lib/Driver/OptTable.cpp - clang - Git at Google

 //===--- OptTable.cpp - Option Table Implementation ---------------------*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Driver/OptTable.h"
 #include "clang/Driver/Arg.h"
 #include "clang/Driver/ArgList.h"
 #include "clang/Driver/Option.h"
 #include "llvm/Support/raw_ostream.h"
 #include <algorithm>
 #include <cassert>
 #include <map>
 using namespace clang::driver;
 using namespace clang::driver::options;

 // Ordering on Info. The ordering is *almost* lexicographic, with two
 // exceptions. First, '\0' comes at the end of the alphabet instead of
 // the beginning (thus options preceed any other options which prefix
 // them). Second, for options with the same name, the less permissive
 // version should come first; a Flag option should preceed a Joined
 // option, for example.

 static int StrCmpOptionName(const char *A, const char *B) {
   char a = *A, b = *B;
   while (a == b) {
     if (a == '\0')
       return 0;

     a = *++A;
     b = *++B;
   }

   if (a == '\0') // A is a prefix of B.
     return 1;
   if (b == '\0') // B is a prefix of A.
     return -1;

   // Otherwise lexicographic.
   return (a < b) ? -1 : 1;
 }

 namespace clang {
 namespace driver {
 static inline bool operator<(const OptTable::Info &A, const OptTable::Info &B) {
   if (&A == &B)
     return false;

   if (int N = StrCmpOptionName(A.Name, B.Name))
     return N == -1;

   // Names are the same, check that classes are in order; exactly one
   // should be joined, and it should succeed the other.
   assert(((A.Kind == Option::JoinedClass) ^ (B.Kind == Option::JoinedClass)) &&
          "Unexpected classes for options with same name.");
   return B.Kind == Option::JoinedClass;
 }

 // Support lower_bound between info and an option name.
 static inline bool operator<(const OptTable::Info &I, const char *Name) {
   return StrCmpOptionName(I.Name, Name) == -1;
 }
 static inline bool operator<(const char *Name, const OptTable::Info &I) {
   return StrCmpOptionName(Name, I.Name) == -1;
 }
 }
 }

 //

 OptSpecifier::OptSpecifier(const Option *Opt) : ID(Opt->getID()) {}

 //

 OptTable::OptTable(const Info *_OptionInfos, unsigned _NumOptionInfos)
   : OptionInfos(_OptionInfos), NumOptionInfos(_NumOptionInfos),
     Options(new Option*[NumOptionInfos]),
     TheInputOption(0), TheUnknownOption(0), FirstSearchableIndex(0)
 {
   // Explicitly zero initialize the error to work around a bug in array
   // value-initialization on MinGW with gcc 4.3.5.
   memset(Options, 0, sizeof(*Options) * NumOptionInfos);

   // Find start of normal options.
   for (unsigned i = 0, e = getNumOptions(); i != e; ++i) {
     unsigned Kind = getInfo(i + 1).Kind;
     if (Kind == Option::InputClass) {
       assert(!TheInputOption && "Cannot have multiple input options!");
       TheInputOption = getOption(i + 1);
     } else if (Kind == Option::UnknownClass) {
       assert(!TheUnknownOption && "Cannot have multiple input options!");
       TheUnknownOption = getOption(i + 1);
     } else if (Kind != Option::GroupClass) {
       FirstSearchableIndex = i;
       break;
     }
   }
   assert(FirstSearchableIndex != 0 && "No searchable options?");

 #ifndef NDEBUG
   // Check that everything after the first searchable option is a
   // regular option class.
   for (unsigned i = FirstSearchableIndex, e = getNumOptions(); i != e; ++i) {
     Option::OptionClass Kind = (Option::OptionClass) getInfo(i + 1).Kind;
     assert((Kind != Option::InputClass && Kind != Option::UnknownClass &&
             Kind != Option::GroupClass) &&
            "Special options should be defined first!");
   }

   // Check that options are in order.
   for (unsigned i = FirstSearchableIndex+1, e = getNumOptions(); i != e; ++i) {
     if (!(getInfo(i) < getInfo(i + 1))) {
       getOption(i)->dump();
       getOption(i + 1)->dump();
       assert(0 && "Options are not in order!");
     }
   }
 #endif
 }

 OptTable::~OptTable() {
   for (unsigned i = 0, e = getNumOptions(); i != e; ++i)
     delete Options[i];
   delete[] Options;
 }

 Option *OptTable::CreateOption(unsigned id) const {
   const Info &info = getInfo(id);
   const OptionGroup *Group =
     cast_or_null<OptionGroup>(getOption(info.GroupID));
   const Option *Alias = getOption(info.AliasID);

   Option *Opt = 0;
   switch (info.Kind) {
   case Option::InputClass:
     Opt = new InputOption(id); break;
   case Option::UnknownClass:
     Opt = new UnknownOption(id); break;
   case Option::GroupClass:
     Opt = new OptionGroup(id, info.Name, Group); break;
   case Option::FlagClass:
     Opt = new FlagOption(id, info.Name, Group, Alias); break;
   case Option::JoinedClass:
     Opt = new JoinedOption(id, info.Name, Group, Alias); break;
   case Option::SeparateClass:
     Opt = new SeparateOption(id, info.Name, Group, Alias); break;
   case Option::CommaJoinedClass:
     Opt = new CommaJoinedOption(id, info.Name, Group, Alias); break;
   case Option::MultiArgClass:
     Opt = new MultiArgOption(id, info.Name, Group, Alias, info.Param); break;
   case Option::JoinedOrSeparateClass:
     Opt = new JoinedOrSeparateOption(id, info.Name, Group, Alias); break;
   case Option::JoinedAndSeparateClass:
     Opt = new JoinedAndSeparateOption(id, info.Name, Group, Alias); break;
   }

   if (info.Flags & DriverOption)
     Opt->setDriverOption(true);
   if (info.Flags & LinkerInput)
     Opt->setLinkerInput(true);
   if (info.Flags & NoArgumentUnused)
     Opt->setNoArgumentUnused(true);
   if (info.Flags & RenderAsInput)
     Opt->setNoOptAsInput(true);
   if (info.Flags & RenderJoined) {
     assert(info.Kind == Option::SeparateClass && "Invalid option.");
     Opt->setForceJoinedRender(true);
   }
   if (info.Flags & RenderSeparate) {
     assert(info.Kind == Option::JoinedClass && "Invalid option.");
     Opt->setForceSeparateRender(true);
   }
   if (info.Flags & Unsupported)
     Opt->setUnsupported(true);

   return Opt;
 }

 Arg *OptTable::ParseOneArg(const InputArgList &Args, unsigned &Index) const {
   unsigned Prev = Index;
   const char *Str = Args.getArgString(Index);

   // Anything that doesn't start with '-' is an input, as is '-' itself.
   if (Str[0] != '-' || Str[1] == '\0')
     return new PositionalArg(TheInputOption, Index++);

   const Info *Start = OptionInfos + FirstSearchableIndex;
   const Info *End = OptionInfos + getNumOptions();

   // Search for the first next option which could be a prefix.
   Start = std::lower_bound(Start, End, Str);

   // Options are stored in sorted order, with '\0' at the end of the
   // alphabet. Since the only options which can accept a string must
   // prefix it, we iteratively search for the next option which could
   // be a prefix.
   //
   // FIXME: This is searching much more than necessary, but I am
   // blanking on the simplest way to make it fast. We can solve this
   // problem when we move to TableGen.
   for (; Start != End; ++Start) {
     // Scan for first option which is a proper prefix.
     for (; Start != End; ++Start)
       if (memcmp(Str, Start->Name, strlen(Start->Name)) == 0)
         break;
     if (Start == End)
       break;

     // See if this option matches.
     if (Arg *A = getOption(Start - OptionInfos + 1)->accept(Args, Index))
       return A;

     // Otherwise, see if this argument was missing values.
     if (Prev != Index)
       return 0;
   }

   return new PositionalArg(TheUnknownOption, Index++);
 }

 InputArgList *OptTable::ParseArgs(const char **ArgBegin, const char **ArgEnd,
                                   unsigned &MissingArgIndex,
                                   unsigned &MissingArgCount) const {
   InputArgList *Args = new InputArgList(ArgBegin, ArgEnd);

   // FIXME: Handle '@' args (or at least error on them).

   MissingArgIndex = MissingArgCount = 0;
   unsigned Index = 0, End = ArgEnd - ArgBegin;
   while (Index < End) {
     // Ignore empty arguments (other things may still take them as arguments).
     if (Args->getArgString(Index)[0] == '\0') {
       ++Index;
       continue;
     }

     unsigned Prev = Index;
     Arg *A = ParseOneArg(*Args, Index);
     assert(Index > Prev && "Parser failed to consume argument.");

     // Check for missing argument error.
     if (!A) {
       assert(Index >= End && "Unexpected parser error.");
       assert(Index - Prev - 1 && "No missing arguments!");
       MissingArgIndex = Prev;
       MissingArgCount = Index - Prev - 1;
       break;
     }

     Args->append(A);
   }

   return Args;
 }

 static std::string getOptionHelpName(const OptTable &Opts, OptSpecifier Id) {
   std::string Name = Opts.getOptionName(Id);

   // Add metavar, if used.
   switch (Opts.getOptionKind(Id)) {
   case Option::GroupClass: case Option::InputClass: case Option::UnknownClass:
     assert(0 && "Invalid option with help text.");

   case Option::MultiArgClass: case Option::JoinedAndSeparateClass:
     assert(0 && "Cannot print metavar for this kind of option.");

   case Option::FlagClass:
     break;

   case Option::SeparateClass: case Option::JoinedOrSeparateClass:
     Name += ' ';
     // FALLTHROUGH
   case Option::JoinedClass: case Option::CommaJoinedClass:
     if (const char *MetaVarName = Opts.getOptionMetaVar(Id))
       Name += MetaVarName;
     else
       Name += "<value>";
     break;
   }

   return Name;
 }

 static void PrintHelpOptionList(llvm::raw_ostream &OS, llvm::StringRef Title,
                                 std::vector<std::pair<std::string,
                                 const char*> > &OptionHelp) {
   OS << Title << ":\n";

   // Find the maximum option length.
   unsigned OptionFieldWidth = 0;
   for (unsigned i = 0, e = OptionHelp.size(); i != e; ++i) {
     // Skip titles.
     if (!OptionHelp[i].second)
       continue;

     // Limit the amount of padding we are willing to give up for alignment.
     unsigned Length = OptionHelp[i].first.size();
     if (Length <= 23)
       OptionFieldWidth = std::max(OptionFieldWidth, Length);
   }

   const unsigned InitialPad = 2;
   for (unsigned i = 0, e = OptionHelp.size(); i != e; ++i) {
     const std::string &Option = OptionHelp[i].first;
     int Pad = OptionFieldWidth - int(Option.size());
     OS.indent(InitialPad) << Option;

     // Break on long option names.
     if (Pad < 0) {
       OS << "\n";
       Pad = OptionFieldWidth + InitialPad;
     }
     OS.indent(Pad + 1) << OptionHelp[i].second << '\n';
   }
 }

 static const char *getOptionHelpGroup(const OptTable &Opts, OptSpecifier Id) {
   unsigned GroupID = Opts.getOptionGroupID(Id);

   // If not in a group, return the default help group.
   if (!GroupID)
     return "OPTIONS";

   // Abuse the help text of the option groups to store the "help group"
   // name.
   //
   // FIXME: Split out option groups.
   if (const char *GroupHelp = Opts.getOptionHelpText(GroupID))
     return GroupHelp;

   // Otherwise keep looking.
   return getOptionHelpGroup(Opts, GroupID);
 }

 void OptTable::PrintHelp(llvm::raw_ostream &OS, const char *Name,
                          const char *Title, bool ShowHidden) const {
   OS << "OVERVIEW: " << Title << "\n";
   OS << '\n';
   OS << "USAGE: " << Name << " [options] <inputs>\n";
   OS << '\n';

   // Render help text into a map of group-name to a list of (option, help)
   // pairs.
   typedef std::map<std::string,
                  std::vector<std::pair<std::string, const char*> > > helpmap_ty;
   helpmap_ty GroupedOptionHelp;

   for (unsigned i = 0, e = getNumOptions(); i != e; ++i) {
     unsigned Id = i + 1;

     // FIXME: Split out option groups.
     if (getOptionKind(Id) == Option::GroupClass)
       continue;

     if (!ShowHidden && isOptionHelpHidden(Id))
       continue;

     if (const char *Text = getOptionHelpText(Id)) {
       const char *HelpGroup = getOptionHelpGroup(*this, Id);
       const std::string &OptName = getOptionHelpName(*this, Id);
       GroupedOptionHelp[HelpGroup].push_back(std::make_pair(OptName, Text));
     }
   }

   for (helpmap_ty::iterator it = GroupedOptionHelp .begin(),
          ie = GroupedOptionHelp.end(); it != ie; ++it) {
     if (it != GroupedOptionHelp .begin())
       OS << "\n";
     PrintHelpOptionList(OS, it->first, it->second);
   }

   OS.flush();
 }
	//===--- OptTable.cpp - Option Table Implementation ---------------------*-===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Driver/OptTable.h"
	#include "clang/Driver/Arg.h"
	#include "clang/Driver/ArgList.h"
	#include "clang/Driver/Option.h"
	#include "llvm/Support/raw_ostream.h"
	#include <algorithm>
	#include <cassert>
	#include <map>
	using namespace clang::driver;
	using namespace clang::driver::options;

	// Ordering on Info. The ordering is almost lexicographic, with two
	// exceptions. First, '\0' comes at the end of the alphabet instead of
	// the beginning (thus options preceed any other options which prefix
	// them). Second, for options with the same name, the less permissive
	// version should come first; a Flag option should preceed a Joined
	// option, for example.

	static int StrCmpOptionName(const char A, const char B) {
	char a = A, b = B;
	while (a == b) {
	if (a == '\0')
	return 0;

	a = *++A;
	b = *++B;
	}

	if (a == '\0') // A is a prefix of B.
	return 1;
	if (b == '\0') // B is a prefix of A.
	return -1;

	// Otherwise lexicographic.
	return (a < b) ? -1 : 1;
	}

	namespace clang {
	namespace driver {
	static inline bool operator<(const OptTable::Info &A, const OptTable::Info &B) {
	if (&A == &B)
	return false;

	if (int N = StrCmpOptionName(A.Name, B.Name))
	return N == -1;

	// Names are the same, check that classes are in order; exactly one
	// should be joined, and it should succeed the other.
	assert(((A.Kind == Option::JoinedClass) ^ (B.Kind == Option::JoinedClass)) &&
	"Unexpected classes for options with same name.");
	return B.Kind == Option::JoinedClass;
	}

	// Support lower_bound between info and an option name.
	static inline bool operator<(const OptTable::Info &I, const char *Name) {
	return StrCmpOptionName(I.Name, Name) == -1;
	}
	static inline bool operator<(const char *Name, const OptTable::Info &I) {
	return StrCmpOptionName(Name, I.Name) == -1;
	}
	}
	}

	//

	OptSpecifier::OptSpecifier(const Option *Opt) : ID(Opt->getID()) {}

	//

	OptTable::OptTable(const Info *_OptionInfos, unsigned _NumOptionInfos)
	: OptionInfos(_OptionInfos), NumOptionInfos(_NumOptionInfos),
	Options(new Option*[NumOptionInfos]),
	TheInputOption(0), TheUnknownOption(0), FirstSearchableIndex(0)
	{
	// Explicitly zero initialize the error to work around a bug in array
	// value-initialization on MinGW with gcc 4.3.5.
	memset(Options, 0, sizeof(Options) NumOptionInfos);

	// Find start of normal options.
	for (unsigned i = 0, e = getNumOptions(); i != e; ++i) {
	unsigned Kind = getInfo(i + 1).Kind;
	if (Kind == Option::InputClass) {
	assert(!TheInputOption && "Cannot have multiple input options!");
	TheInputOption = getOption(i + 1);
	} else if (Kind == Option::UnknownClass) {
	assert(!TheUnknownOption && "Cannot have multiple input options!");
	TheUnknownOption = getOption(i + 1);
	} else if (Kind != Option::GroupClass) {
	FirstSearchableIndex = i;
	break;
	}
	}
	assert(FirstSearchableIndex != 0 && "No searchable options?");

	#ifndef NDEBUG
	// Check that everything after the first searchable option is a
	// regular option class.
	for (unsigned i = FirstSearchableIndex, e = getNumOptions(); i != e; ++i) {
	Option::OptionClass Kind = (Option::OptionClass) getInfo(i + 1).Kind;
	assert((Kind != Option::InputClass && Kind != Option::UnknownClass &&
	Kind != Option::GroupClass) &&
	"Special options should be defined first!");
	}

	// Check that options are in order.
	for (unsigned i = FirstSearchableIndex+1, e = getNumOptions(); i != e; ++i) {
	if (!(getInfo(i) < getInfo(i + 1))) {
	getOption(i)->dump();
	getOption(i + 1)->dump();
	assert(0 && "Options are not in order!");
	}
	}
	#endif
	}

	OptTable::~OptTable() {
	for (unsigned i = 0, e = getNumOptions(); i != e; ++i)
	delete Options[i];
	delete[] Options;
	}

	Option *OptTable::CreateOption(unsigned id) const {
	const Info &info = getInfo(id);
	const OptionGroup *Group =
	cast_or_null<OptionGroup>(getOption(info.GroupID));
	const Option *Alias = getOption(info.AliasID);

	Option *Opt = 0;
	switch (info.Kind) {
	case Option::InputClass:
	Opt = new InputOption(id); break;
	case Option::UnknownClass:
	Opt = new UnknownOption(id); break;
	case Option::GroupClass:
	Opt = new OptionGroup(id, info.Name, Group); break;
	case Option::FlagClass:
	Opt = new FlagOption(id, info.Name, Group, Alias); break;
	case Option::JoinedClass:
	Opt = new JoinedOption(id, info.Name, Group, Alias); break;
	case Option::SeparateClass:
	Opt = new SeparateOption(id, info.Name, Group, Alias); break;
	case Option::CommaJoinedClass:
	Opt = new CommaJoinedOption(id, info.Name, Group, Alias); break;
	case Option::MultiArgClass:
	Opt = new MultiArgOption(id, info.Name, Group, Alias, info.Param); break;
	case Option::JoinedOrSeparateClass:
	Opt = new JoinedOrSeparateOption(id, info.Name, Group, Alias); break;
	case Option::JoinedAndSeparateClass:
	Opt = new JoinedAndSeparateOption(id, info.Name, Group, Alias); break;
	}

	if (info.Flags & DriverOption)
	Opt->setDriverOption(true);
	if (info.Flags & LinkerInput)
	Opt->setLinkerInput(true);
	if (info.Flags & NoArgumentUnused)
	Opt->setNoArgumentUnused(true);
	if (info.Flags & RenderAsInput)
	Opt->setNoOptAsInput(true);
	if (info.Flags & RenderJoined) {
	assert(info.Kind == Option::SeparateClass && "Invalid option.");
	Opt->setForceJoinedRender(true);
	}
	if (info.Flags & RenderSeparate) {
	assert(info.Kind == Option::JoinedClass && "Invalid option.");
	Opt->setForceSeparateRender(true);
	}
	if (info.Flags & Unsupported)
	Opt->setUnsupported(true);

	return Opt;
	}

	Arg *OptTable::ParseOneArg(const InputArgList &Args, unsigned &Index) const {
	unsigned Prev = Index;
	const char *Str = Args.getArgString(Index);

	// Anything that doesn't start with '-' is an input, as is '-' itself.
	if (Str[0] != '-' \|\| Str[1] == '\0')
	return new PositionalArg(TheInputOption, Index++);

	const Info *Start = OptionInfos + FirstSearchableIndex;
	const Info *End = OptionInfos + getNumOptions();

	// Search for the first next option which could be a prefix.
	Start = std::lower_bound(Start, End, Str);

	// Options are stored in sorted order, with '\0' at the end of the
	// alphabet. Since the only options which can accept a string must
	// prefix it, we iteratively search for the next option which could
	// be a prefix.
	//
	// FIXME: This is searching much more than necessary, but I am
	// blanking on the simplest way to make it fast. We can solve this
	// problem when we move to TableGen.
	for (; Start != End; ++Start) {
	// Scan for first option which is a proper prefix.
	for (; Start != End; ++Start)
	if (memcmp(Str, Start->Name, strlen(Start->Name)) == 0)
	break;
	if (Start == End)
	break;

	// See if this option matches.
	if (Arg *A = getOption(Start - OptionInfos + 1)->accept(Args, Index))
	return A;

	// Otherwise, see if this argument was missing values.
	if (Prev != Index)
	return 0;
	}

	return new PositionalArg(TheUnknownOption, Index++);
	}

	InputArgList OptTable::ParseArgs(const char ArgBegin, const char *ArgEnd,
	unsigned &MissingArgIndex,
	unsigned &MissingArgCount) const {
	InputArgList *Args = new InputArgList(ArgBegin, ArgEnd);

	// FIXME: Handle '@' args (or at least error on them).

	MissingArgIndex = MissingArgCount = 0;
	unsigned Index = 0, End = ArgEnd - ArgBegin;
	while (Index < End) {
	// Ignore empty arguments (other things may still take them as arguments).
	if (Args->getArgString(Index)[0] == '\0') {
	++Index;
	continue;
	}

	unsigned Prev = Index;
	Arg A = ParseOneArg(Args, Index);
	assert(Index > Prev && "Parser failed to consume argument.");

	// Check for missing argument error.
	if (!A) {
	assert(Index >= End && "Unexpected parser error.");
	assert(Index - Prev - 1 && "No missing arguments!");
	MissingArgIndex = Prev;
	MissingArgCount = Index - Prev - 1;
	break;
	}

	Args->append(A);
	}

	return Args;
	}

	static std::string getOptionHelpName(const OptTable &Opts, OptSpecifier Id) {
	std::string Name = Opts.getOptionName(Id);

	// Add metavar, if used.
	switch (Opts.getOptionKind(Id)) {
	case Option::GroupClass: case Option::InputClass: case Option::UnknownClass:
	assert(0 && "Invalid option with help text.");

	case Option::MultiArgClass: case Option::JoinedAndSeparateClass:
	assert(0 && "Cannot print metavar for this kind of option.");

	case Option::FlagClass:
	break;

	case Option::SeparateClass: case Option::JoinedOrSeparateClass:
	Name += ' ';
	// FALLTHROUGH
	case Option::JoinedClass: case Option::CommaJoinedClass:
	if (const char *MetaVarName = Opts.getOptionMetaVar(Id))
	Name += MetaVarName;
	else
	Name += "<value>";
	break;
	}

	return Name;
	}

	static void PrintHelpOptionList(llvm::raw_ostream &OS, llvm::StringRef Title,
	std::vector<std::pair<std::string,
	const char*> > &OptionHelp) {
	OS << Title << ":\n";

	// Find the maximum option length.
	unsigned OptionFieldWidth = 0;
	for (unsigned i = 0, e = OptionHelp.size(); i != e; ++i) {
	// Skip titles.
	if (!OptionHelp[i].second)
	continue;

	// Limit the amount of padding we are willing to give up for alignment.
	unsigned Length = OptionHelp[i].first.size();
	if (Length <= 23)
	OptionFieldWidth = std::max(OptionFieldWidth, Length);
	}

	const unsigned InitialPad = 2;
	for (unsigned i = 0, e = OptionHelp.size(); i != e; ++i) {
	const std::string &Option = OptionHelp[i].first;
	int Pad = OptionFieldWidth - int(Option.size());
	OS.indent(InitialPad) << Option;

	// Break on long option names.
	if (Pad < 0) {
	OS << "\n";
	Pad = OptionFieldWidth + InitialPad;
	}
	OS.indent(Pad + 1) << OptionHelp[i].second << '\n';
	}
	}

	static const char *getOptionHelpGroup(const OptTable &Opts, OptSpecifier Id) {
	unsigned GroupID = Opts.getOptionGroupID(Id);

	// If not in a group, return the default help group.
	if (!GroupID)
	return "OPTIONS";

	// Abuse the help text of the option groups to store the "help group"
	// name.
	//
	// FIXME: Split out option groups.
	if (const char *GroupHelp = Opts.getOptionHelpText(GroupID))
	return GroupHelp;

	// Otherwise keep looking.
	return getOptionHelpGroup(Opts, GroupID);
	}

	void OptTable::PrintHelp(llvm::raw_ostream &OS, const char *Name,
	const char *Title, bool ShowHidden) const {
	OS << "OVERVIEW: " << Title << "\n";
	OS << '\n';
	OS << "USAGE: " << Name << " [options] <inputs>\n";
	OS << '\n';

	// Render help text into a map of group-name to a list of (option, help)
	// pairs.
	typedef std::map<std::string,
	std::vector<std::pair<std::string, const char*> > > helpmap_ty;
	helpmap_ty GroupedOptionHelp;

	for (unsigned i = 0, e = getNumOptions(); i != e; ++i) {
	unsigned Id = i + 1;

	// FIXME: Split out option groups.
	if (getOptionKind(Id) == Option::GroupClass)
	continue;

	if (!ShowHidden && isOptionHelpHidden(Id))
	continue;

	if (const char *Text = getOptionHelpText(Id)) {
	const char HelpGroup = getOptionHelpGroup(this, Id);
	const std::string &OptName = getOptionHelpName(*this, Id);
	GroupedOptionHelp[HelpGroup].push_back(std::make_pair(OptName, Text));
	}
	}

	for (helpmap_ty::iterator it = GroupedOptionHelp .begin(),
	ie = GroupedOptionHelp.end(); it != ie; ++it) {
	if (it != GroupedOptionHelp .begin())
	OS << "\n";
	PrintHelpOptionList(OS, it->first, it->second);
	}

	OS.flush();
	}