llvm-6502/include/llvm/Support/CommandLine.h
Chandler Carruth 6d51d26a24 Add an extension point to the CommandLine library where clients can
register extra version information to be printed. This is designed to
allow those tools which link in various targets to also print those
registered targets under --version.

Currently this printing logic is embedded into the Support library
directly; a huge layering violation. This is the first step to hoisting
it out into the tools without adding lots of duplicated code.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@135755 91177308-0d34-0410-b5e6-96231b3b80d8
2011-07-22 07:50:40 +00:00

1666 lines
55 KiB
C++

//===- llvm/Support/CommandLine.h - Command line handler --------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This class implements a command line argument processor that is useful when
// creating a tool. It provides a simple, minimalistic interface that is easily
// extensible and supports nonlocal (library) command line options.
//
// Note that rather than trying to figure out what this code does, you should
// read the library documentation located in docs/CommandLine.html or looks at
// the many example usages in tools/*/*.cpp
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_SUPPORT_COMMANDLINE_H
#define LLVM_SUPPORT_COMMANDLINE_H
#include "llvm/Support/type_traits.h"
#include "llvm/Support/Compiler.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/Twine.h"
#include <cassert>
#include <climits>
#include <cstdarg>
#include <utility>
#include <vector>
namespace llvm {
/// cl Namespace - This namespace contains all of the command line option
/// processing machinery. It is intentionally a short name to make qualified
/// usage concise.
namespace cl {
//===----------------------------------------------------------------------===//
// ParseCommandLineOptions - Command line option processing entry point.
//
void ParseCommandLineOptions(int argc, char **argv,
const char *Overview = 0,
bool ReadResponseFiles = false);
//===----------------------------------------------------------------------===//
// ParseEnvironmentOptions - Environment variable option processing alternate
// entry point.
//
void ParseEnvironmentOptions(const char *progName, const char *envvar,
const char *Overview = 0,
bool ReadResponseFiles = false);
///===---------------------------------------------------------------------===//
/// SetVersionPrinter - Override the default (LLVM specific) version printer
/// used to print out the version when --version is given
/// on the command line. This allows other systems using the
/// CommandLine utilities to print their own version string.
void SetVersionPrinter(void (*func)());
///===---------------------------------------------------------------------===//
/// AddExtraVersionPrinter - Add an extra printer to use in addition to the
/// default one. This can be called multiple times,
/// and each time it adds a new function to the list
/// which will be called after the basic LLVM version
/// printing is complete. Each can then add additional
/// information specific to the tool.
void AddExtraVersionPrinter(void (*func)());
// PrintOptionValues - Print option values.
// With -print-options print the difference between option values and defaults.
// With -print-all-options print all option values.
// (Currently not perfect, but best-effort.)
void PrintOptionValues();
// MarkOptionsChanged - Internal helper function.
void MarkOptionsChanged();
//===----------------------------------------------------------------------===//
// Flags permitted to be passed to command line arguments
//
enum NumOccurrencesFlag { // Flags for the number of occurrences allowed
Optional = 0x01, // Zero or One occurrence
ZeroOrMore = 0x02, // Zero or more occurrences allowed
Required = 0x03, // One occurrence required
OneOrMore = 0x04, // One or more occurrences required
// ConsumeAfter - Indicates that this option is fed anything that follows the
// last positional argument required by the application (it is an error if
// there are zero positional arguments, and a ConsumeAfter option is used).
// Thus, for example, all arguments to LLI are processed until a filename is
// found. Once a filename is found, all of the succeeding arguments are
// passed, unprocessed, to the ConsumeAfter option.
//
ConsumeAfter = 0x05,
OccurrencesMask = 0x07
};
enum ValueExpected { // Is a value required for the option?
ValueOptional = 0x08, // The value can appear... or not
ValueRequired = 0x10, // The value is required to appear!
ValueDisallowed = 0x18, // A value may not be specified (for flags)
ValueMask = 0x18
};
enum OptionHidden { // Control whether -help shows this option
NotHidden = 0x20, // Option included in -help & -help-hidden
Hidden = 0x40, // -help doesn't, but -help-hidden does
ReallyHidden = 0x60, // Neither -help nor -help-hidden show this arg
HiddenMask = 0x60
};
// Formatting flags - This controls special features that the option might have
// that cause it to be parsed differently...
//
// Prefix - This option allows arguments that are otherwise unrecognized to be
// matched by options that are a prefix of the actual value. This is useful for
// cases like a linker, where options are typically of the form '-lfoo' or
// '-L../../include' where -l or -L are the actual flags. When prefix is
// enabled, and used, the value for the flag comes from the suffix of the
// argument.
//
// Grouping - With this option enabled, multiple letter options are allowed to
// bunch together with only a single hyphen for the whole group. This allows
// emulation of the behavior that ls uses for example: ls -la === ls -l -a
//
enum FormattingFlags {
NormalFormatting = 0x000, // Nothing special
Positional = 0x080, // Is a positional argument, no '-' required
Prefix = 0x100, // Can this option directly prefix its value?
Grouping = 0x180, // Can this option group with other options?
FormattingMask = 0x180 // Union of the above flags.
};
enum MiscFlags { // Miscellaneous flags to adjust argument
CommaSeparated = 0x200, // Should this cl::list split between commas?
PositionalEatsArgs = 0x400, // Should this positional cl::list eat -args?
Sink = 0x800, // Should this cl::list eat all unknown options?
MiscMask = 0xE00 // Union of the above flags.
};
//===----------------------------------------------------------------------===//
// Option Base class
//
class alias;
class Option {
friend class alias;
// handleOccurrences - Overriden by subclasses to handle the value passed into
// an argument. Should return true if there was an error processing the
// argument and the program should exit.
//
virtual bool handleOccurrence(unsigned pos, StringRef ArgName,
StringRef Arg) = 0;
virtual enum ValueExpected getValueExpectedFlagDefault() const {
return ValueOptional;
}
// Out of line virtual function to provide home for the class.
virtual void anchor();
int NumOccurrences; // The number of times specified
int Flags; // Flags for the argument
unsigned Position; // Position of last occurrence of the option
unsigned AdditionalVals;// Greater than 0 for multi-valued option.
Option *NextRegistered; // Singly linked list of registered options.
public:
const char *ArgStr; // The argument string itself (ex: "help", "o")
const char *HelpStr; // The descriptive text message for -help
const char *ValueStr; // String describing what the value of this option is
inline enum NumOccurrencesFlag getNumOccurrencesFlag() const {
return static_cast<enum NumOccurrencesFlag>(Flags & OccurrencesMask);
}
inline enum ValueExpected getValueExpectedFlag() const {
int VE = Flags & ValueMask;
return VE ? static_cast<enum ValueExpected>(VE)
: getValueExpectedFlagDefault();
}
inline enum OptionHidden getOptionHiddenFlag() const {
return static_cast<enum OptionHidden>(Flags & HiddenMask);
}
inline enum FormattingFlags getFormattingFlag() const {
return static_cast<enum FormattingFlags>(Flags & FormattingMask);
}
inline unsigned getMiscFlags() const {
return Flags & MiscMask;
}
inline unsigned getPosition() const { return Position; }
inline unsigned getNumAdditionalVals() const { return AdditionalVals; }
// hasArgStr - Return true if the argstr != ""
bool hasArgStr() const { return ArgStr[0] != 0; }
//-------------------------------------------------------------------------===
// Accessor functions set by OptionModifiers
//
void setArgStr(const char *S) { ArgStr = S; }
void setDescription(const char *S) { HelpStr = S; }
void setValueStr(const char *S) { ValueStr = S; }
void setFlag(unsigned Flag, unsigned FlagMask) {
Flags &= ~FlagMask;
Flags |= Flag;
}
void setNumOccurrencesFlag(enum NumOccurrencesFlag Val) {
setFlag(Val, OccurrencesMask);
}
void setValueExpectedFlag(enum ValueExpected Val) { setFlag(Val, ValueMask); }
void setHiddenFlag(enum OptionHidden Val) { setFlag(Val, HiddenMask); }
void setFormattingFlag(enum FormattingFlags V) { setFlag(V, FormattingMask); }
void setMiscFlag(enum MiscFlags M) { setFlag(M, M); }
void setPosition(unsigned pos) { Position = pos; }
protected:
explicit Option(unsigned DefaultFlags)
: NumOccurrences(0), Flags(DefaultFlags | NormalFormatting), Position(0),
AdditionalVals(0), NextRegistered(0),
ArgStr(""), HelpStr(""), ValueStr("") {
assert(getNumOccurrencesFlag() != 0 &&
getOptionHiddenFlag() != 0 && "Not all default flags specified!");
}
inline void setNumAdditionalVals(unsigned n) { AdditionalVals = n; }
public:
// addArgument - Register this argument with the commandline system.
//
void addArgument();
Option *getNextRegisteredOption() const { return NextRegistered; }
// Return the width of the option tag for printing...
virtual size_t getOptionWidth() const = 0;
// printOptionInfo - Print out information about this option. The
// to-be-maintained width is specified.
//
virtual void printOptionInfo(size_t GlobalWidth) const = 0;
virtual void printOptionValue(size_t GlobalWidth, bool Force) const = 0;
virtual void getExtraOptionNames(SmallVectorImpl<const char*> &) {}
// addOccurrence - Wrapper around handleOccurrence that enforces Flags.
//
bool addOccurrence(unsigned pos, StringRef ArgName,
StringRef Value, bool MultiArg = false);
// Prints option name followed by message. Always returns true.
bool error(const Twine &Message, StringRef ArgName = StringRef());
public:
inline int getNumOccurrences() const { return NumOccurrences; }
virtual ~Option() {}
};
//===----------------------------------------------------------------------===//
// Command line option modifiers that can be used to modify the behavior of
// command line option parsers...
//
// desc - Modifier to set the description shown in the -help output...
struct desc {
const char *Desc;
desc(const char *Str) : Desc(Str) {}
void apply(Option &O) const { O.setDescription(Desc); }
};
// value_desc - Modifier to set the value description shown in the -help
// output...
struct value_desc {
const char *Desc;
value_desc(const char *Str) : Desc(Str) {}
void apply(Option &O) const { O.setValueStr(Desc); }
};
// init - Specify a default (initial) value for the command line argument, if
// the default constructor for the argument type does not give you what you
// want. This is only valid on "opt" arguments, not on "list" arguments.
//
template<class Ty>
struct initializer {
const Ty &Init;
initializer(const Ty &Val) : Init(Val) {}
template<class Opt>
void apply(Opt &O) const { O.setInitialValue(Init); }
};
template<class Ty>
initializer<Ty> init(const Ty &Val) {
return initializer<Ty>(Val);
}
// location - Allow the user to specify which external variable they want to
// store the results of the command line argument processing into, if they don't
// want to store it in the option itself.
//
template<class Ty>
struct LocationClass {
Ty &Loc;
LocationClass(Ty &L) : Loc(L) {}
template<class Opt>
void apply(Opt &O) const { O.setLocation(O, Loc); }
};
template<class Ty>
LocationClass<Ty> location(Ty &L) { return LocationClass<Ty>(L); }
//===----------------------------------------------------------------------===//
// OptionValue class
// Support value comparison outside the template.
struct GenericOptionValue {
virtual ~GenericOptionValue() {}
virtual bool compare(const GenericOptionValue &V) const = 0;
};
template<class DataType> struct OptionValue;
// The default value safely does nothing. Option value printing is only
// best-effort.
template<class DataType, bool isClass>
struct OptionValueBase : public GenericOptionValue {
// Temporary storage for argument passing.
typedef OptionValue<DataType> WrapperType;
bool hasValue() const { return false; }
const DataType &getValue() const { assert(false && "no default value"); }
// Some options may take their value from a different data type.
template<class DT>
void setValue(const DT& /*V*/) {}
bool compare(const DataType &/*V*/) const { return false; }
virtual bool compare(const GenericOptionValue& /*V*/) const { return false; }
};
// Simple copy of the option value.
template<class DataType>
class OptionValueCopy : public GenericOptionValue {
DataType Value;
bool Valid;
public:
OptionValueCopy() : Valid(false) {}
bool hasValue() const { return Valid; }
const DataType &getValue() const {
assert(Valid && "invalid option value");
return Value;
}
void setValue(const DataType &V) { Valid = true; Value = V; }
bool compare(const DataType &V) const {
return Valid && (Value != V);
}
virtual bool compare(const GenericOptionValue &V) const {
const OptionValueCopy<DataType> &VC =
static_cast< const OptionValueCopy<DataType>& >(V);
if (!VC.hasValue()) return false;
return compare(VC.getValue());
}
};
// Non-class option values.
template<class DataType>
struct OptionValueBase<DataType, false> : OptionValueCopy<DataType> {
typedef DataType WrapperType;
};
// Top-level option class.
template<class DataType>
struct OptionValue : OptionValueBase<DataType, is_class<DataType>::value> {
OptionValue() {}
OptionValue(const DataType& V) {
this->setValue(V);
}
// Some options may take their value from a different data type.
template<class DT>
OptionValue<DataType> &operator=(const DT& V) {
this->setValue(V);
return *this;
}
};
// Other safe-to-copy-by-value common option types.
enum boolOrDefault { BOU_UNSET, BOU_TRUE, BOU_FALSE };
template<>
struct OptionValue<cl::boolOrDefault> : OptionValueCopy<cl::boolOrDefault> {
typedef cl::boolOrDefault WrapperType;
OptionValue() {}
OptionValue(const cl::boolOrDefault& V) {
this->setValue(V);
}
OptionValue<cl::boolOrDefault> &operator=(const cl::boolOrDefault& V) {
setValue(V);
return *this;
}
};
template<>
struct OptionValue<std::string> : OptionValueCopy<std::string> {
typedef StringRef WrapperType;
OptionValue() {}
OptionValue(const std::string& V) {
this->setValue(V);
}
OptionValue<std::string> &operator=(const std::string& V) {
setValue(V);
return *this;
}
};
//===----------------------------------------------------------------------===//
// Enum valued command line option
//
#define clEnumVal(ENUMVAL, DESC) #ENUMVAL, int(ENUMVAL), DESC
#define clEnumValN(ENUMVAL, FLAGNAME, DESC) FLAGNAME, int(ENUMVAL), DESC
#define clEnumValEnd (reinterpret_cast<void*>(0))
// values - For custom data types, allow specifying a group of values together
// as the values that go into the mapping that the option handler uses. Note
// that the values list must always have a 0 at the end of the list to indicate
// that the list has ended.
//
template<class DataType>
class ValuesClass {
// Use a vector instead of a map, because the lists should be short,
// the overhead is less, and most importantly, it keeps them in the order
// inserted so we can print our option out nicely.
SmallVector<std::pair<const char *, std::pair<int, const char *> >,4> Values;
void processValues(va_list Vals);
public:
ValuesClass(const char *EnumName, DataType Val, const char *Desc,
va_list ValueArgs) {
// Insert the first value, which is required.
Values.push_back(std::make_pair(EnumName, std::make_pair(Val, Desc)));
// Process the varargs portion of the values...
while (const char *enumName = va_arg(ValueArgs, const char *)) {
DataType EnumVal = static_cast<DataType>(va_arg(ValueArgs, int));
const char *EnumDesc = va_arg(ValueArgs, const char *);
Values.push_back(std::make_pair(enumName, // Add value to value map
std::make_pair(EnumVal, EnumDesc)));
}
}
template<class Opt>
void apply(Opt &O) const {
for (unsigned i = 0, e = static_cast<unsigned>(Values.size());
i != e; ++i)
O.getParser().addLiteralOption(Values[i].first, Values[i].second.first,
Values[i].second.second);
}
};
template<class DataType>
ValuesClass<DataType> END_WITH_NULL values(const char *Arg, DataType Val,
const char *Desc, ...) {
va_list ValueArgs;
va_start(ValueArgs, Desc);
ValuesClass<DataType> Vals(Arg, Val, Desc, ValueArgs);
va_end(ValueArgs);
return Vals;
}
//===----------------------------------------------------------------------===//
// parser class - Parameterizable parser for different data types. By default,
// known data types (string, int, bool) have specialized parsers, that do what
// you would expect. The default parser, used for data types that are not
// built-in, uses a mapping table to map specific options to values, which is
// used, among other things, to handle enum types.
//--------------------------------------------------
// generic_parser_base - This class holds all the non-generic code that we do
// not need replicated for every instance of the generic parser. This also
// allows us to put stuff into CommandLine.cpp
//
class generic_parser_base {
protected:
class GenericOptionInfo {
public:
GenericOptionInfo(const char *name, const char *helpStr) :
Name(name), HelpStr(helpStr) {}
const char *Name;
const char *HelpStr;
};
public:
virtual ~generic_parser_base() {} // Base class should have virtual-dtor
// getNumOptions - Virtual function implemented by generic subclass to
// indicate how many entries are in Values.
//
virtual unsigned getNumOptions() const = 0;
// getOption - Return option name N.
virtual const char *getOption(unsigned N) const = 0;
// getDescription - Return description N
virtual const char *getDescription(unsigned N) const = 0;
// Return the width of the option tag for printing...
virtual size_t getOptionWidth(const Option &O) const;
virtual const GenericOptionValue &getOptionValue(unsigned N) const = 0;
// printOptionInfo - Print out information about this option. The
// to-be-maintained width is specified.
//
virtual void printOptionInfo(const Option &O, size_t GlobalWidth) const;
void printGenericOptionDiff(const Option &O, const GenericOptionValue &V,
const GenericOptionValue &Default,
size_t GlobalWidth) const;
// printOptionDiff - print the value of an option and it's default.
//
// Template definition ensures that the option and default have the same
// DataType (via the same AnyOptionValue).
template<class AnyOptionValue>
void printOptionDiff(const Option &O, const AnyOptionValue &V,
const AnyOptionValue &Default,
size_t GlobalWidth) const {
printGenericOptionDiff(O, V, Default, GlobalWidth);
}
void initialize(Option &O) {
// All of the modifiers for the option have been processed by now, so the
// argstr field should be stable, copy it down now.
//
hasArgStr = O.hasArgStr();
}
void getExtraOptionNames(SmallVectorImpl<const char*> &OptionNames) {
// If there has been no argstr specified, that means that we need to add an
// argument for every possible option. This ensures that our options are
// vectored to us.
if (!hasArgStr)
for (unsigned i = 0, e = getNumOptions(); i != e; ++i)
OptionNames.push_back(getOption(i));
}
enum ValueExpected getValueExpectedFlagDefault() const {
// If there is an ArgStr specified, then we are of the form:
//
// -opt=O2 or -opt O2 or -optO2
//
// In which case, the value is required. Otherwise if an arg str has not
// been specified, we are of the form:
//
// -O2 or O2 or -la (where -l and -a are separate options)
//
// If this is the case, we cannot allow a value.
//
if (hasArgStr)
return ValueRequired;
else
return ValueDisallowed;
}
// findOption - Return the option number corresponding to the specified
// argument string. If the option is not found, getNumOptions() is returned.
//
unsigned findOption(const char *Name);
protected:
bool hasArgStr;
};
// Default parser implementation - This implementation depends on having a
// mapping of recognized options to values of some sort. In addition to this,
// each entry in the mapping also tracks a help message that is printed with the
// command line option for -help. Because this is a simple mapping parser, the
// data type can be any unsupported type.
//
template <class DataType>
class parser : public generic_parser_base {
protected:
class OptionInfo : public GenericOptionInfo {
public:
OptionInfo(const char *name, DataType v, const char *helpStr) :
GenericOptionInfo(name, helpStr), V(v) {}
OptionValue<DataType> V;
};
SmallVector<OptionInfo, 8> Values;
public:
typedef DataType parser_data_type;
// Implement virtual functions needed by generic_parser_base
unsigned getNumOptions() const { return unsigned(Values.size()); }
const char *getOption(unsigned N) const { return Values[N].Name; }
const char *getDescription(unsigned N) const {
return Values[N].HelpStr;
}
// getOptionValue - Return the value of option name N.
virtual const GenericOptionValue &getOptionValue(unsigned N) const {
return Values[N].V;
}
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, DataType &V) {
StringRef ArgVal;
if (hasArgStr)
ArgVal = Arg;
else
ArgVal = ArgName;
for (unsigned i = 0, e = static_cast<unsigned>(Values.size());
i != e; ++i)
if (Values[i].Name == ArgVal) {
V = Values[i].V.getValue();
return false;
}
return O.error("Cannot find option named '" + ArgVal + "'!");
}
/// addLiteralOption - Add an entry to the mapping table.
///
template <class DT>
void addLiteralOption(const char *Name, const DT &V, const char *HelpStr) {
assert(findOption(Name) == Values.size() && "Option already exists!");
OptionInfo X(Name, static_cast<DataType>(V), HelpStr);
Values.push_back(X);
MarkOptionsChanged();
}
/// removeLiteralOption - Remove the specified option.
///
void removeLiteralOption(const char *Name) {
unsigned N = findOption(Name);
assert(N != Values.size() && "Option not found!");
Values.erase(Values.begin()+N);
}
};
//--------------------------------------------------
// basic_parser - Super class of parsers to provide boilerplate code
//
class basic_parser_impl { // non-template implementation of basic_parser<t>
public:
virtual ~basic_parser_impl() {}
enum ValueExpected getValueExpectedFlagDefault() const {
return ValueRequired;
}
void getExtraOptionNames(SmallVectorImpl<const char*> &) {}
void initialize(Option &) {}
// Return the width of the option tag for printing...
size_t getOptionWidth(const Option &O) const;
// printOptionInfo - Print out information about this option. The
// to-be-maintained width is specified.
//
void printOptionInfo(const Option &O, size_t GlobalWidth) const;
// printOptionNoValue - Print a placeholder for options that don't yet support
// printOptionDiff().
void printOptionNoValue(const Option &O, size_t GlobalWidth) const;
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "value"; }
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
protected:
// A helper for basic_parser::printOptionDiff.
void printOptionName(const Option &O, size_t GlobalWidth) const;
};
// basic_parser - The real basic parser is just a template wrapper that provides
// a typedef for the provided data type.
//
template<class DataType>
class basic_parser : public basic_parser_impl {
public:
typedef DataType parser_data_type;
typedef OptionValue<DataType> OptVal;
};
//--------------------------------------------------
// parser<bool>
//
template<>
class parser<bool> : public basic_parser<bool> {
const char *ArgStr;
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, bool &Val);
template <class Opt>
void initialize(Opt &O) {
ArgStr = O.ArgStr;
}
enum ValueExpected getValueExpectedFlagDefault() const {
return ValueOptional;
}
// getValueName - Do not print =<value> at all.
virtual const char *getValueName() const { return 0; }
void printOptionDiff(const Option &O, bool V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<bool>);
//--------------------------------------------------
// parser<boolOrDefault>
template<>
class parser<boolOrDefault> : public basic_parser<boolOrDefault> {
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, boolOrDefault &Val);
enum ValueExpected getValueExpectedFlagDefault() const {
return ValueOptional;
}
// getValueName - Do not print =<value> at all.
virtual const char *getValueName() const { return 0; }
void printOptionDiff(const Option &O, boolOrDefault V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<boolOrDefault>);
//--------------------------------------------------
// parser<int>
//
template<>
class parser<int> : public basic_parser<int> {
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, int &Val);
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "int"; }
void printOptionDiff(const Option &O, int V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<int>);
//--------------------------------------------------
// parser<unsigned>
//
template<>
class parser<unsigned> : public basic_parser<unsigned> {
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, unsigned &Val);
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "uint"; }
void printOptionDiff(const Option &O, unsigned V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<unsigned>);
//--------------------------------------------------
// parser<double>
//
template<>
class parser<double> : public basic_parser<double> {
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, double &Val);
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "number"; }
void printOptionDiff(const Option &O, double V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<double>);
//--------------------------------------------------
// parser<float>
//
template<>
class parser<float> : public basic_parser<float> {
public:
// parse - Return true on error.
bool parse(Option &O, StringRef ArgName, StringRef Arg, float &Val);
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "number"; }
void printOptionDiff(const Option &O, float V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<float>);
//--------------------------------------------------
// parser<std::string>
//
template<>
class parser<std::string> : public basic_parser<std::string> {
public:
// parse - Return true on error.
bool parse(Option &, StringRef, StringRef Arg, std::string &Value) {
Value = Arg.str();
return false;
}
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "string"; }
void printOptionDiff(const Option &O, StringRef V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<std::string>);
//--------------------------------------------------
// parser<char>
//
template<>
class parser<char> : public basic_parser<char> {
public:
// parse - Return true on error.
bool parse(Option &, StringRef, StringRef Arg, char &Value) {
Value = Arg[0];
return false;
}
// getValueName - Overload in subclass to provide a better default value.
virtual const char *getValueName() const { return "char"; }
void printOptionDiff(const Option &O, char V, OptVal Default,
size_t GlobalWidth) const;
// An out-of-line virtual method to provide a 'home' for this class.
virtual void anchor();
};
EXTERN_TEMPLATE_INSTANTIATION(class basic_parser<char>);
//--------------------------------------------------
// PrintOptionDiff
//
// This collection of wrappers is the intermediary between class opt and class
// parser to handle all the template nastiness.
// This overloaded function is selected by the generic parser.
template<class ParserClass, class DT>
void printOptionDiff(const Option &O, const generic_parser_base &P, const DT &V,
const OptionValue<DT> &Default, size_t GlobalWidth) {
OptionValue<DT> OV = V;
P.printOptionDiff(O, OV, Default, GlobalWidth);
}
// This is instantiated for basic parsers when the parsed value has a different
// type than the option value. e.g. HelpPrinter.
template<class ParserDT, class ValDT>
struct OptionDiffPrinter {
void print(const Option &O, const parser<ParserDT> P, const ValDT &/*V*/,
const OptionValue<ValDT> &/*Default*/, size_t GlobalWidth) {
P.printOptionNoValue(O, GlobalWidth);
}
};
// This is instantiated for basic parsers when the parsed value has the same
// type as the option value.
template<class DT>
struct OptionDiffPrinter<DT, DT> {
void print(const Option &O, const parser<DT> P, const DT &V,
const OptionValue<DT> &Default, size_t GlobalWidth) {
P.printOptionDiff(O, V, Default, GlobalWidth);
}
};
// This overloaded function is selected by the basic parser, which may parse a
// different type than the option type.
template<class ParserClass, class ValDT>
void printOptionDiff(
const Option &O,
const basic_parser<typename ParserClass::parser_data_type> &P,
const ValDT &V, const OptionValue<ValDT> &Default,
size_t GlobalWidth) {
OptionDiffPrinter<typename ParserClass::parser_data_type, ValDT> printer;
printer.print(O, static_cast<const ParserClass&>(P), V, Default,
GlobalWidth);
}
//===----------------------------------------------------------------------===//
// applicator class - This class is used because we must use partial
// specialization to handle literal string arguments specially (const char* does
// not correctly respond to the apply method). Because the syntax to use this
// is a pain, we have the 'apply' method below to handle the nastiness...
//
template<class Mod> struct applicator {
template<class Opt>
static void opt(const Mod &M, Opt &O) { M.apply(O); }
};
// Handle const char* as a special case...
template<unsigned n> struct applicator<char[n]> {
template<class Opt>
static void opt(const char *Str, Opt &O) { O.setArgStr(Str); }
};
template<unsigned n> struct applicator<const char[n]> {
template<class Opt>
static void opt(const char *Str, Opt &O) { O.setArgStr(Str); }
};
template<> struct applicator<const char*> {
template<class Opt>
static void opt(const char *Str, Opt &O) { O.setArgStr(Str); }
};
template<> struct applicator<NumOccurrencesFlag> {
static void opt(NumOccurrencesFlag NO, Option &O) {
O.setNumOccurrencesFlag(NO);
}
};
template<> struct applicator<ValueExpected> {
static void opt(ValueExpected VE, Option &O) { O.setValueExpectedFlag(VE); }
};
template<> struct applicator<OptionHidden> {
static void opt(OptionHidden OH, Option &O) { O.setHiddenFlag(OH); }
};
template<> struct applicator<FormattingFlags> {
static void opt(FormattingFlags FF, Option &O) { O.setFormattingFlag(FF); }
};
template<> struct applicator<MiscFlags> {
static void opt(MiscFlags MF, Option &O) { O.setMiscFlag(MF); }
};
// apply method - Apply a modifier to an option in a type safe way.
template<class Mod, class Opt>
void apply(const Mod &M, Opt *O) {
applicator<Mod>::opt(M, *O);
}
//===----------------------------------------------------------------------===//
// opt_storage class
// Default storage class definition: external storage. This implementation
// assumes the user will specify a variable to store the data into with the
// cl::location(x) modifier.
//
template<class DataType, bool ExternalStorage, bool isClass>
class opt_storage {
DataType *Location; // Where to store the object...
OptionValue<DataType> Default;
void check() const {
assert(Location != 0 && "cl::location(...) not specified for a command "
"line option with external storage, "
"or cl::init specified before cl::location()!!");
}
public:
opt_storage() : Location(0) {}
bool setLocation(Option &O, DataType &L) {
if (Location)
return O.error("cl::location(x) specified more than once!");
Location = &L;
Default = L;
return false;
}
template<class T>
void setValue(const T &V, bool initial = false) {
check();
*Location = V;
if (initial)
Default = V;
}
DataType &getValue() { check(); return *Location; }
const DataType &getValue() const { check(); return *Location; }
operator DataType() const { return this->getValue(); }
const OptionValue<DataType> &getDefault() const { return Default; }
};
// Define how to hold a class type object, such as a string. Since we can
// inherit from a class, we do so. This makes us exactly compatible with the
// object in all cases that it is used.
//
template<class DataType>
class opt_storage<DataType,false,true> : public DataType {
public:
OptionValue<DataType> Default;
template<class T>
void setValue(const T &V, bool initial = false) {
DataType::operator=(V);
if (initial)
Default = V;
}
DataType &getValue() { return *this; }
const DataType &getValue() const { return *this; }
const OptionValue<DataType> &getDefault() const { return Default; }
};
// Define a partial specialization to handle things we cannot inherit from. In
// this case, we store an instance through containment, and overload operators
// to get at the value.
//
template<class DataType>
class opt_storage<DataType, false, false> {
public:
DataType Value;
OptionValue<DataType> Default;
// Make sure we initialize the value with the default constructor for the
// type.
opt_storage() : Value(DataType()) {}
template<class T>
void setValue(const T &V, bool initial = false) {
Value = V;
if (initial)
Default = V;
}
DataType &getValue() { return Value; }
DataType getValue() const { return Value; }
const OptionValue<DataType> &getDefault() const { return Default; }
operator DataType() const { return getValue(); }
// If the datatype is a pointer, support -> on it.
DataType operator->() const { return Value; }
};
//===----------------------------------------------------------------------===//
// opt - A scalar command line option.
//
template <class DataType, bool ExternalStorage = false,
class ParserClass = parser<DataType> >
class opt : public Option,
public opt_storage<DataType, ExternalStorage,
is_class<DataType>::value> {
ParserClass Parser;
virtual bool handleOccurrence(unsigned pos, StringRef ArgName,
StringRef Arg) {
typename ParserClass::parser_data_type Val =
typename ParserClass::parser_data_type();
if (Parser.parse(*this, ArgName, Arg, Val))
return true; // Parse error!
this->setValue(Val);
this->setPosition(pos);
return false;
}
virtual enum ValueExpected getValueExpectedFlagDefault() const {
return Parser.getValueExpectedFlagDefault();
}
virtual void getExtraOptionNames(SmallVectorImpl<const char*> &OptionNames) {
return Parser.getExtraOptionNames(OptionNames);
}
// Forward printing stuff to the parser...
virtual size_t getOptionWidth() const {return Parser.getOptionWidth(*this);}
virtual void printOptionInfo(size_t GlobalWidth) const {
Parser.printOptionInfo(*this, GlobalWidth);
}
virtual void printOptionValue(size_t GlobalWidth, bool Force) const {
if (Force || this->getDefault().compare(this->getValue())) {
cl::printOptionDiff<ParserClass>(
*this, Parser, this->getValue(), this->getDefault(), GlobalWidth);
}
}
void done() {
addArgument();
Parser.initialize(*this);
}
public:
// setInitialValue - Used by the cl::init modifier...
void setInitialValue(const DataType &V) { this->setValue(V, true); }
ParserClass &getParser() { return Parser; }
template<class T>
DataType &operator=(const T &Val) {
this->setValue(Val);
return this->getValue();
}
// One option...
template<class M0t>
explicit opt(const M0t &M0) : Option(Optional | NotHidden) {
apply(M0, this);
done();
}
// Two options...
template<class M0t, class M1t>
opt(const M0t &M0, const M1t &M1) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this);
done();
}
// Three options...
template<class M0t, class M1t, class M2t>
opt(const M0t &M0, const M1t &M1,
const M2t &M2) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this);
done();
}
// Four options...
template<class M0t, class M1t, class M2t, class M3t>
opt(const M0t &M0, const M1t &M1, const M2t &M2,
const M3t &M3) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
done();
}
// Five options...
template<class M0t, class M1t, class M2t, class M3t, class M4t>
opt(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this);
done();
}
// Six options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t>
opt(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this);
done();
}
// Seven options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t>
opt(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5,
const M6t &M6) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this);
done();
}
// Eight options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t, class M7t>
opt(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5, const M6t &M6,
const M7t &M7) : Option(Optional | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this); apply(M7, this);
done();
}
};
EXTERN_TEMPLATE_INSTANTIATION(class opt<unsigned>);
EXTERN_TEMPLATE_INSTANTIATION(class opt<int>);
EXTERN_TEMPLATE_INSTANTIATION(class opt<std::string>);
EXTERN_TEMPLATE_INSTANTIATION(class opt<char>);
EXTERN_TEMPLATE_INSTANTIATION(class opt<bool>);
//===----------------------------------------------------------------------===//
// list_storage class
// Default storage class definition: external storage. This implementation
// assumes the user will specify a variable to store the data into with the
// cl::location(x) modifier.
//
template<class DataType, class StorageClass>
class list_storage {
StorageClass *Location; // Where to store the object...
public:
list_storage() : Location(0) {}
bool setLocation(Option &O, StorageClass &L) {
if (Location)
return O.error("cl::location(x) specified more than once!");
Location = &L;
return false;
}
template<class T>
void addValue(const T &V) {
assert(Location != 0 && "cl::location(...) not specified for a command "
"line option with external storage!");
Location->push_back(V);
}
};
// Define how to hold a class type object, such as a string. Since we can
// inherit from a class, we do so. This makes us exactly compatible with the
// object in all cases that it is used.
//
template<class DataType>
class list_storage<DataType, bool> : public std::vector<DataType> {
public:
template<class T>
void addValue(const T &V) { std::vector<DataType>::push_back(V); }
};
//===----------------------------------------------------------------------===//
// list - A list of command line options.
//
template <class DataType, class Storage = bool,
class ParserClass = parser<DataType> >
class list : public Option, public list_storage<DataType, Storage> {
std::vector<unsigned> Positions;
ParserClass Parser;
virtual enum ValueExpected getValueExpectedFlagDefault() const {
return Parser.getValueExpectedFlagDefault();
}
virtual void getExtraOptionNames(SmallVectorImpl<const char*> &OptionNames) {
return Parser.getExtraOptionNames(OptionNames);
}
virtual bool handleOccurrence(unsigned pos, StringRef ArgName, StringRef Arg){
typename ParserClass::parser_data_type Val =
typename ParserClass::parser_data_type();
if (Parser.parse(*this, ArgName, Arg, Val))
return true; // Parse Error!
list_storage<DataType, Storage>::addValue(Val);
setPosition(pos);
Positions.push_back(pos);
return false;
}
// Forward printing stuff to the parser...
virtual size_t getOptionWidth() const {return Parser.getOptionWidth(*this);}
virtual void printOptionInfo(size_t GlobalWidth) const {
Parser.printOptionInfo(*this, GlobalWidth);
}
// Unimplemented: list options don't currently store their default value.
virtual void printOptionValue(size_t /*GlobalWidth*/, bool /*Force*/) const {}
void done() {
addArgument();
Parser.initialize(*this);
}
public:
ParserClass &getParser() { return Parser; }
unsigned getPosition(unsigned optnum) const {
assert(optnum < this->size() && "Invalid option index");
return Positions[optnum];
}
void setNumAdditionalVals(unsigned n) {
Option::setNumAdditionalVals(n);
}
// One option...
template<class M0t>
explicit list(const M0t &M0) : Option(ZeroOrMore | NotHidden) {
apply(M0, this);
done();
}
// Two options...
template<class M0t, class M1t>
list(const M0t &M0, const M1t &M1) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this);
done();
}
// Three options...
template<class M0t, class M1t, class M2t>
list(const M0t &M0, const M1t &M1, const M2t &M2)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this);
done();
}
// Four options...
template<class M0t, class M1t, class M2t, class M3t>
list(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
done();
}
// Five options...
template<class M0t, class M1t, class M2t, class M3t, class M4t>
list(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this);
done();
}
// Six options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t>
list(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this);
done();
}
// Seven options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t>
list(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5, const M6t &M6)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this);
done();
}
// Eight options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t, class M7t>
list(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5, const M6t &M6,
const M7t &M7) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this); apply(M7, this);
done();
}
};
// multi_val - Modifier to set the number of additional values.
struct multi_val {
unsigned AdditionalVals;
explicit multi_val(unsigned N) : AdditionalVals(N) {}
template <typename D, typename S, typename P>
void apply(list<D, S, P> &L) const { L.setNumAdditionalVals(AdditionalVals); }
};
//===----------------------------------------------------------------------===//
// bits_storage class
// Default storage class definition: external storage. This implementation
// assumes the user will specify a variable to store the data into with the
// cl::location(x) modifier.
//
template<class DataType, class StorageClass>
class bits_storage {
unsigned *Location; // Where to store the bits...
template<class T>
static unsigned Bit(const T &V) {
unsigned BitPos = reinterpret_cast<unsigned>(V);
assert(BitPos < sizeof(unsigned) * CHAR_BIT &&
"enum exceeds width of bit vector!");
return 1 << BitPos;
}
public:
bits_storage() : Location(0) {}
bool setLocation(Option &O, unsigned &L) {
if (Location)
return O.error("cl::location(x) specified more than once!");
Location = &L;
return false;
}
template<class T>
void addValue(const T &V) {
assert(Location != 0 && "cl::location(...) not specified for a command "
"line option with external storage!");
*Location |= Bit(V);
}
unsigned getBits() { return *Location; }
template<class T>
bool isSet(const T &V) {
return (*Location & Bit(V)) != 0;
}
};
// Define how to hold bits. Since we can inherit from a class, we do so.
// This makes us exactly compatible with the bits in all cases that it is used.
//
template<class DataType>
class bits_storage<DataType, bool> {
unsigned Bits; // Where to store the bits...
template<class T>
static unsigned Bit(const T &V) {
unsigned BitPos = (unsigned)V;
assert(BitPos < sizeof(unsigned) * CHAR_BIT &&
"enum exceeds width of bit vector!");
return 1 << BitPos;
}
public:
template<class T>
void addValue(const T &V) {
Bits |= Bit(V);
}
unsigned getBits() { return Bits; }
template<class T>
bool isSet(const T &V) {
return (Bits & Bit(V)) != 0;
}
};
//===----------------------------------------------------------------------===//
// bits - A bit vector of command options.
//
template <class DataType, class Storage = bool,
class ParserClass = parser<DataType> >
class bits : public Option, public bits_storage<DataType, Storage> {
std::vector<unsigned> Positions;
ParserClass Parser;
virtual enum ValueExpected getValueExpectedFlagDefault() const {
return Parser.getValueExpectedFlagDefault();
}
virtual void getExtraOptionNames(SmallVectorImpl<const char*> &OptionNames) {
return Parser.getExtraOptionNames(OptionNames);
}
virtual bool handleOccurrence(unsigned pos, StringRef ArgName, StringRef Arg){
typename ParserClass::parser_data_type Val =
typename ParserClass::parser_data_type();
if (Parser.parse(*this, ArgName, Arg, Val))
return true; // Parse Error!
addValue(Val);
setPosition(pos);
Positions.push_back(pos);
return false;
}
// Forward printing stuff to the parser...
virtual size_t getOptionWidth() const {return Parser.getOptionWidth(*this);}
virtual void printOptionInfo(size_t GlobalWidth) const {
Parser.printOptionInfo(*this, GlobalWidth);
}
// Unimplemented: bits options don't currently store their default values.
virtual void printOptionValue(size_t /*GlobalWidth*/, bool /*Force*/) const {}
void done() {
addArgument();
Parser.initialize(*this);
}
public:
ParserClass &getParser() { return Parser; }
unsigned getPosition(unsigned optnum) const {
assert(optnum < this->size() && "Invalid option index");
return Positions[optnum];
}
// One option...
template<class M0t>
explicit bits(const M0t &M0) : Option(ZeroOrMore | NotHidden) {
apply(M0, this);
done();
}
// Two options...
template<class M0t, class M1t>
bits(const M0t &M0, const M1t &M1) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this);
done();
}
// Three options...
template<class M0t, class M1t, class M2t>
bits(const M0t &M0, const M1t &M1, const M2t &M2)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this);
done();
}
// Four options...
template<class M0t, class M1t, class M2t, class M3t>
bits(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
done();
}
// Five options...
template<class M0t, class M1t, class M2t, class M3t, class M4t>
bits(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this);
done();
}
// Six options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t>
bits(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this);
done();
}
// Seven options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t>
bits(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5, const M6t &M6)
: Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this);
done();
}
// Eight options...
template<class M0t, class M1t, class M2t, class M3t,
class M4t, class M5t, class M6t, class M7t>
bits(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3,
const M4t &M4, const M5t &M5, const M6t &M6,
const M7t &M7) : Option(ZeroOrMore | NotHidden) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
apply(M4, this); apply(M5, this); apply(M6, this); apply(M7, this);
done();
}
};
//===----------------------------------------------------------------------===//
// Aliased command line option (alias this name to a preexisting name)
//
class alias : public Option {
Option *AliasFor;
virtual bool handleOccurrence(unsigned pos, StringRef /*ArgName*/,
StringRef Arg) {
return AliasFor->handleOccurrence(pos, AliasFor->ArgStr, Arg);
}
// Handle printing stuff...
virtual size_t getOptionWidth() const;
virtual void printOptionInfo(size_t GlobalWidth) const;
// Aliases do not need to print their values.
virtual void printOptionValue(size_t /*GlobalWidth*/, bool /*Force*/) const {}
void done() {
if (!hasArgStr())
error("cl::alias must have argument name specified!");
if (AliasFor == 0)
error("cl::alias must have an cl::aliasopt(option) specified!");
addArgument();
}
public:
void setAliasFor(Option &O) {
if (AliasFor)
error("cl::alias must only have one cl::aliasopt(...) specified!");
AliasFor = &O;
}
// One option...
template<class M0t>
explicit alias(const M0t &M0) : Option(Optional | Hidden), AliasFor(0) {
apply(M0, this);
done();
}
// Two options...
template<class M0t, class M1t>
alias(const M0t &M0, const M1t &M1) : Option(Optional | Hidden), AliasFor(0) {
apply(M0, this); apply(M1, this);
done();
}
// Three options...
template<class M0t, class M1t, class M2t>
alias(const M0t &M0, const M1t &M1, const M2t &M2)
: Option(Optional | Hidden), AliasFor(0) {
apply(M0, this); apply(M1, this); apply(M2, this);
done();
}
// Four options...
template<class M0t, class M1t, class M2t, class M3t>
alias(const M0t &M0, const M1t &M1, const M2t &M2, const M3t &M3)
: Option(Optional | Hidden), AliasFor(0) {
apply(M0, this); apply(M1, this); apply(M2, this); apply(M3, this);
done();
}
};
// aliasfor - Modifier to set the option an alias aliases.
struct aliasopt {
Option &Opt;
explicit aliasopt(Option &O) : Opt(O) {}
void apply(alias &A) const { A.setAliasFor(Opt); }
};
// extrahelp - provide additional help at the end of the normal help
// output. All occurrences of cl::extrahelp will be accumulated and
// printed to stderr at the end of the regular help, just before
// exit is called.
struct extrahelp {
const char * morehelp;
explicit extrahelp(const char* help);
};
void PrintVersionMessage();
// This function just prints the help message, exactly the same way as if the
// -help option had been given on the command line.
// NOTE: THIS FUNCTION TERMINATES THE PROGRAM!
void PrintHelpMessage();
} // End namespace cl
} // End namespace llvm
#endif