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android / platform / external / catch2 / d6508ae1fce7a1b6edffeb4ef8615ab0ffdefe36 / . / include / external / clara.hpp
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// Copyright 2017 Two Blue Cubes Ltd. All rights reserved.
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
// See https://github.com/philsquared/Clara for more details
// Clara v1.1.1
#ifndef CATCH_CLARA_HPP_INCLUDED
#define CATCH_CLARA_HPP_INCLUDED
#ifndef CATCH_CLARA_CONFIG_CONSOLE_WIDTH
#define CATCH_CLARA_CONFIG_CONSOLE_WIDTH 80
#endif
#ifndef CATCH_CLARA_TEXTFLOW_CONFIG_CONSOLE_WIDTH
#define CATCH_CLARA_TEXTFLOW_CONFIG_CONSOLE_WIDTH CATCH_CLARA_CONFIG_CONSOLE_WIDTH
#endif
// ----------- #included from clara_textflow.hpp -----------
// TextFlowCpp
//
// A single-header library for wrapping and laying out basic text, by Phil Nash
//
// This work is licensed under the BSD 2-Clause license.
// See the accompanying LICENSE file, or the one at https://opensource.org/licenses/BSD-2-Clause
//
// This project is hosted at https://github.com/philsquared/textflowcpp
#ifndef CATCH_CLARA_TEXTFLOW_HPP_INCLUDED
#define CATCH_CLARA_TEXTFLOW_HPP_INCLUDED
#include <cassert>
#include <ostream>
#include <sstream>
#include <vector>
#ifndef CATCH_CLARA_TEXTFLOW_CONFIG_CONSOLE_WIDTH
#define CATCH_CLARA_TEXTFLOW_CONFIG_CONSOLE_WIDTH 80
#endif
#if CATCH_CONFIG_USE_EXCEPTIONS == 0
// std::cerr + std::terminate instead of 'throw'
#include <iostream>
#include <exception>
#endif
namespace Catch { namespace clara { namespace TextFlow {
inline auto isWhitespace( char c ) -> bool {
static std::string chars = " \t\n\r";
return chars.find( c ) != std::string::npos;
}
inline auto isBreakableBefore( char c ) -> bool {
static std::string chars = "[({<|";
return chars.find( c ) != std::string::npos;
}
inline auto isBreakableAfter( char c ) -> bool {
static std::string chars = "])}>.,:;*+-=&/\\";
return chars.find( c ) != std::string::npos;
}
class Columns;
class Column {
std::vector<std::string> m_strings;
size_t m_width = CATCH_CLARA_TEXTFLOW_CONFIG_CONSOLE_WIDTH;
size_t m_indent = 0;
size_t m_initialIndent = std::string::npos;
public:
class iterator {
friend Column;
Column const& m_column;
size_t m_stringIndex = 0;
size_t m_pos = 0;
size_t m_len = 0;
size_t m_end = 0;
bool m_suffix = false;
iterator( Column const& column, size_t stringIndex )
: m_column( column ),
m_stringIndex( stringIndex )
{}
auto line() const -> std::string const& { return m_column.m_strings[m_stringIndex]; }
auto isBoundary( size_t at ) const -> bool {
assert( at > 0 );
assert( at <= line().size() );
return at == line().size() ||
( isWhitespace( line()[at] ) && !isWhitespace( line()[at-1] ) ) ||
isBreakableBefore( line()[at] ) ||
isBreakableAfter( line()[at-1] );
}
void calcLength() {
assert( m_stringIndex < m_column.m_strings.size() );
m_suffix = false;
auto width = m_column.m_width-indent();
m_end = m_pos;
while( m_end < line().size() && line()[m_end] != '\n' )
++m_end;
if( m_end < m_pos + width ) {
m_len = m_end - m_pos;
}
else {
size_t len = width;
while (len > 0 && !isBoundary(m_pos + len))
--len;
while (len > 0 && isWhitespace( line()[m_pos + len - 1] ))
--len;
if (len > 0) {
m_len = len;
} else {
m_suffix = true;
m_len = width - 1;
}
}
}
auto indent() const -> size_t {
auto initial = m_pos == 0 && m_stringIndex == 0 ? m_column.m_initialIndent : std::string::npos;
return initial == std::string::npos ? m_column.m_indent : initial;
}
auto addIndentAndSuffix(std::string const &plain) const -> std::string {
return std::string( indent(), ' ' ) + (m_suffix ? plain + "-" : plain);
}
public:
explicit iterator( Column const& column ) : m_column( column ) {
assert( m_column.m_width > m_column.m_indent );
assert( m_column.m_initialIndent == std::string::npos || m_column.m_width > m_column.m_initialIndent );
calcLength();
if( m_len == 0 )
m_stringIndex++; // Empty string
}
auto operator *() const -> std::string {
assert( m_stringIndex < m_column.m_strings.size() );
assert( m_pos <= m_end );
if( m_pos + m_column.m_width < m_end )
return addIndentAndSuffix(line().substr(m_pos, m_len));
else
return addIndentAndSuffix(line().substr(m_pos, m_end - m_pos));
}
auto operator ++() -> iterator& {
m_pos += m_len;
if( m_pos < line().size() && line()[m_pos] == '\n' )
m_pos += 1;
else
while( m_pos < line().size() && isWhitespace( line()[m_pos] ) )
++m_pos;
if( m_pos == line().size() ) {
m_pos = 0;
++m_stringIndex;
}
if( m_stringIndex < m_column.m_strings.size() )
calcLength();
return *this;
}
auto operator ++(int) -> iterator {
iterator prev( *this );
operator++();
return prev;
}
auto operator ==( iterator const& other ) const -> bool {
return
m_pos == other.m_pos &&
m_stringIndex == other.m_stringIndex &&
&m_column == &other.m_column;
}
auto operator !=( iterator const& other ) const -> bool {
return !operator==( other );
}
};
using const_iterator = iterator;
explicit Column( std::string const& text ) { m_strings.push_back( text ); }
auto width( size_t newWidth ) -> Column& {
assert( newWidth > 0 );
m_width = newWidth;
return *this;
}
auto indent( size_t newIndent ) -> Column& {
m_indent = newIndent;
return *this;
}
auto initialIndent( size_t newIndent ) -> Column& {
m_initialIndent = newIndent;
return *this;
}
auto width() const -> size_t { return m_width; }
auto begin() const -> iterator { return iterator( *this ); }
auto end() const -> iterator { return { *this, m_strings.size() }; }
inline friend std::ostream& operator << ( std::ostream& os, Column const& col ) {
bool first = true;
for( auto line : col ) {
if( first )
first = false;
else
os << "\n";
os << line;
}
return os;
}
auto operator + ( Column const& other ) -> Columns;
auto toString() const -> std::string {
std::ostringstream oss;
oss << *this;
return oss.str();
}
};
class Spacer : public Column {
public:
explicit Spacer( size_t spaceWidth ) : Column( "" ) {
width( spaceWidth );
}
};
class Columns {
std::vector<Column> m_columns;
public:
class iterator {
friend Columns;
struct EndTag {};
std::vector<Column> const& m_columns;
std::vector<Column::iterator> m_iterators;
size_t m_activeIterators;
iterator( Columns const& columns, EndTag )
: m_columns( columns.m_columns ),
m_activeIterators( 0 )
{
m_iterators.reserve( m_columns.size() );
for( auto const& col : m_columns )
m_iterators.push_back( col.end() );
}
public:
explicit iterator( Columns const& columns )
: m_columns( columns.m_columns ),
m_activeIterators( m_columns.size() )
{
m_iterators.reserve( m_columns.size() );
for( auto const& col : m_columns )
m_iterators.push_back( col.begin() );
}
auto operator ==( iterator const& other ) const -> bool {
return m_iterators == other.m_iterators;
}
auto operator !=( iterator const& other ) const -> bool {
return m_iterators != other.m_iterators;
}
auto operator *() const -> std::string {
std::string row, padding;
for( size_t i = 0; i < m_columns.size(); ++i ) {
auto width = m_columns[i].width();
if( m_iterators[i] != m_columns[i].end() ) {
std::string col = *m_iterators[i];
row += padding + col;
if( col.size() < width )
padding = std::string( width - col.size(), ' ' );
else
padding = "";
}
else {
padding += std::string( width, ' ' );
}
}
return row;
}
auto operator ++() -> iterator& {
for( size_t i = 0; i < m_columns.size(); ++i ) {
if (m_iterators[i] != m_columns[i].end())
++m_iterators[i];
}
return *this;
}
auto operator ++(int) -> iterator {
iterator prev( *this );
operator++();
return prev;
}
};
using const_iterator = iterator;
auto begin() const -> iterator { return iterator( *this ); }
auto end() const -> iterator { return { *this, iterator::EndTag() }; }
auto operator += ( Column const& col ) -> Columns& {
m_columns.push_back( col );
return *this;
}
auto operator + ( Column const& col ) -> Columns {
Columns combined = *this;
combined += col;
return combined;
}
inline friend std::ostream& operator << ( std::ostream& os, Columns const& cols ) {
bool first = true;
for( auto line : cols ) {
if( first )
first = false;
else
os << "\n";
os << line;
}
return os;
}
auto toString() const -> std::string {
std::ostringstream oss;
oss << *this;
return oss.str();
}
};
inline auto Column::operator + ( Column const& other ) -> Columns {
Columns cols;
cols += *this;
cols += other;
return cols;
}
}}} // namespace Catch::clara::TextFlow
#endif // CATCH_CLARA_TEXTFLOW_HPP_INCLUDED
// ----------- end of #include from clara_textflow.hpp -----------
// ........... back in clara.hpp
#include <memory>
#include <set>
#include <algorithm>
#if !defined(CATCH_PLATFORM_WINDOWS) && ( defined(WIN32) || defined(__WIN32__) || defined(_WIN32) || defined(_MSC_VER) )
#define CATCH_PLATFORM_WINDOWS
#endif
namespace Catch { namespace clara {
namespace detail {
// Traits for extracting arg and return type of lambdas (for single argument lambdas)
template<typename L>
struct UnaryLambdaTraits : UnaryLambdaTraits<decltype( &L::operator() )> {};
template<typename ClassT, typename ReturnT, typename... Args>
struct UnaryLambdaTraits<ReturnT( ClassT::* )( Args... ) const> {
static const bool isValid = false;
};
template<typename ClassT, typename ReturnT, typename ArgT>
struct UnaryLambdaTraits<ReturnT( ClassT::* )( ArgT ) const> {
static const bool isValid = true;
using ArgType = typename std::remove_const<typename std::remove_reference<ArgT>::type>::type;
using ReturnType = ReturnT;
};
class TokenStream;
// Transport for raw args (copied from main args, or supplied via init list for testing)
class Args {
friend TokenStream;
std::string m_exeName;
std::vector<std::string> m_args;
public:
Args( int argc, char *argv[] ) {
m_exeName = argv[0];
for( int i = 1; i < argc; ++i )
m_args.push_back( argv[i] );
}
Args( std::initializer_list<std::string> args )
: m_exeName( *args.begin() ),
m_args( args.begin()+1, args.end() )
{}
auto exeName() const -> std::string {
return m_exeName;
}
};
// Wraps a token coming from a token stream. These may not directly correspond to strings as a single string
// may encode an option + its argument if the : or = form is used
enum class TokenType {
Option, Argument
};
struct Token {
TokenType type;
std::string token;
};
inline auto isOptPrefix( char c ) -> bool {
return c == '-'
#ifdef CATCH_PLATFORM_WINDOWS
|| c == '/'
#endif
;
}
// Abstracts iterators into args as a stream of tokens, with option arguments uniformly handled
class TokenStream {
using Iterator = std::vector<std::string>::const_iterator;
Iterator it;
Iterator itEnd;
std::vector<Token> m_tokenBuffer;
void loadBuffer() {
m_tokenBuffer.resize( 0 );
// Skip any empty strings
while( it != itEnd && it->empty() )
++it;
if( it != itEnd ) {
auto const &next = *it;
if( isOptPrefix( next[0] ) ) {
auto delimiterPos = next.find_first_of( " :=" );
if( delimiterPos != std::string::npos ) {
m_tokenBuffer.push_back( { TokenType::Option, next.substr( 0, delimiterPos ) } );
m_tokenBuffer.push_back( { TokenType::Argument, next.substr( delimiterPos + 1 ) } );
} else {
if( next[1] != '-' && next.size() > 2 ) {
std::string opt = "- ";
for( size_t i = 1; i < next.size(); ++i ) {
opt[1] = next[i];
m_tokenBuffer.push_back( { TokenType::Option, opt } );
}
} else {
m_tokenBuffer.push_back( { TokenType::Option, next } );
}
}
} else {
m_tokenBuffer.push_back( { TokenType::Argument, next } );
}
}
}
public:
explicit TokenStream( Args const &args ) : TokenStream( args.m_args.begin(), args.m_args.end() ) {}
TokenStream( Iterator it, Iterator itEnd ) : it( it ), itEnd( itEnd ) {
loadBuffer();
}
explicit operator bool() const {
return !m_tokenBuffer.empty() || it != itEnd;
}
auto count() const -> size_t { return m_tokenBuffer.size() + (itEnd - it); }
auto operator*() const -> Token {
assert( !m_tokenBuffer.empty() );
return m_tokenBuffer.front();
}
auto operator->() const -> Token const * {
assert( !m_tokenBuffer.empty() );
return &m_tokenBuffer.front();
}
auto operator++() -> TokenStream & {
if( m_tokenBuffer.size() >= 2 ) {
m_tokenBuffer.erase( m_tokenBuffer.begin() );
} else {
if( it != itEnd )
++it;
loadBuffer();
}
return *this;
}
};
class ResultBase {
public:
enum Type {
Ok, LogicError, RuntimeError
};
protected:
ResultBase( Type type ) : m_type( type ) {}
virtual ~ResultBase() = default;
virtual void enforceOk() const = 0;
Type m_type;
};
template<typename T>
class ResultValueBase : public ResultBase {
public:
auto value() const -> T const & {
enforceOk();
return m_value;
}
protected:
ResultValueBase( Type type ) : ResultBase( type ) {}
ResultValueBase( ResultValueBase const &other ) : ResultBase( other ) {
if( m_type == ResultBase::Ok )
new( &m_value ) T( other.m_value );
}
ResultValueBase( Type, T const &value ) : ResultBase( Ok ) {
new( &m_value ) T( value );
}
auto operator=( ResultValueBase const &other ) -> ResultValueBase & {
if( m_type == ResultBase::Ok )
m_value.~T();
ResultBase::operator=(other);
if( m_type == ResultBase::Ok )
new( &m_value ) T( other.m_value );
return *this;
}
~ResultValueBase() override {
if( m_type == Ok )
m_value.~T();
}
union {
T m_value;
};
};
template<>
class ResultValueBase<void> : public ResultBase {
protected:
using ResultBase::ResultBase;
};
template<typename T = void>
class BasicResult : public ResultValueBase<T> {
public:
template<typename U>
explicit BasicResult( BasicResult<U> const &other )
: ResultValueBase<T>( other.type() ),
m_errorMessage( other.errorMessage() )
{
assert( type() != ResultBase::Ok );
}
template<typename U>
static auto ok( U const &value ) -> BasicResult { return { ResultBase::Ok, value }; }
static auto ok() -> BasicResult { return { ResultBase::Ok }; }
static auto logicError( std::string const &message ) -> BasicResult { return { ResultBase::LogicError, message }; }
static auto runtimeError( std::string const &message ) -> BasicResult { return { ResultBase::RuntimeError, message }; }
explicit operator bool() const { return m_type == ResultBase::Ok; }
auto type() const -> ResultBase::Type { return m_type; }
auto errorMessage() const -> std::string { return m_errorMessage; }
protected:
void enforceOk() const override {
switch( m_type ) {
case ResultBase::LogicError:
Exception::doThrow( std::logic_error( m_errorMessage ) );
case ResultBase::RuntimeError:
Exception::doThrow( std::runtime_error( m_errorMessage ) );
case ResultBase::Ok:
break;
}
}
std::string m_errorMessage; // Only populated if resultType is an error
BasicResult( ResultBase::Type type, std::string const &message )
: ResultValueBase<T>(type),
m_errorMessage(message)
{
assert( m_type != ResultBase::Ok );
}
using ResultValueBase<T>::ResultValueBase;
using ResultBase::m_type;
};
enum class ParseResultType {
Matched, NoMatch, ShortCircuitAll, ShortCircuitSame
};
class ParseState {
public:
ParseState( ParseResultType type, TokenStream const &remainingTokens )
: m_type(type),
m_remainingTokens( remainingTokens )
{}
auto type() const -> ParseResultType { return m_type; }
auto remainingTokens() const -> TokenStream { return m_remainingTokens; }
private:
ParseResultType m_type;
TokenStream m_remainingTokens;
};
using Result = BasicResult<void>;
using ParserResult = BasicResult<ParseResultType>;
using InternalParseResult = BasicResult<ParseState>;
struct HelpColumns {
std::string left;
std::string right;
};
template<typename T>
inline auto convertInto( std::string const &source, T& target ) -> ParserResult {
std::stringstream ss;
ss << source;
ss >> target;
if( ss.fail() )
return ParserResult::runtimeError( "Unable to convert '" + source + "' to destination type" );
else
return ParserResult::ok( ParseResultType::Matched );
}
inline auto convertInto( std::string const &source, std::string& target ) -> ParserResult {
target = source;
return ParserResult::ok( ParseResultType::Matched );
}
inline auto convertInto( std::string const &source, bool &target ) -> ParserResult {
std::string srcLC = source;
std::transform( srcLC.begin(), srcLC.end(), srcLC.begin(), []( char c ) { return static_cast<char>( ::tolower(c) ); } );
if (srcLC == "y" || srcLC == "1" || srcLC == "true" || srcLC == "yes" || srcLC == "on")
target = true;
else if (srcLC == "n" || srcLC == "0" || srcLC == "false" || srcLC == "no" || srcLC == "off")
target = false;
else
return ParserResult::runtimeError( "Expected a boolean value but did not recognise: '" + source + "'" );
return ParserResult::ok( ParseResultType::Matched );
}
struct NonCopyable {
NonCopyable() = default;
NonCopyable( NonCopyable const & ) = delete;
NonCopyable( NonCopyable && ) = delete;
NonCopyable &operator=( NonCopyable const & ) = delete;
NonCopyable &operator=( NonCopyable && ) = delete;
};
struct BoundValueRefBase;
struct BoundRef : NonCopyable {
virtual ~BoundRef() = default;
virtual auto isContainer() const -> bool { return false; }
virtual auto isValueRefBase() const -> bool = 0; // Support for compiling without rtti.
};
struct BoundValueRefBase : BoundRef {
virtual auto setValue( std::string const &arg ) -> ParserResult = 0;
virtual auto isValueRefBase() const -> bool { return true; }
};
struct BoundFlagRefBase : BoundRef {
virtual auto setFlag( bool flag ) -> ParserResult = 0;
virtual auto isValueRefBase() const -> bool { return false; }
};
template<typename T>
struct BoundValueRef : BoundValueRefBase {
T &m_ref;
explicit BoundValueRef( T &ref ) : m_ref( ref ) {}
auto setValue( std::string const &arg ) -> ParserResult override {
return convertInto( arg, m_ref );
}
};
template<typename T>
struct BoundValueRef<std::vector<T>> : BoundValueRefBase {
std::vector<T> &m_ref;
explicit BoundValueRef( std::vector<T> &ref ) : m_ref( ref ) {}
auto isContainer() const -> bool override { return true; }
auto setValue( std::string const &arg ) -> ParserResult override {
T temp;
auto result = convertInto( arg, temp );
if( result )
m_ref.push_back( temp );
return result;
}
};
struct BoundFlagRef : BoundFlagRefBase {
bool &m_ref;
explicit BoundFlagRef( bool &ref ) : m_ref( ref ) {}
auto setFlag( bool flag ) -> ParserResult override {
m_ref = flag;
return ParserResult::ok( ParseResultType::Matched );
}
};
template<typename ReturnType>
struct LambdaInvoker {
static_assert( std::is_same<ReturnType, ParserResult>::value, "Lambda must return void or clara::ParserResult" );
template<typename L, typename ArgType>
static auto invoke( L const &lambda, ArgType const &arg ) -> ParserResult {
return lambda( arg );
}
};
template<>
struct LambdaInvoker<void> {
template<typename L, typename ArgType>
static auto invoke( L const &lambda, ArgType const &arg ) -> ParserResult {
lambda( arg );
return ParserResult::ok( ParseResultType::Matched );
}
};
template<typename ArgType, typename L>
inline auto invokeLambda( L const &lambda, std::string const &arg ) -> ParserResult {
ArgType temp{};
auto result = convertInto( arg, temp );
return !result
? result
: LambdaInvoker<typename UnaryLambdaTraits<L>::ReturnType>::invoke( lambda, temp );
}
template<typename L>
struct BoundLambda : BoundValueRefBase {
L m_lambda;
static_assert( UnaryLambdaTraits<L>::isValid, "Supplied lambda must take exactly one argument" );
explicit BoundLambda( L const &lambda ) : m_lambda( lambda ) {}
auto setValue( std::string const &arg ) -> ParserResult override {
return invokeLambda<typename UnaryLambdaTraits<L>::ArgType>( m_lambda, arg );
}
};
template<typename L>
struct BoundFlagLambda : BoundFlagRefBase {
L m_lambda;
static_assert( UnaryLambdaTraits<L>::isValid, "Supplied lambda must take exactly one argument" );
static_assert( std::is_same<typename UnaryLambdaTraits<L>::ArgType, bool>::value, "flags must be boolean" );
explicit BoundFlagLambda( L const &lambda ) : m_lambda( lambda ) {}
auto setFlag( bool flag ) -> ParserResult override {
return LambdaInvoker<typename UnaryLambdaTraits<L>::ReturnType>::invoke( m_lambda, flag );
}
};
enum class Optionality { Optional, Required };
struct Parser;
class ParserBase {
public:
virtual ~ParserBase() = default;
virtual auto validate() const -> Result { return Result::ok(); }
virtual auto parse( std::string const& exeName, TokenStream const &tokens) const -> InternalParseResult = 0;
virtual auto cardinality() const -> size_t { return 1; }
auto parse( Args const &args ) const -> InternalParseResult {
return parse( args.exeName(), TokenStream( args ) );
}
};
template<typename DerivedT>
class ComposableParserImpl : public ParserBase {
public:
template<typename T>
auto operator|( T const &other ) const -> Parser;
template<typename T>
auto operator+( T const &other ) const -> Parser;
};
// Common code and state for Args and Opts
template<typename DerivedT>
class ParserRefImpl : public ComposableParserImpl<DerivedT> {
protected:
Optionality m_optionality = Optionality::Optional;
std::shared_ptr<BoundRef> m_ref;
std::string m_hint;
std::string m_description;
explicit ParserRefImpl( std::shared_ptr<BoundRef> const &ref ) : m_ref( ref ) {}
public:
template<typename T>
ParserRefImpl( T &ref, std::string const &hint )
: m_ref( std::make_shared<BoundValueRef<T>>( ref ) ),
m_hint( hint )
{}
template<typename LambdaT>
ParserRefImpl( LambdaT const &ref, std::string const &hint )
: m_ref( std::make_shared<BoundLambda<LambdaT>>( ref ) ),
m_hint(hint)
{}
auto operator()( std::string const &description ) -> DerivedT & {
m_description = description;
return static_cast<DerivedT &>( *this );
}
auto optional() -> DerivedT & {
m_optionality = Optionality::Optional;
return static_cast<DerivedT &>( *this );
};
auto required() -> DerivedT & {
m_optionality = Optionality::Required;
return static_cast<DerivedT &>( *this );
};
auto isOptional() const -> bool {
return m_optionality == Optionality::Optional;
}
auto cardinality() const -> size_t override {
if( m_ref->isContainer() )
return 0;
else
return 1;
}
auto hint() const -> std::string { return m_hint; }
};
class ExeName : public ComposableParserImpl<ExeName> {
std::shared_ptr<std::string> m_name;
std::shared_ptr<BoundValueRefBase> m_ref;
template<typename LambdaT>
static auto makeRef(LambdaT const &lambda) -> std::shared_ptr<BoundValueRefBase> {
return std::make_shared<BoundLambda<LambdaT>>( lambda) ;
}
public:
ExeName() : m_name( std::make_shared<std::string>( "<executable>" ) ) {}
explicit ExeName( std::string &ref ) : ExeName() {
m_ref = std::make_shared<BoundValueRef<std::string>>( ref );
}
template<typename LambdaT>
explicit ExeName( LambdaT const& lambda ) : ExeName() {
m_ref = std::make_shared<BoundLambda<LambdaT>>( lambda );
}
// The exe name is not parsed out of the normal tokens, but is handled specially
auto parse( std::string const&, TokenStream const &tokens ) const -> InternalParseResult override {
return InternalParseResult::ok( ParseState( ParseResultType::NoMatch, tokens ) );
}
auto name() const -> std::string { return *m_name; }
auto set( std::string const& newName ) -> ParserResult {
auto lastSlash = newName.find_last_of( "\\/" );
auto filename = ( lastSlash == std::string::npos )
? newName
: newName.substr( lastSlash+1 );
*m_name = filename;
if( m_ref )
return m_ref->setValue( filename );
else
return ParserResult::ok( ParseResultType::Matched );
}
};
class Arg : public ParserRefImpl<Arg> {
public:
using ParserRefImpl::ParserRefImpl;
auto parse( std::string const &, TokenStream const &tokens ) const -> InternalParseResult override {
auto validationResult = validate();
if( !validationResult )
return InternalParseResult( validationResult );
auto remainingTokens = tokens;
auto const &token = *remainingTokens;
if( token.type != TokenType::Argument )
return InternalParseResult::ok( ParseState( ParseResultType::NoMatch, remainingTokens ) );
assert( m_ref.get()->isValueRefBase() );
auto valueRef = static_cast<detail::BoundValueRefBase*>( m_ref.get() );
auto result = valueRef->setValue( remainingTokens->token );
if( !result )
return InternalParseResult( result );
else
return InternalParseResult::ok( ParseState( ParseResultType::Matched, ++remainingTokens ) );
}
};
inline auto normaliseOpt( std::string const &optName ) -> std::string {
#ifdef CATCH_PLATFORM_WINDOWS
if( optName[0] == '/' )
return "-" + optName.substr( 1 );
else
#endif
return optName;
}
class Opt : public ParserRefImpl<Opt> {
protected:
std::vector<std::string> m_optNames;
public:
template<typename LambdaT>
explicit Opt( LambdaT const &ref ) : ParserRefImpl( std::make_shared<BoundFlagLambda<LambdaT>>( ref ) ) {}
explicit Opt( bool &ref ) : ParserRefImpl( std::make_shared<BoundFlagRef>( ref ) ) {}
template<typename LambdaT>
Opt( LambdaT const &ref, std::string const &hint ) : ParserRefImpl( ref, hint ) {}
template<typename T>
Opt( T &ref, std::string const &hint ) : ParserRefImpl( ref, hint ) {}
auto operator[]( std::string const &optName ) -> Opt & {
m_optNames.push_back( optName );
return *this;
}
auto getHelpColumns() const -> std::vector<HelpColumns> {
std::ostringstream oss;
bool first = true;
for( auto const &opt : m_optNames ) {
if (first)
first = false;
else
oss << ", ";
oss << opt;
}
if( !m_hint.empty() )
oss << " <" << m_hint << ">";
return { { oss.str(), m_description } };
}
auto isMatch( std::string const &optToken ) const -> bool {
auto normalisedToken = normaliseOpt( optToken );
for( auto const &name : m_optNames ) {
if( normaliseOpt( name ) == normalisedToken )
return true;
}
return false;
}
using ParserBase::parse;
auto parse( std::string const&, TokenStream const &tokens ) const -> InternalParseResult override {
auto validationResult = validate();
if( !validationResult )
return InternalParseResult( validationResult );
auto remainingTokens = tokens;
if( remainingTokens && remainingTokens->type == TokenType::Option ) {
auto const &token = *remainingTokens;
if( isMatch(token.token ) ) {
if ( !m_ref.get()->isValueRefBase() ) {
detail::BoundFlagRefBase* flagRef = static_cast<detail::BoundFlagRefBase*>( m_ref.get() );
#if CATCH_CONFIG_USE_RTTI
assert( dynamic_cast<detail::BoundFlagRefBase*>( m_ref.get() ) );
#endif
auto result = flagRef->setFlag( true );
if( !result )
return InternalParseResult( result );
if( result.value() == ParseResultType::ShortCircuitAll )
return InternalParseResult::ok( ParseState( result.value(), remainingTokens ) );
} else {
#if CATCH_CONFIG_USE_RTTI
assert( dynamic_cast<detail::BoundValueRefBase*>( m_ref.get() ) );
#endif
auto valueRef = static_cast<detail::BoundValueRefBase*>( m_ref.get() );
++remainingTokens;
if( !remainingTokens )
return InternalParseResult::runtimeError( "Expected argument following " + token.token );
auto const &argToken = *remainingTokens;
if( argToken.type != TokenType::Argument )
return InternalParseResult::runtimeError( "Expected argument following " + token.token );
auto result = valueRef->setValue( argToken.token );
if( !result )
return InternalParseResult( result );
if( result.value() == ParseResultType::ShortCircuitAll )
return InternalParseResult::ok( ParseState( result.value(), remainingTokens ) );
}
return InternalParseResult::ok( ParseState( ParseResultType::Matched, ++remainingTokens ) );
}
}
return InternalParseResult::ok( ParseState( ParseResultType::NoMatch, remainingTokens ) );
}
auto validate() const -> Result override {
if( m_optNames.empty() )
return Result::logicError( "No options supplied to Opt" );
for( auto const &name : m_optNames ) {
if( name.empty() )
return Result::logicError( "Option name cannot be empty" );
#ifdef CATCH_PLATFORM_WINDOWS
if( name[0] != '-' && name[0] != '/' )
return Result::logicError( "Option name must begin with '-' or '/'" );
#else
if( name[0] != '-' )
return Result::logicError( "Option name must begin with '-'" );
#endif
}
return ParserRefImpl::validate();
}
};
struct Help : Opt {
Help( bool &showHelpFlag )
: Opt([&]( bool flag ) {
showHelpFlag = flag;
return ParserResult::ok( ParseResultType::ShortCircuitAll );
})
{
static_cast<Opt &>( *this )
("display usage information")
["-?"]["-h"]["--help"]
.optional();
}
};
struct Parser : ParserBase {
mutable ExeName m_exeName;
std::vector<Opt> m_options;
std::vector<Arg> m_args;
auto operator|=( ExeName const &exeName ) -> Parser & {
m_exeName = exeName;
return *this;
}
auto operator|=( Arg const &arg ) -> Parser & {
m_args.push_back(arg);
return *this;
}
auto operator|=( Opt const &opt ) -> Parser & {
m_options.push_back(opt);
return *this;
}
auto operator|=( Parser const &other ) -> Parser & {
m_options.insert(m_options.end(), other.m_options.begin(), other.m_options.end());
m_args.insert(m_args.end(), other.m_args.begin(), other.m_args.end());
return *this;
}
template<typename T>
auto operator|( T const &other ) const -> Parser {
return Parser( *this ) |= other;
}
// Forward deprecated interface with '+' instead of '|'
template<typename T>
auto operator+=( T const &other ) -> Parser & { return operator|=( other ); }
template<typename T>
auto operator+( T const &other ) const -> Parser { return operator|( other ); }
auto getHelpColumns() const -> std::vector<HelpColumns> {
std::vector<HelpColumns> cols;
for (auto const &o : m_options) {
auto childCols = o.getHelpColumns();
cols.insert( cols.end(), childCols.begin(), childCols.end() );
}
return cols;
}
void writeToStream( std::ostream &os ) const {
if (!m_exeName.name().empty()) {
os << "usage:\n" << " " << m_exeName.name() << " ";
bool required = true, first = true;
for( auto const &arg : m_args ) {
if (first)
first = false;
else
os << " ";
if( arg.isOptional() && required ) {
os << "[";
required = false;
}
os << "<" << arg.hint() << ">";
if( arg.cardinality() == 0 )
os << " ... ";
}
if( !required )
os << "]";
if( !m_options.empty() )
os << " options";
os << "\n\nwhere options are:" << std::endl;
}
auto rows = getHelpColumns();
size_t consoleWidth = CATCH_CLARA_CONFIG_CONSOLE_WIDTH;
size_t optWidth = 0;
for( auto const &cols : rows )
optWidth = (std::max)(optWidth, cols.left.size() + 2);
optWidth = (std::min)(optWidth, consoleWidth/2);
for( auto const &cols : rows ) {
auto row =
TextFlow::Column( cols.left ).width( optWidth ).indent( 2 ) +
TextFlow::Spacer(4) +
TextFlow::Column( cols.right ).width( consoleWidth - 7 - optWidth );
os << row << std::endl;
}
}
friend auto operator<<( std::ostream &os, Parser const &parser ) -> std::ostream& {
parser.writeToStream( os );
return os;
}
auto validate() const -> Result override {
for( auto const &opt : m_options ) {
auto result = opt.validate();
if( !result )
return result;
}
for( auto const &arg : m_args ) {
auto result = arg.validate();
if( !result )
return result;
}
return Result::ok();
}
using ParserBase::parse;
auto parse( std::string const& exeName, TokenStream const &tokens ) const -> InternalParseResult override {
struct ParserInfo {
ParserBase const* parser = nullptr;
size_t count = 0;
};
const size_t totalParsers = m_options.size() + m_args.size();
assert( totalParsers < 512 );
// ParserInfo parseInfos[totalParsers]; // <-- this is what we really want to do
ParserInfo parseInfos[512];
{
size_t i = 0;
for (auto const &opt : m_options) parseInfos[i++].parser = &opt;
for (auto const &arg : m_args) parseInfos[i++].parser = &arg;
}
m_exeName.set( exeName );
auto result = InternalParseResult::ok( ParseState( ParseResultType::NoMatch, tokens ) );
while( result.value().remainingTokens() ) {
bool tokenParsed = false;
for( size_t i = 0; i < totalParsers; ++i ) {
auto& parseInfo = parseInfos[i];
if( parseInfo.parser->cardinality() == 0 || parseInfo.count < parseInfo.parser->cardinality() ) {
result = parseInfo.parser->parse(exeName, result.value().remainingTokens());
if (!result)
return result;
if (result.value().type() != ParseResultType::NoMatch) {
tokenParsed = true;
++parseInfo.count;
break;
}
}
}
if( result.value().type() == ParseResultType::ShortCircuitAll )
return result;
if( !tokenParsed )
return InternalParseResult::runtimeError( "Unrecognised token: " + result.value().remainingTokens()->token );
}
// !TBD Check missing required options
return result;
}
};
template<typename DerivedT>
template<typename T>
auto ComposableParserImpl<DerivedT>::operator|( T const &other ) const -> Parser {
return Parser() | static_cast<DerivedT const &>( *this ) | other;
}
} // namespace detail
// A Combined parser
using detail::Parser;
// A parser for options
using detail::Opt;
// A parser for arguments
using detail::Arg;
// Wrapper for argc, argv from main()
using detail::Args;
// Specifies the name of the executable
using detail::ExeName;
// Convenience wrapper for option parser that specifies the help option
using detail::Help;
// enum of result types from a parse
using detail::ParseResultType;
// Result type for parser operation
using detail::ParserResult;
}} // namespace Catch::clara
#endif // CATCH_CLARA_HPP_INCLUDED