B<C<$1>>, B<C<${1}>>
or B<C<$(1)>> within a macro.

You can directly use the variable as though it were a function, if there is no
function of that name.  This is internally converted to C<call>, so these are
equivalent:

    discussion = The $0 turned into $1 $2.
    direct = $(discussion an,argument)
    called = $(call discussion,an,argument)

It might seem debatable whether C<$[call]> should also expand the macro's
C<$[]> expressions, or whether a function should always do the same thing, no
matter how it is called.  The latter was chosen, because with normal make
syntax it would be impossible to get C<$[1], $[2]...> into a variable (they'd
get replaced by nothing, before the assignment even takes place.)  Hence, if
you have a macro for defining a rule, you want expressions like C<$(output)>
to be seen when the rule gets parsed, so you must protect them from C<call>:

    define myrule
 	$2: $1
 	    mycommand $$(input) -o $$(output)
    endef
    $[myrule myinput,myoutput]

=item filter I<patterns, words>

Returns all words in the list that match the patterns.  Patterns may simply be
other words, or filename wildcards (i.e., C<*>, C<?>, and C<[a-z]> are
recognized), or they may have a C<%> character, which means to match any
string at that point (same as C<*>).

=item filter_out I<patterns, words>

Returns all words in the list that do not match the patterns.  Patterns may
simply be other words, or filename wildcards (i.e., C<*>, C<?>, and C<[a-z]>
are recognized), or they may have a C<%> character, which means to match any
string at that point (same as C<*>).

For example:

    libproduction.a: $(filter_out test_*, $(wildcard *.o))

will put all F<.o> files which exist or can be built, except those beginning
with F<test_>, into F<libproduction.a>.

=item findstring I<find, in>

Return I<find>, if it is a substring of I<in>.

=item firstword I<words>

Return the first word.

=item map I<words, perlcode>

=item makemap I<words, perlcode>

Similarly to Perl's map, applies I<perlcode> to each word in turn and returns
the results.  The first variant is plain Perl code, while the second variant
first passes the perlcode through Make-style variable expansion.  The words
are expanded in both cases.

The words are in C<$_> and are returned unless you undef C<$_>.  This is
intended for modifications not easily handled by C<patsubst>.  Only the first
comma is a separator, any others are considered part of the I<perlcode>.

    # Switch words.  Double parens, to allow parens in perlcode, or use ${}:
    X = $((map $(VALUES), s/(.+)-(.+)/$2-$1/))
    # You can use make expressions, but then you must use $$ for Perl $:
    Y = $(makemap $(VALUES), tr/$(OLDCHARS)/$(NEWCHARS)/ or $$_ = 'failed')
    # You can eliminate candidates:
    Y = $(map $(VALUES), undef $_ if /no_good/)

=item join I<words1, words2>

Do a pairwise join of the first words and the second words.

=item patsubst I<pattern, substitute, words>

Performs a substitution on each word in the word list.  A
C<%> character matches any string.  This is best
illustrated by an example:

    OBJS = $(patsubst %.c, object_dir/%.o, $(C_SOURCES))

takes every file in C_SOURCES and returns the name of an object
file in object_dir.  Sometimes it is more concise to use a
L<substitution reference|makepp_variables/Substitution References>, e.g.,
the above could have been written as

    OBJS = $(C_SOURCES:%.c=object_dir/%.o)

=item sort I<word1 word2 word3 ...>

Sorts the words in lexical order and removes duplicates.

=item strip I<string>

Removes leading and trailing whitespace from string and replaces each internal
sequence of one or more whitespace characters with a single space. Thus,
C<$(strip  a b  c )> results in C<a b c>.

=item subst I<from,to,text>

Performs a textual replacement on the text text: each occurrence of from is
replaced by to. The result is substituted for the function call. For example,

    $(subst ee,EE,feet on the street)

substitutes the string C<fEEt on the strEEt>.

=item word I<n,text>

Returns the I<n>th word of I<text>. The legitimate values of I<n> start from 1
at the beginning or backwards from -1 at the end. If I<n> is bigger than the
number of words in I<text>, the value is empty.

=item wordlist I<indexlist, words>

=item wordlist I<firstindex, lastindex, words>

In the first form you supply a list of indices (counting from 1 at the
beginning or backwards from -1 at the end) to select the words you want.  In
the second form you specify the range of words you want returned.

=item words I<text>

Returns the number of words in I<text>.

=back

=head2 Miscellaneous Functions

=over 4

=item foreach I<var,list,text>

The first two arguments, I<var> and I<list>, are expanded before anything else
is done; note that the last argument, text, is not expanded at the same
time. Then for each word of the expanded value of list, the variable named by
the expanded value of var is set to that word, and text is
expanded. Presumably text contains references to that variable, so its
expansion will be different each time.

This simple example sets the variable I<files> to the list of all files in the
directories in the list I<dirs>:

    dirs := a b c d
    files := $(foreach dir,$(dirs),$(wildcard $(dir)/*))

Here text is C<$(wildcard $(dir)/*)>. The first repetition finds the value C<a>
for dir, so it produces the same result as C<$(wildcard a/*)>; the second
repetition produces the result of C<$(wildcard b/*)>; and the third, that of
C<$(wildcard c/*)>.

This example has the same result (except for setting C<dirs>) as the following example:

    files := $(wildcard a/* b/* c/* d/*)

When text is complicated, you can improve readability by giving it a name, with an additional variable:

    find_files = $(wildcard $(dir)/*)
    dirs := a b c d
    files := $(foreach dir,$(dirs),$(find_files))

Here we use the variable find_files this way. We use plain C<=> to define a
recursively-expanding variable, so that its value contains an actual function
call to be reexpanded under the control of foreach; a simply-expanded variable
would not do, since wildcard would be called only once at the time of defining
find_files.

Note: Don't confuse this with the C<$(foreach)> special variable.

=item info I<text>

=item warning I<text>

=item error I<text>

Output text returning the nothing.  The first goes to STDOUT, the second to
STDERR, the third additionally aborts processing.

=item prebuild I<targets>

=item make I<targets>

Returns its argument verbatim, but first builds all the files listed.
This is useful when a given file is needed when evaluating a make
expression.  This typically happens when you have a build where the set
of files involved is computed by some shell commands.  For example,

    file_list :
 	# shell commands to compute a list of files to put into the program

    my_program : $(&cat $(prebuild file_list))

If you need the list in more than one rule, it would be more efficient to use
an expand at most once variable:

    file_list ;= $(&cat $(prebuild file_list))

    my_program1 : a.o $(file_list)

    my_program2 : b.o $(file_list)

If instead you specified just S<C<$(&cat file_list)>>, then makepp would not
force file_list to be up-to-date before it executes the shell command.  Using
S<C<$(prebuild )>> is the best way to solve this problem.  You might be
tempted to try other things, like this:

    my_program : file_list $(&cat file_list)

but this won't work because S<C<$(&cat file_list)>> is evaluated
before makepp attempts to build C<file_list>.

=item only_phony_targets I<names>

Returns only those names in the list that are phony targets of
some rule (either explicit or pattern rules).  You may specify wildcards
(including makepp's special wildcard, C<**>) in the filenames.  (See the
S<C<$(wildcard )>> function for more details.  This can be used for grouping
targets, for example:

    $(phony tests): $(only_phony_targets */**/tests)

=item origin I<variable>

Given the name of a variable, tells you where its value comes from.

=item perl I<perlcode>

=item makeperl I<perlcode>

Evaluates perlcode in a block and returns the result.  The first
variant is plain Perl code, while the second variant first passes the
perlcode through Make-style variable expansion.

Note, that, as with all functions, the function delimiter used may not appear
within the perlcode outside of single or double quoted strings.  But you can
double it as in the last example:

    VAR = 1
    VAR1 = ${perl ($VAR + 1) * 3}
    VAR2 = $(perl do { $VAR *= 3; return $VAR + 1 } if $VAR)
    VAR3 = $(makeperl $(VAR1) * 3 + $$VAR) # one Make var and one Perl var
    VAR = $((perl if( ... ) { ... }))

=item phony I<words>

Indicates that the list of words are actually phony targets, and
returns the list of targets.  It's intended to be used like
this:

    $(phony all): my_program

    $(phony clean):
 	&rm -f *.o my_program

You can also declare one or more targets as phony with a line like
this anywhere in your makefile:

    .PHONY: all clean

=item print I<text>

Outputs the text and returns it.  This is mostly useful for
debugging, when you don't understand why variable substitution
has the result that it does.  For example,

    XYZ := $(print $(patsubst %.c, %o, $(SOURCE_FILES)))

will print out the result of the C<patsubst> call.

    XYZ := $(patsubst %.c, %o, $(print $(SOURCE_FILES)))

will print out the last argument to the C<patsubst>
call.

=item shell I<shell-command>

Returns the output from the given shell command, with newlines
replaced by spaces.

Note, that, as with all functions, the function delimiter used may not appear
within the shell-command outside of single or double quoted strings.  But you can
double it as in the second example:

    date = $(shell date)	# better: $(perl scalar localtime)
    VAR = ${{shell f() { echo hello; }; f}}

=item xargs I<command,arguments[,suffix[,length]]>

Returns a newline-separated list of commands that each begin with the
specified command, and end with as many elements of the list as possible
without going over I<length> (default 1000) characters.

The purpose of this is to avoid spilling over the command length limit on your
system.  For example, if there are a lot of generated files, then you would
probably want your clean target (which you should not have, because
C<makeppclean> is more efficient) to look something like this:

    $(phony clean):
 	$(xargs $(RM), $(only_targets **/*))

This also has the side-effect that no command whatsoever is generated if the
list happens to be empty.  But in this case it would be better to use the
builtin C<&rm>, because the arguments to the builtin commands are only limited
by Perl's memory:

    $(phony clean):
 	&rm -f $(only_targets **/*)

If a third argument is specified, then it is used to postfix each command.
This is useful for specifying redirectors, e.g. (though here again C<&echo>
would help):

    manifest:
 	&rm -f $@
 	&touch $@
 	$(xargs echo, $(only_nontargets **/*), >> $@)

=back

Some of this documentation is based on the GNU make documentation.

Please note that if a function gets called during makefile initialization,
e.g. the expansion of export variables, error or warning messages will report
line number 0.

=head1 AUTHOR

Gary Holt (holt-makepp@gholt.net)