FreeType 2.0 Build System

© 2000 David Turner ([email protected])
© 2000 The FreeType Development Team ([email protected])


Table of Content

Introduction

I. Features & Background

II. Overview of the build process

III. Build setup details

IV. Library compilation details


Introduction:

This document describes the new build system that was introduced with FreeType 2.


I. Features and Background:

The FreeType 2 build system is a set of Makefiles and sub-Makefiles that are used to build the library on a very large variety of systems easily. One of its main features are the following:

1. Convenience, not Requirement

    Even though the build system is rather sophisticated, it simply is a convenience that was written simply to allow the compilation of the FreeType 2 library on as many platforms as possible, as easily as possible. However, it is not a requirement and the library can be compiled manually or in a graphical IDE without using it, with minimal efforts

    (for more information on this topic, see the BUILD document that comes with your release of FreeType, in its Detailed Compilation Guide section).

2. Compiler and platform independence

    The FreeType 2 build system can be used with any compiler, on any platform. It is independent of object file suffix, executable file suffix, directory separator convention (i.e. "/" or "\"), and compiler flags for path inclusion, macro definition, output naming, ansi compliance, etc..

    Supporting a new compiler is trivial and only requires writing a minimal configuration sub-makefile that contains several Makefile variables definitions that are later used by the rest of the build system. This is described in details later in the document.

3. Uses GNU Make

    The build system works exclusively with GNU Make. Reason is that it is the only make utility that has all the features required to implement the build system as described below. Moreover, it is already ported to hundreds of various distinct platforms and is widely and freely available.

    It also uses the native command line shell. You thus don't need a Unix-like shell on your platform. For example, FreeType 2 already compiles on Unix, Dos, Windows and OS/2 right "out of the box" (assuming you have GNU Make installed).

    Finally, note that the build system is specifically designed for gnu make and will fail with any other make tool. We have no plans to support a different tools, as you'll rapidly understand by reading this document or looking at the sub-makefiles themselves.

4. Automatic host platform detection

    When you launch the build system for the first time, by simply invoking GNU make in the top-level directory, it automatically tries to detect your current platform in order to choose the best configuration sub-makefile available. It then displays what it found. If everything is ok, you can then launch compilation of the library, by invoking make a second time.

    The following platforms are currently automatically detected:

    • Dos (plain-dos, windows in Dos mode, or Dos session under OS/2)
    • Windows 95, 98 + Windows NT (a.k.a win32)
    • OS/2
    • Unix (uses Autoconf/Automake)

    Note that adding support for a new platform requires writing a minimal number of very small files, and simply putting them in a new sub-directory of freetype2/config.

5. User-selectable builds

    The platform auto-detection rules try to setup the build for a default compiler (gcc for most platforms), with default build options for the library (which normally is "all features enable, no debugging"), as well as the default list of modules (which is "all modules in freetype2/src")

    There are cases where it is important to specify a different compiler, different build options or simply a different module list. The FreeType 2 build system is designed in such a way that all of this is easily possible from the command line, without having to touch a single file. The latter is crucial when dealing with projects that need specific builds of the library without modifying a single file from the FreeType distribution.

    The exact mechanism and implementation to do this is described later in this document. It allows, for example, to compile FreeType with any of the following compilers on Win32: gcc, Visual C++, Win32-LCC.

6. Robustness

7. Simple Module Management

    FreeType 2 has a very modular design, and is made of a core base layer that provides its high-level API as well as generic services used by one or more modules. Most modules are used to support a specific font format (like TrueType or Type 1), and they are called font drivers. However, some of them do not support font files directly, but rather provide helper services to the font drivers.

    FreeType 2 is designed so that adding modules at run-time is possible and easy. Similarly, we expect many more modules to come in the near future and wanted a build system that makes such additions to the source package itself dead easy. Indeed, all source code (base + modules) is located in the freetype2/src directory hierarchy. And the build system is capable of re-generating automatically the list of known modules from the contents of this directory. Hence, adding a new font driver to the FreeType sources simply requires to:

    • Add a new sub-directory to freetype2/src

    • Re-launch the build system

    There is thus no need to edit a source file


II. Overview of the build process(es):

Before describing in details how the build system works, it is essential to give a few examples of how it's used. This section presents what's the build process is to the typical developer:

Compiling the library is normally done in two steps: the first one configures the build according to the current platform and possible additional parameters, while the second simply compiles the library with the information gathered in the configuration step.

1. Build Setup

a. Default build setup

    To configure the build, simply invoke gnu make from the top-level FreeType directory. This will launch a series of rules that will detect your current host platform, and choose a configuration file for you. It will then display what it found. For example, here's the output of typing the command "make" on a win32 platform (assuming this calls GNU make):

    
        C:\FreeType> make
    
        FreeType build system -- automatic system detection
    
        The following settings are used:
    
          platform                     win32
          compiler                     gcc
          configuration directory      ./config/win32
          configuration rules          ./config/win32/w32-gcc.mk
    
        If this does not correspond to your system or settings please remove the file
        'config.mk' from this directory then read the INSTALL file for help.
    
        Otherwise, simply type 'make' again to build the library.
    
        C:\FreeType>
    

    Note that this step copies the selected configuration file (here ./config/win32/w32-gcc.mk) to the current directory, under the name config.mk. This file contains data that is used to drive the library compilation of the second step. It correspond to the platform and compiler selected by the auto-detection phase.

    Note that you can re-generate the config.mk file anytime by invoking make setup whenever you need it, even when the file is already present in the current directory.

    Finally, if your platform is not correctly detected, the build system will display and use configuration information for the virtual "ansi" platform.

b. Selecting another build configuration

    You may not be really satisfied by the configuration file selected by the auto-detection routines. Typically, you might be using a compiler that is not the default one for your platform. It is however possible to re-launch the build setup phase with an additional argument, used to specify a different compiler/config file. For example, you can type the following commands on Win32 systems:

    make setup

    re-run the platform detection phase, and select the default compiler for it. On Win32, this is gcc.

    make setup visualc

    re-run the platform detection phase, and select a config file that corresponds to the Visual C++ compiler

    make setup lcc

    re-run the platform detection phase, and select a config file that corresponds to the Win32-LCC compiler

    Note that a specific configuration is selected with a command that looks like : make setup compiler, where the compiler keywords depends on the platform. Moreover, each one of them corresponds to a specific configuration sub-makefile that is copied as config.mk in the current directory.

2. Library compilation

Once you're satisfied with the version of config.mk that has been copied to your current directory, you can simply re-invoke gnu make with no arguments. The top-level Makefile will automatically detect the config sub-makefile in the current directory, and use it to drive the library compilation. The latter can be seen as a series of different steps decribed here:

  • Compiling the ftsystem component

      It encapsulates all low-level operations (memory management + i/o access) for the library. Its default version, located in ./src/base/ftsystem.c uses the ANSI C library but system-specific implementations are also available to improve performance (e.g. memory-mapped files on Unix).

  • Compiling the base layer and optional components

      They provide the library's high-level API as well as various useful routines for client applications. Many features of the base layer can be activated or not depending on a configuration file named ftoption.h

  • Compiling the modules

      Each module is used to support a specific font format (it is then called a font driver), or to provide helper services to the drivers (e.g. the auto-hinter). They are all located in sub-directories of ./src, like ./src/truetype, ./src/type1.

  • Compiling the ftinit component

      This one is in charge of implementing FT_Init_FreeType, the library initialisation routine. It also selects what modules are activated when a new library instance is created.


II. Details of the build setup.

When the top-level Makefile is invoked, it looks for a file named config.mk in the current directory. If this file is found, it is used directly to build the library (skip to Section III for details then).

Otherwise, the file ./config/detect.mk is included by the top-level Makefile and parsed. Its purpose is to drive the platform-detection phase, by:

  • Defining the PLATFORM variable, which indicates what the currently detected platform is. It is initially set to the default value "ansi".

  • Searching for a detect.mk file in all subdirectories of ./config. Each such file is included and parsed. Each of these files must try to detect if the host platform is a system it knows about. If so, it changes the value of the PLATFORM variable accordingly.

  • Copying the selected configuration submakefile to the current directory under the name config.mk.

This is illustrated by the following graphics :

Each system-specific detect.mk works as follows:

  • It checks that the value of PLATFORM is currently set to ansi, which indicates that no platform was detected for now. If this isn't true, it doesn't do anything

  • Otherwise, it runs a series of test to see wether it is on a system it knows about. Here are a few examples of tests:

    Unix

    checks for a file named /sbin/init, and runs, when it found it, a 'configure' script to generate the relevant config sub-makefile

    Dos

    checks for the COMSPEC environment variable, then tries to run the "ver" command on the current shell to check that there is a "Dos" substring in its output; if not, it tries to find the substring "MDOS\COMMAND" in COMSPEC, which indicates a Dos session under OS/2.

    Win32

    if the environment variable OS is defined and has the value Windows_NT, or if COMSPEC is defined and the "ver" returns a string that contains Windows in it, we're on a Win32 system.

  • It sets the value of PLATFORM to a new value corresponding to its platform.

  • It then tries to select a configuration sub-makefile, depending on the current platform and any optional make target (like "visualc" or "devel", etc..). Note that it can even generate the file, as on Unix through Autoconf/Automake.

  • It copies the selected configuration sub-makefile to the current directory, under the name config.mk

If one wants to support a new platform in the build system, it simply needs to provide:

  • A new subdirectory, in ./config, with a file named detect.mk in it, containing relevant checks for the system.
  • One or more configuration sub-makefiles that will get copied to config.mk at build setup time. You can use the one in ./config/ansi/config.mk as a template.

Similary, supporting a new compiler on an existing system simply means:

  • Writing a new config sub-makefile that contains definitions used to specify the compiler and flags for the build.
  • Change your ./config/system/detect.mk to recognize a new optional build target that will copy your new config sub-makefile instead of the default one.


III. Details of the library compilation.

When the top-level Makefile is invoked, it looks for a file named config.mk in the current directory. If one is found, it defines the BUILD_FREETYPE variable, then includes and parses it. The structure of this file is the following:

  • First, it defines a series of Make variables that describe the host environment, like the compiler, compilation flags, object file suffix, the directory where all object files are placed, etc..

  • If BUILD_FREETYPE is defined, it includes the file ./config/freetype.mk, which is in charge of defining all the rules used to build the library object files. (The test is useful to use the config.mk file to compile other projects that rely on FreeType 2, like its demonstration programs).

  • Finally, it defines the rule(s) used to link FreeType 2 object files into a library file (e.g. libfreetype.a, freetype.lib, freetype.dll, ...). Unfortunately, the command line interface of link tools is a lot less standardized than those of compilers, which explains why this rule must be defined in the system-specific config.mk.

The following is an explanation of what ./config/freetype.mk does to build the library objects:

a. Include paths

    To avoid namespace pollution, the freetype directory prefix is used to include all public header files of the library. This means that a client application will typically use lines like:

    
        #include <freetype/freetype.h>
        #include <freetype/ftglyph.h>
    

    to include one the FreeType 2 public header files. freetype.mk uses a variable named INCLUDES to hold the inclusion paths list, and thus starts by adding ./include to it. However, nothing prevents

    freetype.mk uses a variable named INCLUDES to hold directory inclusion-path to be used when compiling the library. It always add ./include to this variable, which means

b. Configuration header files:

    Three header files used to configure the compilation of the FreeType 2 library. Their default versions are all located in the directory ./include/freetype/config/, even though project specific versions can be provided on a given build, as described later:

      #include <freetype/config/ftoption.h>

        This file contains a set of configuration macro definitions that can be toggled to activate or deactivate certain features of the library. By changing one of these definitions, it is possible to compile only the features that are needed for a specific project. Note that by default, all options are enabled.

        You might need to provide an alternative version of ftoption.h for one of your own projects.

      #include <freetype/config/ftconfig.h>

        This file includes ftoption.h but also contains some automatic macro definitions used to indicate some important system-specific features (e.g: word size in bytes, DLL export prefix macros, etc..).

        You shouldn't normally need to change or provide an alternative version of this file.

      #include <freetype/config/ftmodule.h>

        This file is very special, as it is normally machine-generated, and used by the ftinit component that is described below. To understand it, one must reminds that FreeType 2 has an extremely modular design and that it's possible to change, at run-time, the modules it's using. The ftmodule.h file simply contains the list of modules that are registered with each new instance of the library.

        Note that the file can be re-generated automatically by invoking make setup from the top-level directory. The re-generated list contains all the modules that were found in subdirectories of ./src.

    Note that we strongly advise you to avoid modifying the config files within the FreeType 2 source directory hierarchy. Rather, it's possible to specify alternative versions through the help of a build-specific include path that is include before ./include in the inclusion path.

    For example, imagine that your platform, named foo, needs a specific version of ftoption.h

a. Compiling the ftsystem component:

    FreeType 2 encapsulates all low-level operations (i.e. memory management and i/o access) within a single component called ftsystem. Its default implementation uses the ANSI C Library and is located in ./src/base/ftsystem.c.

    However, some alternate, system-specific, implementations of ftsystem are provided with the library in order to support more efficient and advanced features. As an example, the file ./config/unix/ftsystem.c is an implementation that uses memory-mapped files rather than the slow ANSI fopen, fread and fseek, boosting performance significantly.

    The build system is thus capable of managing alternate implementations of ftsystem

b. Compiling the base layer and optional components:

    The high-level API of the library is provided by a component called the base layer, whose source is located in ./src/base. This directory also contains one or more components that are optional, i.e. that are not required by the library but provide valuable routines to client applications.

    The features of the base library and other components are selected through a single configuration file named ./include/freetype/config/ftoption.h. It contains a list of commented configuration macro definitions, that can be toggled to activate or de-activate a certain feature or component at build time.

    For example, the code in ./src/base/ftdebug.c will be compiled only if one of these two macros are defined in ftoption.h: FT_DEBUG_LEVEL_ERROR or FT_DEBUG_LEVEL_TRACE

c. Compiling the modules:

    Once the base layer is completed, the build system starts to compile each additional module independently. These are simply defined as all source code located in a sub-directory of ./src that contains a file named rules., for example: src/sfnt, src/truetype, src/type1, ...

    The rules. file simply contains directives used by the build system to compile the corresponding module into a single object file.

d. Compiling the ftinit component:

    The file ./src/base/ftinit.c is special because it is used to implement the library initialisation function FT_Init_FreeType.

Typically, you will end up with all object files, as well as the corresponding library file, residing in the freetype2/obj directory.

1. Purpose of the configuration sub-makefile

2. Managing module dependencies

3.


IV. Managing the modules list


The build system features some important points, which are all detailed in the following sections:

  • Automatic host platform detection
    The first time the top Makefile is invoked, it will run a series of rules to detect your platform. It will then create a system-specific configuration sub-Makefile in the current directory, called config.mk. You can now invoke the top Makefile a second time to compile the library directly.

    The configuration sub-makefile can be regenerated any time by invoking "make setup", which will re-run the detection rules even if a config.mk is already present.

  • User-selectable builds

  • Automatic detection of font drivers
    FreeType is made of a "base" layer that invokes several separately-compiled modules. Each module is a given font driver, in charge of supporting a given font format.

    The list of font drivers is located in the file "freetype2/config/system/ftmodule.h", however it can be regenerated on-demand. Adding a new module to the FreeType source tree is thus as easy as:

    • create a new directory in "freetype2/src" and put the new driver's source code and sub-makefiles there.

    • invoke the top Makefile with target "modules" (as in "make modules"), as this will automatically regenerate the list of available drivers by detecting the new directory and its content.


II. Host Platform Detection

    When the top-level Makefile is invoked, it looks for a file named config.mk in the current directory. If this file is found, it is used to build the library (see Section III).

    Otherwise, the file freetype2/config/detect.mk is included and parsed. Its purpose is to:

    • Define the PLATFORM variable, which indicates what is the currently detected platform. It is initially set to the default value "ansi".

    • It searches for a detect.mk file in all subdirectories of freetype2/config. Each such file is included and parsed. Each of these files must try to detect if the host platform is a system it knows about. If so, it changes the value of the PLATFORM accordingly.

    This is illustrated by the following graphics :

    Note that each system-specific detect.mk is in charge of copying a valid configuration makefile to the current directory (i.e. the one where make was invoked), depending on the current targets. For example, the Win32 detect.mk will be able to detect a "visualc" or "lcc" target, as described in section I. Similarly, the OS/2 detect.mk can detect targets like "borlandc", "watcom" or "visualage", etc..


III. Building the library

    When the top-level Makefile is invoked and that it finds a config.mk file in the current directory, it defines the variable BUILD_FREETYPE, then includes and parses the configuration sub-makefile.

    The latter defines a number of important variables that describe the compilation process to the build system. Among other things:

    • the extension to be used for object files and library files (i.e. .o and .a on Unix, .obj and .lib on Dos-Windows-OS/2, etc..).

    • the directory where all object files will be stored (usually freetype2/obj), as well as the one containing the library file (usually the same as for objects).

    • the command line compiler, and its compilation flags for indicating a new include path (usually "-I"), a new macro declaration (usually "-D") or the target object file (usually "-o ")

    Once these variable are defined, config.mk test for the definition of the BUILD_FREETYPE variable. If it exists, the makefile then includes "freetype2/config/freetype.mk" which contains the rules required to compile the library.

    Note that freetype.mk also scans the subdirectories of "freetype2/src" for a file called "rules.mk". Each rules.mk contains, as it names suggests, the rules required to compile a given font driver or module.

    Once all this parsing is done, the library can be compiled. Usually, each font driver is compiled as a standalone object file (e.g. sfnt.o, truetype.o and type1.o).

    This process can be illustrated by the following graphics:


IIV. Managing the list of modules

    The makefile freetype.mk only determines how to compile each one of the modules that are located in the sub-directories of freetype2/src.

    However, when the function FT_Init_FreeType is invoked at the start of an application, it must create a new FT_Library object, and registers all known font drivers to it by repeatly calling FT_Add_Driver.

    The list of known drivers is located in the file "freetype2/config/system/ftmodule.h", and is used exclusively by the internal function FT_Default_Drivers. The list in ftmodule.h must be re-generated each time you add or remove a module from freetype2/src.

    This is normally performed by invoking the top-level Makefile with the modules target, as in:

      make modules

    This will trigger a special rule that will re-generate ftmodule.h. To do so, the Makefile will parse all module directories for a file called "module.mk". Each module.mk is a tiny sub-Makefile used to add a single module to the driver list.

    This is illustrated by the following graphics:

    Note that the new list of modules is displayed in a very human-friendly way after a "make modules". Here's an example with the current source tree (on 11 Jan 2000):

      Regenerating the font drivers list in ./config/unix/ftmodule.h
      * driver:  sfnt      ( pseudo-driver for TrueType & OpenType formats )
      * driver:  truetype  ( Windows/Mac font files with extension *.ttf or *.ttc )
      * driver:  type1     ( Postscript font files with extension *.pfa or *.pfb )
      -- done --
          


V. Building the demonstration programs

    Several demonstration programs are located in the "freetype2/demos" directory hierarchy. This directory also includes a tiny graphics sub-system that is able to blit glyphs to a great variety of surfaces, as well as display these in various graphics libraries or windowed environments.

    This section describes how the demonstration programs are compiled, using the configuration freetype2/config.mk and their own freetype2/demos/Makefile.

    To compile the demonstration programs, after the library, simply go to freetype2/demos then invoke GNU make with no arguments.

    The top-level Makefile will detect the config.mk in the upper directory and include it. Because it doesn't define the BUILD_FREETYPE variable, this will not force the inclusion of freetype2/config/freetype.mk as described in the previous section.

    the Makefile will then include the makefile called "freetype2/demos/graph/rules.mk". The graphics rules.mk defines the rules required to compile the graphics sub-system.

    Because the graphics syb-system is also designed modularly, it is able to use any number of "modules" to display surfaces on the screen. The graphics modules are located in the subdirectories of freetype2/demos/config. Each such directory contains a file named rules.mk which is in charge of:

    • detecting wether the corresponding graphics library is available at the time of compilation.

    • if it is, alter the compilation rules to include the graphics module in the build of the graph library.

    When the graph library is built in demos/obj, the demonstration programs executables are generated by the top-level Makefile.

    This is illustrated by the following graphics: