Source/cmGlobalUnixMakefileGenerator3.h - third_party/cmake - Git at Google

 /*=========================================================================

   Program:   CMake - Cross-Platform Makefile Generator3
   Module:    $RCSfile$
   Language:  C++
   Date:      $Date$
   Version:   $Revision$

   Copyright (c) 2005 Kitware, Inc., Insight Consortium.  All rights reserved.
   See Copyright.txt or http://www.cmake.org/HTML/Copyright.html for details.

      This software is distributed WITHOUT ANY WARRANTY; without even
      the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
      PURPOSE.  See the above copyright notices for more information.

 =========================================================================*/
 #ifndef cmGlobalUnixMakefileGenerator3_h
 #define cmGlobalUnixMakefileGenerator3_h

 #include "cmGlobalGenerator.h"

 class cmGeneratedFileStream;
 class cmLocalUnixMakefileGenerator3;

 /** \class cmGlobalUnixMakefileGenerator3
  * \brief Write a Unix makefiles.
  *
  * cmGlobalUnixMakefileGenerator3 manages UNIX build process for a tree


  The basic approach of this generator is to produce Makefiles that will all
  be run with the current working directory set to the Home Output
  directory. The one exception to this is the subdirectory Makefiles which are
  created as a convenience and just cd up to the Home Output directory and
  invoke the main Makefiles.

  The make process starts with Makefile. Makefile should only contain the
  targets the user is likely to invoke directly from a make command line. No
  internal targets should be in this file. Makefile2 contains the internal
  targets that are required to make the process work.

  Makefile2 in turn will recursively make targets in the correct order. Each
  target has its own directory <target>.dir and its own makefile build.make in
  that directory. Also in that directory is a couple makefiles per source file
  used by the target. Typically these are named source.obj.build.make and
  source.obj.build.depend.make. The source.obj.build.make contains the rules
  for building, cleaning, and computing dependencies for the given source
  file. The build.depend.make contains additional dependencies that were
  computed during dependency scanning. An additional file called
  source.obj.depend is used as a marker to indicate when dependencies must be
  rescanned.

  Rules for custom commands follow the same model as rules for source files.

  */

 class cmGlobalUnixMakefileGenerator3 : public cmGlobalGenerator
 {
 public:
   cmGlobalUnixMakefileGenerator3();
   static cmGlobalGenerator* New() {
     return new cmGlobalUnixMakefileGenerator3; }

   ///! Get the name for the generator.
   virtual const char* GetName() const {
     return cmGlobalUnixMakefileGenerator3::GetActualName();}
   static const char* GetActualName() {return "Unix Makefiles";}

   /** Get the documentation entry for this generator.  */
   virtual void GetDocumentation(cmDocumentationEntry& entry) const;

   ///! Create a local generator appropriate to this Global Generator3
   virtual cmLocalGenerator *CreateLocalGenerator();

   /**
    * Try to determine system infomation such as shared library
    * extension, pthreads, byte order etc.
    */
   virtual void EnableLanguage(std::vector<std::string>const& languages,
                               cmMakefile *);

   /**
    * Generate the all required files for building this project/tree. This
    * basically creates a series of LocalGenerators for each directory and
    * requests that they Generate.
    */
   virtual void Generate();


   void WriteMainCMakefileLanguageRules(cmGeneratedFileStream& cmakefileStream,
                                        std::vector<cmLocalGenerator *> &);

   // write out the help rule listing the valid targets
   void WriteHelpRule(std::ostream& ruleFileStream,
                      cmLocalUnixMakefileGenerator3 *);

   // write the top lvel target rules
   void WriteConvenienceRules(std::ostream& ruleFileStream,
                              std::set<cmStdString> &emitted);

   /** In order to support parallel builds for custom commands with
       multiple outputs the outputs are given a serial order, and only
       the first output actually has the build rule.  Other outputs
       just depend on the first one.  The check-build-system step must
       remove a dependee if the depender is missing to make sure both
       are regenerated properly.  This method is used by the local
       makefile generators to register such pairs.  */
   void AddMultipleOutputPair(const char* depender, const char* dependee);

   /** Support for multiple custom command outputs.  Called during
       check-build-system step.  */
   virtual void CheckMultipleOutputs(cmMakefile* mf, bool verbose);

   /** Get the command to use for a non-symbolic target file that has
       no rule.  This is used for multiple output dependencies.  */
   std::string GetEmptyCommandHack() { return this->EmptyCommandsHack; }

   /** Get the fake dependency to use when a rule has no real commands
       or dependencies.  */
   std::string GetEmptyRuleHackDepends() { return this->EmptyRuleHackDepends; }

   // change the build command for speed
   virtual std::string GenerateBuildCommand
   (const char* makeProgram,
    const char *projectName, const char* additionalOptions,
    const char *targetName,
    const char* config, bool ignoreErrors, bool fast);

   // returns some progress informaiton
   int GetTargetTotalNumberOfActions(cmTarget& target,
                                     std::set<cmStdString> &emitted);
   unsigned long GetNumberOfProgressActionsInAll
   (cmLocalUnixMakefileGenerator3 *lg);

   // what targets does the specified target depend on
   std::vector<cmTarget *>& GetTargetDepends(cmTarget& target);

 protected:
   void WriteMainMakefile2();
   void WriteMainCMakefile();

   void WriteConvenienceRules2(std::ostream& ruleFileStream,
                               cmLocalUnixMakefileGenerator3 *,
                               bool exclude);

   void WriteDirectoryRule2(std::ostream& ruleFileStream,
                            cmLocalUnixMakefileGenerator3* lg,
                            const char* pass, bool check_all,
                            bool check_relink);
   void WriteDirectoryRules2(std::ostream& ruleFileStream,
                             cmLocalUnixMakefileGenerator3* lg);

   void AppendGlobalTargetDepends(std::vector<std::string>& depends,
                                  cmTarget& target);
   void AppendAnyGlobalDepend(std::vector<std::string>& depends,
                              const char* name,
                              std::set<cmStdString>& emitted,
                              cmTarget &target);

   // does this generator need a requires step for any of its targets
   bool NeedRequiresStep(cmLocalUnixMakefileGenerator3 *lg, const char *);

   // Setup target names
   virtual const char* GetAllTargetName()          { return "all"; }
   virtual const char* GetInstallTargetName()      { return "install"; }
   virtual const char* GetInstallLocalTargetName() { return "install/local"; }
   virtual const char* GetPreinstallTargetName()   { return "preinstall"; }
   virtual const char* GetTestTargetName()         { return "test"; }
   virtual const char* GetPackageTargetName()      { return "package"; }
   virtual const char* GetPackageSourceTargetName(){ return "package_source"; }
   virtual const char* GetEditCacheTargetName()    { return "edit_cache"; }
   virtual const char* GetRebuildCacheTargetName() { return "rebuild_cache"; }

   // Some make programs (Borland) do not keep a rule if there are no
   // dependencies or commands.  This is a problem for creating rules
   // that might not do anything but might have other dependencies
   // added later.  If non-empty this variable holds a fake dependency
   // that can be added.
   std::string EmptyRuleHackDepends;

   // Some make programs (Watcom) do not like rules with no commands
   // for non-symbolic targets.  If non-empty this variable holds a
   // bogus command that may be put in the rule to satisfy the make
   // program.
   std::string EmptyCommandsHack;

   typedef std::map<cmStdString, cmStdString> MultipleOutputPairsType;
   MultipleOutputPairsType MultipleOutputPairs;

   std::map<cmStdString, std::vector<cmTarget *> > TargetDependencies;
   std::map<cmStdString, int > TargetSourceFileCount;
 };

 #endif
	/*=========================================================================

	Program: CMake - Cross-Platform Makefile Generator3
	Module: $RCSfile$
	Language: C++
	Date: $Date$
	Version: $Revision$

	Copyright (c) 2005 Kitware, Inc., Insight Consortium. All rights reserved.
	See Copyright.txt or http://www.cmake.org/HTML/Copyright.html for details.

	This software is distributed WITHOUT ANY WARRANTY; without even
	the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
	PURPOSE. See the above copyright notices for more information.

	=========================================================================*/
	#ifndef cmGlobalUnixMakefileGenerator3_h
	#define cmGlobalUnixMakefileGenerator3_h

	#include "cmGlobalGenerator.h"

	class cmGeneratedFileStream;
	class cmLocalUnixMakefileGenerator3;

	/** \class cmGlobalUnixMakefileGenerator3
	* \brief Write a Unix makefiles.
	*
	* cmGlobalUnixMakefileGenerator3 manages UNIX build process for a tree


	The basic approach of this generator is to produce Makefiles that will all
	be run with the current working directory set to the Home Output
	directory. The one exception to this is the subdirectory Makefiles which are
	created as a convenience and just cd up to the Home Output directory and
	invoke the main Makefiles.

	The make process starts with Makefile. Makefile should only contain the
	targets the user is likely to invoke directly from a make command line. No
	internal targets should be in this file. Makefile2 contains the internal
	targets that are required to make the process work.

	Makefile2 in turn will recursively make targets in the correct order. Each
	target has its own directory <target>.dir and its own makefile build.make in
	that directory. Also in that directory is a couple makefiles per source file
	used by the target. Typically these are named source.obj.build.make and
	source.obj.build.depend.make. The source.obj.build.make contains the rules
	for building, cleaning, and computing dependencies for the given source
	file. The build.depend.make contains additional dependencies that were
	computed during dependency scanning. An additional file called
	source.obj.depend is used as a marker to indicate when dependencies must be
	rescanned.

	Rules for custom commands follow the same model as rules for source files.

	*/

	class cmGlobalUnixMakefileGenerator3 : public cmGlobalGenerator
	{
	public:
	cmGlobalUnixMakefileGenerator3();
	static cmGlobalGenerator* New() {
	return new cmGlobalUnixMakefileGenerator3; }

	///! Get the name for the generator.
	virtual const char* GetName() const {
	return cmGlobalUnixMakefileGenerator3::GetActualName();}
	static const char* GetActualName() {return "Unix Makefiles";}

	/** Get the documentation entry for this generator. */
	virtual void GetDocumentation(cmDocumentationEntry& entry) const;

	///! Create a local generator appropriate to this Global Generator3
	virtual cmLocalGenerator *CreateLocalGenerator();

	/**
	* Try to determine system infomation such as shared library
	* extension, pthreads, byte order etc.
	*/
	virtual void EnableLanguage(std::vector<std::string>const& languages,
	cmMakefile *);

	/**
	* Generate the all required files for building this project/tree. This
	* basically creates a series of LocalGenerators for each directory and
	* requests that they Generate.
	*/
	virtual void Generate();


	void WriteMainCMakefileLanguageRules(cmGeneratedFileStream& cmakefileStream,
	std::vector<cmLocalGenerator *> &);

	// write out the help rule listing the valid targets
	void WriteHelpRule(std::ostream& ruleFileStream,
	cmLocalUnixMakefileGenerator3 *);

	// write the top lvel target rules
	void WriteConvenienceRules(std::ostream& ruleFileStream,
	std::set<cmStdString> &emitted);

	/** In order to support parallel builds for custom commands with
	multiple outputs the outputs are given a serial order, and only
	the first output actually has the build rule. Other outputs
	just depend on the first one. The check-build-system step must
	remove a dependee if the depender is missing to make sure both
	are regenerated properly. This method is used by the local
	makefile generators to register such pairs. */
	void AddMultipleOutputPair(const char* depender, const char* dependee);

	/** Support for multiple custom command outputs. Called during
	check-build-system step. */
	virtual void CheckMultipleOutputs(cmMakefile* mf, bool verbose);

	/** Get the command to use for a non-symbolic target file that has
	no rule. This is used for multiple output dependencies. */
	std::string GetEmptyCommandHack() { return this->EmptyCommandsHack; }

	/** Get the fake dependency to use when a rule has no real commands
	or dependencies. */
	std::string GetEmptyRuleHackDepends() { return this->EmptyRuleHackDepends; }

	// change the build command for speed
	virtual std::string GenerateBuildCommand
	(const char* makeProgram,
	const char projectName, const char additionalOptions,
	const char *targetName,
	const char* config, bool ignoreErrors, bool fast);

	// returns some progress informaiton
	int GetTargetTotalNumberOfActions(cmTarget& target,
	std::set<cmStdString> &emitted);
	unsigned long GetNumberOfProgressActionsInAll
	(cmLocalUnixMakefileGenerator3 *lg);

	// what targets does the specified target depend on
	std::vector<cmTarget *>& GetTargetDepends(cmTarget& target);

	protected:
	void WriteMainMakefile2();
	void WriteMainCMakefile();

	void WriteConvenienceRules2(std::ostream& ruleFileStream,
	cmLocalUnixMakefileGenerator3 *,
	bool exclude);

	void WriteDirectoryRule2(std::ostream& ruleFileStream,
	cmLocalUnixMakefileGenerator3* lg,
	const char* pass, bool check_all,
	bool check_relink);
	void WriteDirectoryRules2(std::ostream& ruleFileStream,
	cmLocalUnixMakefileGenerator3* lg);

	void AppendGlobalTargetDepends(std::vector<std::string>& depends,
	cmTarget& target);
	void AppendAnyGlobalDepend(std::vector<std::string>& depends,
	const char* name,
	std::set<cmStdString>& emitted,
	cmTarget &target);

	// does this generator need a requires step for any of its targets
	bool NeedRequiresStep(cmLocalUnixMakefileGenerator3 lg, const char );

	// Setup target names
	virtual const char* GetAllTargetName() { return "all"; }
	virtual const char* GetInstallTargetName() { return "install"; }
	virtual const char* GetInstallLocalTargetName() { return "install/local"; }
	virtual const char* GetPreinstallTargetName() { return "preinstall"; }
	virtual const char* GetTestTargetName() { return "test"; }
	virtual const char* GetPackageTargetName() { return "package"; }
	virtual const char* GetPackageSourceTargetName(){ return "package_source"; }
	virtual const char* GetEditCacheTargetName() { return "edit_cache"; }
	virtual const char* GetRebuildCacheTargetName() { return "rebuild_cache"; }

	// Some make programs (Borland) do not keep a rule if there are no
	// dependencies or commands. This is a problem for creating rules
	// that might not do anything but might have other dependencies
	// added later. If non-empty this variable holds a fake dependency
	// that can be added.
	std::string EmptyRuleHackDepends;

	// Some make programs (Watcom) do not like rules with no commands
	// for non-symbolic targets. If non-empty this variable holds a
	// bogus command that may be put in the rule to satisfy the make
	// program.
	std::string EmptyCommandsHack;

	typedef std::map<cmStdString, cmStdString> MultipleOutputPairsType;
	MultipleOutputPairsType MultipleOutputPairs;

	std::map<cmStdString, std::vector<cmTarget *> > TargetDependencies;
	std::map<cmStdString, int > TargetSourceFileCount;
	};

	#endif