Add a class that is useful for hacking around linking problem due to

[oota-llvm.git] / include / llvm / PassSupport.h

//===- llvm/PassSupport.h - Pass Support code -------------------*- C++ -*-===//
//
// This file defines stuff that is used to define and "use" Passes.  This file
// is automatically #included by Pass.h, so:
//
//           NO .CPP FILES SHOULD INCLUDE THIS FILE DIRECTLY
//
// Instead, #include Pass.h.
//
// This file defines Pass registration code and classes used for it.
//
//===----------------------------------------------------------------------===//

#ifndef LLVM_PASS_SUPPORT_H
#define LLVM_PASS_SUPPORT_H

// No need to include Pass.h, we are being included by it!

class TargetData;
class TargetMachine;

//===---------------------------------------------------------------------------
// PassInfo class - An instance of this class exists for every pass known by the
// system, and can be obtained from a live Pass by calling its getPassInfo()
// method.  These objects are set up by the RegisterPass<> template, defined
// below.
//
class PassInfo {
  const char           *PassName;      // Nice name for Pass
  const char           *PassArgument;  // Command Line argument to run this pass
  const std::type_info &TypeInfo;      // type_info object for this Pass class
  unsigned char PassType;              // Set of enums values below...

  Pass *(*NormalCtor)();               // No argument ctor
  Pass *(*DataCtor)(const TargetData&);// Ctor taking TargetData object...

public:
  // PassType - Define symbolic constants that can be used to test to see if
  // this pass should be listed by analyze or opt.  Passes can use none, one or
  // many of these flags or'd together.  It is not legal to combine the
  // AnalysisGroup flag with others.
  //
  enum {
    Analysis = 1, Optimization = 2, LLC = 4, AnalysisGroup = 8
  };

  // PassInfo ctor - Do not call this directly, this should only be invoked
  // through RegisterPass.
  PassInfo(const char *name, const char *arg, const std::type_info &ti, 
           unsigned pt, Pass *(*normal)(), Pass *(*data)(const TargetData &))
    : PassName(name), PassArgument(arg), TypeInfo(ti), PassType(pt),
      NormalCtor(normal), DataCtor(data) {
  }

  // getPassName - Return the friendly name for the pass, never returns null
  const char *getPassName() const { return PassName; }
  void setPassName(const char *Name) { PassName = Name; }

  // getPassArgument - Return the command line option that may be passed to
  // 'opt' that will cause this pass to be run.  This will return null if there
  // is no argument.
  //
  const char *getPassArgument() const { return PassArgument; }

  // getTypeInfo - Return the type_info object for the pass...
  const std::type_info &getTypeInfo() const { return TypeInfo; }

  // getPassType - Return the PassType of a pass.  Note that this can be several
  // different types or'd together.  This is _strictly_ for use by opt, analyze
  // and llc for deciding which passes to use as command line options.
  //
  unsigned getPassType() const { return PassType; }

  // getNormalCtor - Return a pointer to a function, that when called, creates
  // an instance of the pass and returns it.  This pointer may be null if there
  // is no default constructor for the pass.
  
  Pass *(*getNormalCtor() const)() {
    return NormalCtor;
  }
  void setNormalCtor(Pass *(*Ctor)()) {
    NormalCtor = Ctor;
  }

  // createPass() - Use this 
  Pass *createPass() const {
    assert((PassType != AnalysisGroup || NormalCtor) &&
           "No default implementation found for analysis group!");
    assert(NormalCtor &&
           "Cannot call createPass on PassInfo without default ctor!");
    return NormalCtor();
  }

  // getDataCtor - Return a pointer to a function that creates an instance of
  // the pass and returns it.  This returns a constructor for a version of the
  // pass that takes a TArgetData object as a parameter.
  //
  Pass *(*getDataCtor() const)(const TargetData &) {
    return DataCtor;
  }
};


//===---------------------------------------------------------------------------
// RegisterPass<t> template - This template class is used to notify the system
// that a Pass is available for use, and registers it into the internal database
// maintained by the PassManager.  Unless this template is used, opt, for
// example will not be able to see the pass and attempts to create the pass will
// fail. This template is used in the follow manner (at global scope, in your
// .cpp file):
// 
// static RegisterPass<YourPassClassName> tmp("passopt", "My Pass Name");
//
// This statement will cause your pass to be created by calling the default
// constructor exposed by the pass.  If you have a different constructor that
// must be called, create a global constructor function (which takes the
// arguments you need and returns a Pass*) and register your pass like this:
//
// Pass *createMyPass(foo &opt) { return new MyPass(opt); }
// static RegisterPass<PassClassName> tmp("passopt", "My Name", createMyPass);
// 
struct RegisterPassBase {
  // getPassInfo - Get the pass info for the registered class...
  const PassInfo *getPassInfo() const { return PIObj; }

  RegisterPassBase() : PIObj(0) {}
  ~RegisterPassBase() {   // Intentionally non-virtual...
    if (PIObj) unregisterPass(PIObj);
  }

protected:
  PassInfo *PIObj;       // The PassInfo object for this pass
  void registerPass(PassInfo *);
  void unregisterPass(PassInfo *);

  // setPreservesCFG - Notice that this pass only depends on the CFG, so
  // transformations that do not modify the CFG do not invalidate this pass.
  //
  void setPreservesCFG();
};

template<typename PassName>
Pass *callDefaultCtor() { return new PassName(); }

template<typename PassName>
struct RegisterPass : public RegisterPassBase {
  
  // Register Pass using default constructor...
  RegisterPass(const char *PassArg, const char *Name, unsigned PassTy = 0) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName), PassTy,
                              callDefaultCtor<PassName>, 0));
  }

  // Register Pass using default constructor explicitly...
  RegisterPass(const char *PassArg, const char *Name, unsigned PassTy,
               Pass *(*ctor)()) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName), PassTy, ctor,0));
  }

  // Register Pass using TargetData constructor...
  RegisterPass(const char *PassArg, const char *Name, unsigned PassTy,
               Pass *(*datactor)(const TargetData &)) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName), PassTy,
                              0, datactor));
  }

  // Generic constructor version that has an unknown ctor type...
  template<typename CtorType>
  RegisterPass(const char *PassArg, const char *Name, unsigned PassTy,
               CtorType *Fn) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName), PassTy, 0, 0));
  }
};

// RegisterOpt - Register something that is to show up in Opt, this is just a
// shortcut for specifying RegisterPass...
//
template<typename PassName>
struct RegisterOpt : public RegisterPassBase {
  RegisterOpt(const char *PassArg, const char *Name) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::Optimization,
                              callDefaultCtor<PassName>, 0));
  }

  // Register Pass using default constructor explicitly...
  RegisterOpt(const char *PassArg, const char *Name, Pass *(*ctor)()) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::Optimization, ctor, 0));
  }

  // Register Pass using TargetData constructor...
  RegisterOpt(const char *PassArg, const char *Name,
               Pass *(*datactor)(const TargetData &)) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::Optimization, 0, datactor));
  }
};

// RegisterAnalysis - Register something that is to show up in Analysis, this is
// just a shortcut for specifying RegisterPass...  Analyses take a special
// argument that, when set to true, tells the system that the analysis ONLY
// depends on the shape of the CFG, so if a transformation preserves the CFG
// that the analysis is not invalidated.
//
template<typename PassName>
struct RegisterAnalysis : public RegisterPassBase {
  RegisterAnalysis(const char *PassArg, const char *Name,
                   bool CFGOnly = false) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::Analysis,
                              callDefaultCtor<PassName>, 0));
    if (CFGOnly)
      setPreservesCFG();
  }
};

// RegisterLLC - Register something that is to show up in LLC, this is just a
// shortcut for specifying RegisterPass...
//
template<typename PassName>
struct RegisterLLC : public RegisterPassBase {
  RegisterLLC(const char *PassArg, const char *Name) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::LLC,
                              callDefaultCtor<PassName>, 0));
  }

  // Register Pass using default constructor explicitly...
  RegisterLLC(const char *PassArg, const char *Name, Pass *(*ctor)()) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::LLC, ctor, 0));
  }

  // Register Pass using TargetData constructor...
  RegisterLLC(const char *PassArg, const char *Name,
               Pass *(*datactor)(const TargetData &)) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::LLC, 0, datactor));
  }

  // Register Pass using TargetMachine constructor...
  RegisterLLC(const char *PassArg, const char *Name,
               Pass *(*datactor)(TargetMachine &)) {
    registerPass(new PassInfo(Name, PassArg, typeid(PassName),
                              PassInfo::LLC, 0, 0));
  }
};


// RegisterAnalysisGroup - Register a Pass as a member of an analysis _group_.
// Analysis groups are used to define an interface (which need not derive from
// Pass) that is required by passes to do their job.  Analysis Groups differ
// from normal analyses because any available implementation of the group will
// be used if it is available.
//
// If no analysis implementing the interface is available, a default
// implementation is created and added.  A pass registers itself as the default
// implementation by specifying 'true' as the third template argument of this
// class.
//
// In addition to registering itself as an analysis group member, a pass must
// register itself normally as well.  Passes may be members of multiple groups
// and may still be "required" specifically by name.
//
// The actual interface may also be registered as well (by not specifying the
// second template argument).  The interface should be registered to associate a
// nice name with the interface.
//
class RegisterAGBase : public RegisterPassBase {
  PassInfo *InterfaceInfo;
  const PassInfo *ImplementationInfo;
  bool isDefaultImplementation;
protected:
  RegisterAGBase(const std::type_info &Interface,
                 const std::type_info *Pass = 0,
                 bool isDefault = false);
  void setGroupName(const char *Name);
public:
  ~RegisterAGBase();
};


template<typename Interface, typename DefaultImplementationPass = void,
         bool Default = false>
struct RegisterAnalysisGroup : public RegisterAGBase {
  RegisterAnalysisGroup() : RegisterAGBase(typeid(Interface),
                                           &typeid(DefaultImplementationPass),
                                           Default) {
  }
};

// Define a specialization of RegisterAnalysisGroup that is used to set the name
// for the analysis group.
//
template<typename Interface>
struct RegisterAnalysisGroup<Interface, void, false> : public RegisterAGBase {
  RegisterAnalysisGroup(const char *Name)
    : RegisterAGBase(typeid(Interface)) {
    setGroupName(Name);
  }
};



//===---------------------------------------------------------------------------
// PassRegistrationListener class - This class is meant to be derived from by
// clients that are interested in which passes get registered and unregistered
// at runtime (which can be because of the RegisterPass constructors being run
// as the program starts up, or may be because a shared object just got loaded).
// Deriving from the PassRegistationListener class automatically registers your
// object to receive callbacks indicating when passes are loaded and removed.
//
struct PassRegistrationListener {

  // PassRegistrationListener ctor - Add the current object to the list of
  // PassRegistrationListeners...
  PassRegistrationListener();

  // dtor - Remove object from list of listeners...
  virtual ~PassRegistrationListener();

  // Callback functions - These functions are invoked whenever a pass is loaded
  // or removed from the current executable.
  //
  virtual void passRegistered(const PassInfo *P) {}
  virtual void passUnregistered(const PassInfo *P) {}

  // enumeratePasses - Iterate over the registered passes, calling the
  // passEnumerate callback on each PassInfo object.
  //
  void enumeratePasses();

  // passEnumerate - Callback function invoked when someone calls
  // enumeratePasses on this PassRegistrationListener object.
  //
  virtual void passEnumerate(const PassInfo *P) {}
};


//===---------------------------------------------------------------------------
// IncludeFile class - This class is used as a hack to make sure that the
// implementation of a header file is included into a tool that uses the header.
// This is solely to overcome problems linking .a files and not getting the
// implementation of passes we need.
//
struct IncludeFile {
  IncludeFile(void *);
};
#endif