&SCons; provides a number of ways that allow the writer of the &SConscript; files to give users a great deal of control over how to run the builds.
Not Having to Specify Command-Line Options Each Time: the &SCONSFLAGS; Environment Variable Users may find themselves supplying the same command-line options every time they run &SCons;. For example, a user might find that it saves time to specify a value of -j 2 to run the builds in parallel. To avoid having to type -j 2 by hand every time, you can set the external environment variable &SCONSFLAGS; to a string containing command-line options that you want &SCons; to use. If, for example, and you're using a POSIX shell that's compatible with the Bourne shell, and you always want &SCons; to use the -Q option, you can set the &SCONSFLAGS; environment as follows: % scons scons: Reading SConscript files ... scons: done reading SConscript files. scons: Building targets ... ... [build output] ... scons: done building targets. % export SCONSFLAGS="-Q" % scons ... [build output] ... Users of &csh;-style shells on POSIX systems can set the &SCONSFLAGS; environment as follows: $ setenv SCONSFLAGS "-Q" Windows users may typically want to set this &SCONSFLAGS; in the appropriate tab of the System Properties window.
Getting at Command-Line Targets &SCons; supports a &COMMAND_LINE_TARGETS; variable that lets you get at the list of targets that the user specified on the command line. You can use the targets to manipulate the build in any way you wish. As a simple example, suppose that you want to print a reminder to the user whenever a specific program is built. You can do this by checking for the target in the &COMMAND_LINE_TARGETS; list: if 'bar' in COMMAND_LINE_TARGETS: print "Don't forget to copy `bar' to the archive!" Default(Program('foo.c')) Program('bar.c') Then, running &SCons; with the default target works as it always does, but explicity specifying the &bar; target on the command line generates the warning message: % scons -Q cc -c -o foo.o foo.c cc -o foo foo.o % scons -Q bar Don't forget to copy `bar' to the archive! cc -c -o bar.o bar.c cc -o bar bar.o Another practical use for the &COMMAND_LINE_TARGETS; variable might be to speed up a build by only reading certain subsidiary &SConscript; files if a specific target is requested.
Controlling the Default Targets One of the most basic things you can control is which targets &SCons; will build by default--that is, when there are no targets specified on the command line. As mentioned previously, &SCons; will normally build every target in or below the current directory by default--that is, when you don't explicitly specify one or more targets on the command line. Sometimes, however, you may want to specify explicitly that only certain programs, or programs in certain directories, should be built by default. You do this with the &Default; function: env = Environment() hello = env.Program('hello.c') env.Program('goodbye.c') Default(hello) This &SConstruct; file knows how to build two programs, &hello; and &goodbye;, but only builds the &hello; program by default: % scons -Q cc -c -o hello.o hello.c cc -o hello hello.o % scons -Q scons: `hello' is up to date. % scons -Q goodbye cc -c -o goodbye.o goodbye.c cc -o goodbye goodbye.o Note that, even when you use the &Default; function in your &SConstruct; file, you can still explicitly specify the current directory (.) on the command line to tell &SCons; to build everything in (or below) the current directory: % scons -Q . cc -c -o goodbye.o goodbye.c cc -o goodbye goodbye.o cc -c -o hello.o hello.c cc -o hello hello.o You can also call the &Default; function more than once, in which case each call adds to the list of targets to be built by default: env = Environment() prog1 = env.Program('prog1.c') Default(prog1) prog2 = env.Program('prog2.c') prog3 = env.Program('prog3.c') Default(prog3) Or you can specify more than one target in a single call to the &Default; function: env = Environment() prog1 = env.Program('prog1.c') prog2 = env.Program('prog2.c') prog3 = env.Program('prog3.c') Default(prog1, prog3) Either of these last two examples will build only the prog1 and prog3 programs by default: % scons -Q cc -c -o prog1.o prog1.c cc -o prog1 prog1.o cc -c -o prog3.o prog3.c cc -o prog3 prog3.o % scons -Q . cc -c -o prog2.o prog2.c cc -o prog2 prog2.o You can list a directory as an argument to &Default;: env = Environment() env.Program(['prog1/main.c', 'prog1/foo.c']) env.Program(['prog2/main.c', 'prog2/bar.c']) Default('prog1') In which case only the target(s) in that directory will be built by default: % scons -Q cc -c -o prog1/foo.o prog1/foo.c cc -c -o prog1/main.o prog1/main.c cc -o prog1/main prog1/main.o prog1/foo.o % scons -Q scons: `prog1' is up to date. % scons -Q . cc -c -o prog2/bar.o prog2/bar.c cc -c -o prog2/main.o prog2/main.c cc -o prog2/main prog2/main.o prog2/bar.o Lastly, if for some reason you don't want any targets built by default, you can use the Python None variable: env = Environment() prog1 = env.Program('prog1.c') prog2 = env.Program('prog2.c') Default(None) Which would produce build output like: % scons -Q scons: *** No targets specified and no Default() targets found. Stop. % scons -Q . cc -c -o prog1.o prog1.c cc -o prog1 prog1.o cc -c -o prog2.o prog2.c cc -o prog2 prog2.o
Getting at the List of Default Targets &SCons; supports a &DEFAULT_TARGETS; variable that lets you get at the current list of default targets. The &DEFAULT_TARGETS variable has two important differences from the &COMMAND_LINE_TARGETS; variable. First, the &DEFAULT_TARGETS; variable is a list of internal &SCons; nodes, so you need to convert the list elements to strings if you want to print them or look for a specific target name. Fortunately, you can do this easily by using the Python map function to run the list through str: prog1 = Program('prog1.c') Default(prog1) print "DEFAULT_TARGETS is", map(str, DEFAULT_TARGETS) (Keep in mind that all of the manipulation of the &DEFAULT_TARGETS; list takes place during the first phase when &SCons; is reading up the &SConscript; files, which is obvious if we leave off the -Q flag when we run &SCons;:) % scons scons: Reading SConscript files ... DEFAULT_TARGETS is ['prog1'] scons: done reading SConscript files. scons: Building targets ... cc -c -o prog1.o prog1.c cc -o prog1 prog1.o scons: done building targets. Second, the contents of the &DEFAULT_TARGETS; list change in response to calls to the &Default;: function, as you can see from the following &SConstruct; file: prog1 = Program('prog1.c') Default(prog1) print "DEFAULT_TARGETS is now", map(str, DEFAULT_TARGETS) prog2 = Program('prog2.c') Default(prog2) print "DEFAULT_TARGETS is now", map(str, DEFAULT_TARGETS) Which yields the output: % scons scons: Reading SConscript files ... DEFAULT_TARGETS is now ['prog1'] DEFAULT_TARGETS is now ['prog1', 'prog2'] scons: done reading SConscript files. scons: Building targets ... cc -c -o prog1.o prog1.c cc -o prog1 prog1.o cc -c -o prog2.o prog2.c cc -o prog2 prog2.o scons: done building targets. In practice, this simply means that you need to pay attention to the order in which you call the &Default; function and refer to the &DEFAULT_TARGETS; list, to make sure that you don't examine the list before you've added the default targets you expect to find in it.
Getting at the List of Build Targets, Regardless of Origin We've already been introduced to the &COMMAND_LINE_TARGETS; variable, which contains a list of targets specified on the command line, and the &DEFAULT_TARGETS; variable, which contains a list of targets specified via calls to the &Default; method or function. Sometimes, however, you want a list of whatever targets &SCons; will try to build, regardless of whether the targets came from the command line or a &Default; call. You could code this up by hand, as follows: if COMMAND_LINE_TARGETS: targets = COMMAND_LINE_TARGETS else: targets = DEFAULT_TARGETS &SCons;, however, provides a convenient &BUILD_TARGETS; variable that eliminates the need for this by-hand manipulation. Essentially, the &BUILD_TARGETS; variable contains a list of the command-line targets, if any were specified, and if no command-line targets were specified, it contains a list of the targets specified via the &Default; method or function. Because &BUILD_TARGETS; may contain a list of &SCons; nodes, you must convert the list elements to strings if you want to print them or look for a specific target name, just like the &DEFAULT_TARGETS; list: prog1 = Program('prog1.c') Program('prog2.c') Default(prog1) print "BUILD_TARGETS is", map(str, BUILD_TARGETS) Notice how the value of &BUILD_TARGETS; changes depending on whether a target is specified on the command line: % scons -Q BUILD_TARGETS is ['prog1'] cc -c -o prog1.o prog1.c cc -o prog1 prog1.o % scons -Q prog2 BUILD_TARGETS is ['prog2'] cc -c -o prog2.o prog2.c cc -o prog2 prog2.o % scons -Q -c . BUILD_TARGETS is ['.'] Removed prog1.o Removed prog1 Removed prog2.o Removed prog2
Command-Line <varname>variable</varname>=<varname>value</varname> Build Options You may want to control various aspects of your build by allowing the user to specify variable=value values on the command line. For example, suppose you want users to be able to build a debug version of a program by running &SCons; as follows: % scons -Q debug=1 &SCons; provides an &ARGUMENTS; dictionary that stores all of the variable=value assignments from the command line. This allows you to modify aspects of your build in response to specifications on the command line. (Note that unless you want to require that users always specify an option, you probably want to use the Python ARGUMENTS.get() function, which allows you to specify a default value to be used if there is no specification on the command line.) The following code sets the &cv-link-CCFLAGS; construction variable in response to the debug flag being set in the &ARGUMENTS; dictionary: env = Environment() debug = ARGUMENTS.get('debug', 0) if int(debug): env.Append(CCFLAGS = '-g') env.Program('prog.c') This results in the -g compiler option being used when debug=1 is used on the command line: % scons -Q debug=0 cc -c -o prog.o prog.c cc -o prog prog.o % scons -Q debug=0 scons: `.' is up to date. % scons -Q debug=1 cc -g -c -o prog.o prog.c cc -o prog prog.o % scons -Q debug=1 scons: `.' is up to date. Notice that &SCons; keeps track of the last values used to build the object files, and as a result correctly rebuilds the object and executable files only when the value of the debug argument has changed.
Controlling Command-Line Build Options Being able to use a command-line build option like debug=1 is handy, but it can be a chore to write specific Python code to recognize each such option and apply the values to a construction variable. To help with this, &SCons; supports a class to define such build options easily, and a mechanism to apply the build options to a construction environment. This allows you to control how the build options affect construction environments. For example, suppose that you want users to set a &RELEASE; construction variable on the command line whenever the time comes to build a program for release, and that the value of this variable should be added to the command line with the appropriate -D option (or other command line option) to pass the value to the C compiler. Here's how you might do that by setting the appropriate value in a dictionary for the &cv-link-CPPDEFINES; construction variable: opts = Options() opts.Add('RELEASE', 'Set to 1 to build for release', 0) env = Environment(options = opts, CPPDEFINES={'RELEASE_BUILD' : '${RELEASE}'}) env.Program(['foo.c', 'bar.c']) This &SConstruct; file first creates an &Options; object (the opts = Options() call), and then uses the object's &Add; method to indicate that the &RELEASE; option can be set on the command line, and that it's default value will be 0 (the third argument to the &Add; method). The second argument is a line of help text; we'll learn how to use it in the next section. We then pass the created &Options; object as an &options; keyword argument to the &Environment; call used to create the construction environment. This then allows a user to set the &RELEASE; build option on the command line and have the variable show up in the command line used to build each object from a C source file: % scons -Q RELEASE=1 cc -DRELEASE_BUILD=1 -c -o bar.o bar.c cc -DRELEASE_BUILD=1 -c -o foo.o foo.c cc -o foo foo.o bar.o
Providing Help for Command-Line Build Options To make command-line build options most useful, you ideally want to provide some help text that will describe the available options when the user runs scons -h. You could write this text by hand, but &SCons; provides an easier way. &Options; objects support a &GenerateHelpText; method that will, as its name indicates, generate text that describes the various options that have been added to it. You then pass the output from this method to the &Help; function: opts = Options('custom.py') opts.Add('RELEASE', 'Set to 1 to build for release', 0) env = Environment(options = opts) Help(opts.GenerateHelpText(env)) &SCons; will now display some useful text when the -h option is used: % scons -Q -h RELEASE: Set to 1 to build for release default: 0 actual: 0 Use scons -H for help about command-line options. Notice that the help output shows the default value, and the current actual value of the build option.
Reading Build Options From a File Being able to use a command-line build option like debug=1 is handy, but it can be a chore to write specific Python code to recognize each such option and apply the values to a construction variable. To help with this, &SCons; supports a class to define such build options easily and to read build option values from a file. This allows you to control how the build options affect construction environments. The way you do this is by specifying a file name when you call &Options;, like &custom_py; in the following example: opts = Options('custom.py') opts.Add('RELEASE', 'Set to 1 to build for release', 0) env = Environment(options = opts, CPPDEFINES={'RELEASE_BUILD' : '${RELEASE}'}) env.Program(['foo.c', 'bar.c']) Help(opts.GenerateHelpText(env)) This then allows us to control the &RELEASE; variable by setting it in the &custom_py; file: RELEASE = 1 Note that this file is actually executed like a Python script. Now when we run &SCons;: % scons -Q cc -DRELEASE_BUILD=1 -c -o bar.o bar.c cc -DRELEASE_BUILD=1 -c -o foo.o foo.c cc -o foo foo.o bar.o And if we change the contents of &custom_py; to: RELEASE = 0 The object files are rebuilt appropriately with the new option: % scons -Q cc -DRELEASE_BUILD=0 -c -o bar.o bar.c cc -DRELEASE_BUILD=0 -c -o foo.o foo.c cc -o foo foo.o bar.o
Canned Build Options &SCons; provides a number of functions that provide ready-made behaviors for various types of command-line build options.
True/False Values: the &BoolOption; Build Option It's often handy to be able to specify an option that controls a simple Boolean variable with a &true; or &false; value. It would be even more handy to accomodate users who have different preferences for how to represent &true; or &false; values. The &BoolOption; function makes it easy to accomodate a variety of common values that represent &true; or &false;. The &BoolOption; function takes three arguments: the name of the build option, the default value of the build option, and the help string for the option. It then returns appropriate information for passing to the &Add; method of an &Options; object, like so: opts = Options('custom.py') opts.Add(BoolOption('RELEASE', 'Set to build for release', 0)) env = Environment(options = opts, CPPDEFINES={'RELEASE_BUILD' : '${RELEASE}'}) env.Program('foo.c') With this build option, the &RELEASE; variable can now be enabled by setting it to the value yes or t: % scons -Q RELEASE=yes foo.o cc -DRELEASE_BUILD=1 -c -o foo.o foo.c % scons -Q RELEASE=t foo.o cc -DRELEASE_BUILD=1 -c -o foo.o foo.c Other values that equate to &true; include y, 1, on and all. Conversely, &RELEASE; may now be given a &false; value by setting it to no or f: % scons -Q RELEASE=no foo.o cc -DRELEASE_BUILD=0 -c -o foo.o foo.c % scons -Q RELEASE=f foo.o cc -DRELEASE_BUILD=0 -c -o foo.o foo.c Other values that equate to &true; include n, 0, off and none. Lastly, if a user tries to specify any other value, &SCons; supplies an appropriate error message: % scons -Q RELEASE=bad_value foo.o scons: *** Error converting option: RELEASE Invalid value for boolean option: bad_value File "SConstruct", line 4, in ?
Single Value From a List: the &EnumOption; Build Option Suppose that we want a user to be able to set a &COLOR; option that selects a background color to be displayed by an application, but that we want to restrict the choices to a specific set of allowed colors. This can be set up quite easily using the &EnumOption;, which takes a list of &allowed_values in addition to the variable name, default value, and help text arguments: opts = Options('custom.py') opts.Add(EnumOption('COLOR', 'Set background color', 'red', allowed_values=('red', 'green', 'blue'))) env = Environment(options = opts, CPPDEFINES={'COLOR' : '"${COLOR}"'}) env.Program('foo.c') The user can now explicity set the &COLOR; build option to any of the specified allowed values: % scons -Q COLOR=red foo.o cc -DCOLOR="red" -c -o foo.o foo.c % scons -Q COLOR=blue foo.o cc -DCOLOR="blue" -c -o foo.o foo.c % scons -Q COLOR=green foo.o cc -DCOLOR="green" -c -o foo.o foo.c But, almost more importantly, an attempt to set &COLOR; to a value that's not in the list generates an error message: % scons -Q COLOR=magenta foo.o scons: *** Invalid value for option COLOR: magenta File "SConstruct", line 5, in ? The &EnumOption; function also supports a way to map alternate names to allowed values. Suppose, for example, that we want to allow the user to use the word navy as a synonym for blue. We do this by adding a ↦ dictionary that will map its key values to the desired legal value: opts = Options('custom.py') opts.Add(EnumOption('COLOR', 'Set background color', 'red', allowed_values=('red', 'green', 'blue'), map={'navy':'blue'})) env = Environment(options = opts, CPPDEFINES={'COLOR' : '"${COLOR}"'}) env.Program('foo.c') As desired, the user can then use navy on the command line, and &SCons; will translate it into blue when it comes time to use the &COLOR; option to build a target: % scons -Q COLOR=navy foo.o cc -DCOLOR="blue" -c -o foo.o foo.c By default, when using the &EnumOption; function, arguments that differ from the legal values only in case are treated as illegal values: % scons -Q COLOR=Red foo.o scons: *** Invalid value for option COLOR: Red File "SConstruct", line 5, in ? % scons -Q COLOR=BLUE foo.o scons: *** Invalid value for option COLOR: BLUE File "SConstruct", line 5, in ? % scons -Q COLOR=nAvY foo.o scons: *** Invalid value for option COLOR: nAvY File "SConstruct", line 5, in ? The &EnumOption; function can take an additional &ignorecase; keyword argument that, when set to 1, tells &SCons; to allow case differences when the values are specified: opts = Options('custom.py') opts.Add(EnumOption('COLOR', 'Set background color', 'red', allowed_values=('red', 'green', 'blue'), map={'navy':'blue'}, ignorecase=1)) env = Environment(options = opts, CPPDEFINES={'COLOR' : '"${COLOR}"'}) env.Program('foo.c') Which yields the output: % scons -Q COLOR=Red foo.o cc -DCOLOR="Red" -c -o foo.o foo.c % scons -Q COLOR=BLUE foo.o cc -DCOLOR="BLUE" -c -o foo.o foo.c % scons -Q COLOR=nAvY foo.o cc -DCOLOR="blue" -c -o foo.o foo.c % scons -Q COLOR=green foo.o cc -DCOLOR="green" -c -o foo.o foo.c Notice that an &ignorecase; value of 1 preserves the case-spelling that the user supplied. If you want &SCons; to translate the names into lower-case, regardless of the case used by the user, specify an &ignorecase; value of 2: opts = Options('custom.py') opts.Add(EnumOption('COLOR', 'Set background color', 'red', allowed_values=('red', 'green', 'blue'), map={'navy':'blue'}, ignorecase=2)) env = Environment(options = opts, CPPDEFINES={'COLOR' : '"${COLOR}"'}) env.Program('foo.c') Now &SCons; will use values of red, green or blue regardless of how the user spells those values on the command line: % scons -Q COLOR=Red foo.o cc -DCOLOR="red" -c -o foo.o foo.c % scons -Q COLOR=nAvY foo.o cc -DCOLOR="blue" -c -o foo.o foo.c % scons -Q COLOR=GREEN foo.o cc -DCOLOR="green" -c -o foo.o foo.c
Multiple Values From a List: the &ListOption; Build Option Another way in which you might want to allow users to control build option is to specify a list of one or more legal values. &SCons; supports this through the &ListOption; function. If, for example, we want a user to be able to set a &COLORS; option to one or more of the legal list of values: opts = Options('custom.py') opts.Add(ListOption('COLORS', 'List of colors', 0, ['red', 'green', 'blue'])) env = Environment(options = opts, CPPDEFINES={'COLORS' : '"${COLORS}"'}) env.Program('foo.c') A user can now specify a comma-separated list of legal values, which will get translated into a space-separated list for passing to the any build commands: % scons -Q COLORS=red,blue foo.o cc -DCOLORS="red blue" -c -o foo.o foo.c % scons -Q COLORS=blue,green,red foo.o cc -DCOLORS="blue green red" -c -o foo.o foo.c In addition, the &ListOption; function allows the user to specify explicit keywords of &all; or &none; to select all of the legal values, or none of them, respectively: % scons -Q COLORS=all foo.o cc -DCOLORS="red green blue" -c -o foo.o foo.c % scons -Q COLORS=none foo.o cc -DCOLORS="" -c -o foo.o foo.c And, of course, an illegal value still generates an error message: % scons -Q COLORS=magenta foo.o scons: *** Error converting option: COLORS Invalid value(s) for option: magenta File "SConstruct", line 5, in ?
Path Names: the &PathOption; Build Option &SCons; supports a &PathOption; function to make it easy to create a build option to control an expected path name. If, for example, you need to define a variable in the preprocessor that control the location of a configuration file: opts = Options('custom.py') opts.Add(PathOption('CONFIG', 'Path to configuration file', '/etc/my_config')) env = Environment(options = opts, CPPDEFINES={'CONFIG_FILE' : '"$CONFIG"'}) env.Program('foo.c') This then allows the user to override the &CONFIG; build option on the command line as necessary: % scons -Q foo.o cc -DCONFIG_FILE="/etc/my_config" -c -o foo.o foo.c % scons -Q CONFIG=/usr/local/etc/other_config foo.o scons: `foo.o' is up to date. By default, &PathOption; checks to make sure that the specified path exists and generates an error if it doesn't: % scons -Q CONFIG=/does/not/exist foo.o scons: *** Path for option CONFIG does not exist: /does/not/exist File "SConstruct", line 6, in ? &PathOption; provides a number of methods that you can use to change this behavior. If you want to ensure that any specified paths are, in fact, files and not directories, use the &PathOption_PathIsFile; method: opts = Options('custom.py') opts.Add(PathOption('CONFIG', 'Path to configuration file', '/etc/my_config', PathOption.PathIsFile)) env = Environment(options = opts, CPPDEFINES={'CONFIG_FILE' : '"$CONFIG"'}) env.Program('foo.c') Conversely, to ensure that any specified paths are directories and not files, use the &PathOption_PathIsDir; method: opts = Options('custom.py') opts.Add(PathOption('DBDIR', 'Path to database directory', '/var/my_dbdir', PathOption.PathIsDir)) env = Environment(options = opts, CPPDEFINES={'DBDIR' : '"$DBDIR"'}) env.Program('foo.c') If you want to make sure that any specified paths are directories, and you would like the directory created if it doesn't already exist, use the &PathOption_PathIsDirCreate; method: opts = Options('custom.py') opts.Add(PathOption('DBDIR', 'Path to database directory', '/var/my_dbdir', PathOption.PathIsDirCreate)) env = Environment(options = opts, CPPDEFINES={'DBDIR' : '"$DBDIR"'}) env.Program('foo.c') Lastly, if you don't care whether the path exists, is a file, or a directory, use the &PathOption_PathAccept; method to accept any path that the user supplies: opts = Options('custom.py') opts.Add(PathOption('OUTPUT', 'Path to output file or directory', None, PathOption.PathAccept)) env = Environment(options = opts, CPPDEFINES={'OUTPUT' : '"$OUTPUT"'}) env.Program('foo.c')
Enabled/Disabled Path Names: the &PackageOption; Build Option Sometimes you want to give users even more control over a path name variable, allowing them to explicitly enable or disable the path name by using yes or no keywords, in addition to allow them to supply an explicit path name. &SCons; supports the &PackageOption; function to support this: opts = Options('custom.py') opts.Add(PackageOption('PACKAGE', 'Location package', '/opt/location')) env = Environment(options = opts, CPPDEFINES={'PACKAGE' : '"$PACKAGE"'}) env.Program('foo.c') When the &SConscript; file uses the &PackageOption; funciton, user can now still use the default or supply an overriding path name, but can now explicitly set the specified variable to a value that indicates the package should be enabled (in which case the default should be used) or disabled: % scons -Q foo.o cc -DPACKAGE="/opt/location" -c -o foo.o foo.c % scons -Q PACKAGE=/usr/local/location foo.o cc -DPACKAGE="/usr/local/location" -c -o foo.o foo.c % scons -Q PACKAGE=yes foo.o cc -DPACKAGE="1" -c -o foo.o foo.c % scons -Q PACKAGE=no foo.o cc -DPACKAGE="0" -c -o foo.o foo.c
Adding Multiple Command-Line Build Options at Once Lastly, &SCons; provides a way to add multiple build options to an &Options; object at once. Instead of having to call the &Add; method multiple times, you can call the &AddOptions; method with a list of build options to be added to the object. Each build option is specified as either a tuple of arguments, just like you'd pass to the &Add; method itself, or as a call to one of the canned functions for pre-packaged command-line build options. in any order: opts = Options() opts.AddOptions( ('RELEASE', 'Set to 1 to build for release', 0), ('CONFIG', 'Configuration file', '/etc/my_config'), BoolOption('warnings', 'compilation with -Wall and similiar', 1), EnumOption('debug', 'debug output and symbols', 'no', allowed_values=('yes', 'no', 'full'), map={}, ignorecase=0), # case sensitive ListOption('shared', 'libraries to build as shared libraries', 'all', names = list_of_libs), PackageOption('x11', 'use X11 installed here (yes = search some places)', 'yes'), PathOption('qtdir', 'where the root of Qt is installed', qtdir), )