jidt/cuda/lest.hpp

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// Copyright 2013-2017 by Martin Moene
//
// lest is based on ideas by Kevlin Henney, see video at
// http://skillsmatter.com/podcast/agile-testing/kevlin-henney-rethinking-unit-testing-in-c-plus-plus
//
// 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)
#ifndef LEST_LEST_HPP_INCLUDED
#define LEST_LEST_HPP_INCLUDED
#include <algorithm>
#include <chrono>
#include <functional>
#include <iomanip>
#include <iostream>
#include <iterator>
#include <limits>
#include <random>
#include <sstream>
#include <stdexcept>
#include <string>
#include <set>
#include <tuple>
#include <typeinfo>
#include <type_traits>
#include <utility>
#include <vector>
#include <cctype>
#include <cmath>
#include <cstddef>
#ifdef __clang__
# pragma clang diagnostic ignored "-Wgnu-zero-variadic-macro-arguments"
# pragma clang diagnostic ignored "-Woverloaded-shift-op-parentheses"
# pragma clang diagnostic ignored "-Wunused-comparison"
# pragma clang diagnostic ignored "-Wunused-value"
#elif defined __GNUC__
# pragma GCC diagnostic ignored "-Wunused-value"
#endif
#define lest_VERSION "1.29.1"
#ifndef lest_FEATURE_AUTO_REGISTER
# define lest_FEATURE_AUTO_REGISTER 0
#endif
#ifndef lest_FEATURE_COLOURISE
# define lest_FEATURE_COLOURISE 0
#endif
#ifndef lest_FEATURE_LITERAL_SUFFIX
# define lest_FEATURE_LITERAL_SUFFIX 0
#endif
#ifndef lest_FEATURE_REGEX_SEARCH
# define lest_FEATURE_REGEX_SEARCH 0
#endif
#ifndef lest_FEATURE_TIME_PRECISION
#define lest_FEATURE_TIME_PRECISION 0
#endif
#if lest_FEATURE_REGEX_SEARCH
# include <regex>
#endif
#if ! defined( lest_NO_SHORT_MACRO_NAMES ) && ! defined( lest_NO_SHORT_ASSERTION_NAMES )
# define MODULE lest_MODULE
# if ! lest_FEATURE_AUTO_REGISTER
# define CASE lest_CASE
# endif
# define SETUP lest_SETUP
# define SECTION lest_SECTION
# define EXPECT lest_EXPECT
# define EXPECT_NOT lest_EXPECT_NOT
# define EXPECT_NO_THROW lest_EXPECT_NO_THROW
# define EXPECT_THROWS lest_EXPECT_THROWS
# define EXPECT_THROWS_AS lest_EXPECT_THROWS_AS
# define SCENARIO lest_SCENARIO
# define GIVEN lest_GIVEN
# define WHEN lest_WHEN
# define THEN lest_THEN
# define AND_WHEN lest_AND_WHEN
# define AND_THEN lest_AND_THEN
#endif
#define lest_SCENARIO( sketch ) lest_CASE( lest::text("Scenario: ") + sketch )
#define lest_GIVEN( context ) lest_SETUP( lest::text( "Given: ") + context )
#define lest_WHEN( story ) lest_SECTION( lest::text( " When: ") + story )
#define lest_THEN( story ) lest_SECTION( lest::text( " Then: ") + story )
#define lest_AND_WHEN( story ) lest_SECTION( lest::text( " And: ") + story )
#define lest_AND_THEN( story ) lest_SECTION( lest::text( " And: ") + story )
#if lest_FEATURE_AUTO_REGISTER
# define lest_CASE( specification, proposition ) \
static void lest_FUNCTION( lest::env & ); \
namespace { lest::add_test lest_REGISTRAR( specification, lest::test( proposition, lest_FUNCTION ) ); } \
static void lest_FUNCTION( lest::env & lest_env )
#else // lest_FEATURE_AUTO_REGISTER
# define lest_CASE( proposition, ... ) \
proposition, [__VA_ARGS__]( lest::env & lest_env )
# define lest_MODULE( specification, module ) \
namespace { lest::add_module _( specification, module ); }
#endif //lest_FEATURE_AUTO_REGISTER
#define lest_SETUP( context ) \
for ( int lest__section = 0, lest__count = 1; lest__section < lest__count; lest__count -= 0==lest__section++ )
#define lest_SECTION( proposition ) \
static int lest_UNIQUE( id ) = 0; \
if ( lest::guard( lest_UNIQUE( id ), lest__section, lest__count ) ) \
for ( int lest__section = 0, lest__count = 1; lest__section < lest__count; lest__count -= 0==lest__section++ )
#define lest_EXPECT( expr ) \
do { \
try \
{ \
if ( lest::result score = lest_DECOMPOSE( expr ) ) \
throw lest::failure{ lest_LOCATION, #expr, score.decomposition }; \
else if ( lest_env.pass ) \
lest::report( lest_env.os, lest::passing{ lest_LOCATION, #expr, score.decomposition }, lest_env.testing ); \
} \
catch(...) \
{ \
lest::inform( lest_LOCATION, #expr ); \
} \
} while ( lest::is_false() )
#define lest_EXPECT_NOT( expr ) \
do { \
try \
{ \
if ( lest::result score = lest_DECOMPOSE( expr ) ) \
{ \
if ( lest_env.pass ) \
lest::report( lest_env.os, lest::passing{ lest_LOCATION, lest::not_expr( #expr ), lest::not_expr( score.decomposition ) }, lest_env.testing ); \
} \
else \
throw lest::failure{ lest_LOCATION, lest::not_expr( #expr ), lest::not_expr( score.decomposition ) }; \
} \
catch(...) \
{ \
lest::inform( lest_LOCATION, lest::not_expr( #expr ) ); \
} \
} while ( lest::is_false() )
#define lest_EXPECT_NO_THROW( expr ) \
do \
{ \
try \
{ \
expr; \
} \
catch (...) \
{ \
lest::inform( lest_LOCATION, #expr ); \
} \
if ( lest_env.pass ) \
lest::report( lest_env.os, lest::got_none( lest_LOCATION, #expr ), lest_env.testing ); \
} while ( lest::is_false() )
#define lest_EXPECT_THROWS( expr ) \
do \
{ \
try \
{ \
expr; \
} \
catch (...) \
{ \
if ( lest_env.pass ) \
lest::report( lest_env.os, lest::got{ lest_LOCATION, #expr }, lest_env.testing ); \
break; \
} \
throw lest::expected{ lest_LOCATION, #expr }; \
} \
while ( lest::is_false() )
#define lest_EXPECT_THROWS_AS( expr, excpt ) \
do \
{ \
try \
{ \
expr; \
} \
catch ( excpt & ) \
{ \
if ( lest_env.pass ) \
lest::report( lest_env.os, lest::got{ lest_LOCATION, #expr, lest::of_type( #excpt ) }, lest_env.testing ); \
break; \
} \
catch (...) {} \
throw lest::expected{ lest_LOCATION, #expr, lest::of_type( #excpt ) }; \
} \
while ( lest::is_false() )
#define lest_UNIQUE( name ) lest_UNIQUE2( name, __LINE__ )
#define lest_UNIQUE2( name, line ) lest_UNIQUE3( name, line )
#define lest_UNIQUE3( name, line ) name ## line
#define lest_DECOMPOSE( expr ) ( lest::expression_decomposer() << expr )
#define lest_FUNCTION lest_UNIQUE(__lest_function__ )
#define lest_REGISTRAR lest_UNIQUE(__lest_registrar__ )
#define lest_LOCATION lest::location{__FILE__, __LINE__}
namespace lest {
using text = std::string;
using texts = std::vector<text>;
struct env;
struct test
{
text name;
std::function<void( env & )> behaviour;
#if lest_FEATURE_AUTO_REGISTER
test( text name, std::function<void( env & )> behaviour )
: name( name ), behaviour( behaviour ) {}
#endif
};
using tests = std::vector<test>;
#if lest_FEATURE_AUTO_REGISTER
struct add_test
{
add_test( tests & specification, test const & test_case )
{
specification.push_back( test_case );
}
};
#else
struct add_module
{
template <std::size_t N>
add_module( tests & specification, test const (&module)[N] )
{
specification.insert( specification.end(), std::begin( module ), std::end( module ) );
}
};
#endif
struct result
{
const bool passed;
const text decomposition;
explicit operator bool() { return ! passed; }
};
struct location
{
const text file;
const int line;
location( text file, int line )
: file( file ), line( line ) {}
};
struct comment
{
const text info;
comment( text info ) : info( info ) {}
explicit operator bool() { return ! info.empty(); }
};
struct message : std::runtime_error
{
const text kind;
const location where;
const comment note;
~message() throw() {} // GCC 4.6
message( text kind, location where, text expr, text note = "" )
: std::runtime_error( expr ), kind( kind ), where( where ), note( note ) {}
};
struct failure : message
{
failure( location where, text expr, text decomposition )
: message{ "failed", where, expr + " for " + decomposition } {}
};
struct success : message
{
// using message::message; // VC is lagging here
success( text kind, location where, text expr, text note = "" )
: message( kind, where, expr, note ) {}
};
struct passing : success
{
passing( location where, text expr, text decomposition )
: success( "passed", where, expr + " for " + decomposition ) {}
};
struct got_none : success
{
got_none( location where, text expr )
: success( "passed: got no exception", where, expr ) {}
};
struct got : success
{
got( location where, text expr )
: success( "passed: got exception", where, expr ) {}
got( location where, text expr, text excpt )
: success( "passed: got exception " + excpt, where, expr ) {}
};
struct expected : message
{
expected( location where, text expr, text excpt = "" )
: message{ "failed: didn't get exception", where, expr, excpt } {}
};
struct unexpected : message
{
unexpected( location where, text expr, text note = "" )
: message{ "failed: got unexpected exception", where, expr, note } {}
};
struct guard
{
int & id;
int const & section;
guard( int & id, int const & section, int & count )
: id( id ), section( section )
{
if ( section == 0 )
id = count++ - 1;
}
operator bool() { return id == section; }
};
class approx
{
public:
explicit approx ( double magnitude )
: epsilon_ { std::numeric_limits<float>::epsilon() * 100 }
, scale_ { 1.0 }
, magnitude_{ magnitude } {}
approx( approx const & other ) = default;
static approx custom() { return approx( 0 ); }
approx operator()( double magnitude )
{
approx approx ( magnitude );
approx.epsilon( epsilon_ );
approx.scale ( scale_ );
return approx;
}
double magnitude() const { return magnitude_; }
approx & epsilon( double epsilon ) { epsilon_ = epsilon; return *this; }
approx & scale ( double scale ) { scale_ = scale; return *this; }
friend bool operator == ( double lhs, approx const & rhs )
{
// Thanks to Richard Harris for his help refining this formula.
return std::abs( lhs - rhs.magnitude_ ) < rhs.epsilon_ * ( rhs.scale_ + (std::min)( std::abs( lhs ), std::abs( rhs.magnitude_ ) ) );
}
friend bool operator == ( approx const & lhs, double rhs ) { return operator==( rhs, lhs ); }
friend bool operator != ( double lhs, approx const & rhs ) { return !operator==( lhs, rhs ); }
friend bool operator != ( approx const & lhs, double rhs ) { return !operator==( rhs, lhs ); }
friend bool operator <= ( double lhs, approx const & rhs ) { return lhs < rhs.magnitude_ || lhs == rhs; }
friend bool operator <= ( approx const & lhs, double rhs ) { return lhs.magnitude_ < rhs || lhs == rhs; }
friend bool operator >= ( double lhs, approx const & rhs ) { return lhs > rhs.magnitude_ || lhs == rhs; }
friend bool operator >= ( approx const & lhs, double rhs ) { return lhs.magnitude_ > rhs || lhs == rhs; }
private:
double epsilon_;
double scale_;
double magnitude_;
};
inline bool is_false( ) { return false; }
inline bool is_true ( bool flag ) { return flag; }
inline text not_expr( text message )
{
return "! ( " + message + " )";
}
inline text with_message( text message )
{
return "with message \"" + message + "\"";
}
inline text of_type( text type )
{
return "of type " + type;
}
inline void inform( location where, text expr )
{
try
{
throw;
}
catch( message const & )
{
throw;
}
catch( std::exception const & e )
{
throw unexpected{ where, expr, with_message( e.what() ) }; \
}
catch(...)
{
throw unexpected{ where, expr, "of unknown type" }; \
}
}
// Expression decomposition:
template<typename T>
auto make_value_string( T const & value ) -> std::string;
template<typename T>
auto make_memory_string( T const & item ) -> std::string;
#if lest_FEATURE_LITERAL_SUFFIX
inline char const * sfx( char const * text ) { return text; }
#else
inline char const * sfx( char const * ) { return ""; }
#endif
inline std::string to_string( std::nullptr_t ) { return "nullptr"; }
inline std::string to_string( std::string const & text ) { return "\"" + text + "\"" ; }
inline std::string to_string( std::wstring const & text ) ;
inline std::string to_string( char const * const text ) { return text ? to_string( std::string ( text ) ) : "{null string}"; }
inline std::string to_string( char * const text ) { return text ? to_string( std::string ( text ) ) : "{null string}"; }
inline std::string to_string( wchar_t const * const text ) { return text ? to_string( std::wstring( text ) ) : "{null string}"; }
inline std::string to_string( wchar_t * const text ) { return text ? to_string( std::wstring( text ) ) : "{null string}"; }
inline std::string to_string( char text ) { return "\'" + std::string( 1, text ) + "\'" ; }
inline std::string to_string( signed char text ) { return "\'" + std::string( 1, text ) + "\'" ; }
inline std::string to_string( unsigned char text ) { return "\'" + std::string( 1, text ) + "\'" ; }
inline std::string to_string( bool flag ) { return flag ? "true" : "false"; }
inline std::string to_string( signed short value ) { return make_value_string( value ) ; }
inline std::string to_string( unsigned short value ) { return make_value_string( value ) + sfx("u" ); }
inline std::string to_string( signed int value ) { return make_value_string( value ) ; }
inline std::string to_string( unsigned int value ) { return make_value_string( value ) + sfx("u" ); }
inline std::string to_string( signed long value ) { return make_value_string( value ) + sfx("l" ); }
inline std::string to_string( unsigned long value ) { return make_value_string( value ) + sfx("ul" ); }
inline std::string to_string( signed long long value ) { return make_value_string( value ) + sfx("ll" ); }
inline std::string to_string( unsigned long long value ) { return make_value_string( value ) + sfx("ull"); }
inline std::string to_string( double value ) { return make_value_string( value ) ; }
inline std::string to_string( float value ) { return make_value_string( value ) + sfx("f" ); }
template<typename T>
struct is_streamable
{
template<typename U>
static auto test( int ) -> decltype( std::declval<std::ostream &>() << std::declval<U>(), std::true_type() );
template<typename>
static auto test( ... ) -> std::false_type;
#ifdef _MSC_VER
enum { value = std::is_same< decltype( test<T>(0) ), std::true_type >::value };
#else
static constexpr bool value = std::is_same< decltype( test<T>(0) ), std::true_type >::value;
#endif
};
template<typename T>
struct is_container
{
template<typename U>
static auto test( int ) -> decltype( std::declval<U>().begin() == std::declval<U>().end(), std::true_type() );
template<typename>
static auto test( ... ) -> std::false_type;
#ifdef _MSC_VER
enum { value = std::is_same< decltype( test<T>(0) ), std::true_type >::value };
#else
static constexpr bool value = std::is_same< decltype( test<T>(0) ), std::true_type >::value;
#endif
};
template <typename T, typename R>
using ForEnum = typename std::enable_if< std::is_enum<T>::value, R>::type;
template <typename T, typename R>
using ForNonEnum = typename std::enable_if< ! std::is_enum<T>::value, R>::type;
template <typename T, typename R>
using ForStreamable = typename std::enable_if< is_streamable<T>::value, R>::type;
template <typename T, typename R>
using ForNonStreamable = typename std::enable_if< ! is_streamable<T>::value, R>::type;
template <typename T, typename R>
using ForContainer = typename std::enable_if< is_container<T>::value, R>::type;
template <typename T, typename R>
using ForNonContainer = typename std::enable_if< ! is_container<T>::value, R>::type;
template<typename T>
auto make_enum_string( T const & ) -> ForNonEnum<T, std::string>
{
return text("[type: ") + typeid(T).name() + "]";
}
template<typename T>
auto make_enum_string( T const & item ) -> ForEnum<T, std::string>
{
return to_string( static_cast<typename std::underlying_type<T>::type>( item ) );
}
template<typename T>
auto make_string( T const & item ) -> ForNonStreamable<T, std::string>
{
return make_enum_string( item );
}
template<typename T>
auto make_string( T const & item ) -> ForStreamable<T, std::string>
{
std::ostringstream os; os << item; return os.str();
}
template<typename T>
auto make_string( T * p )-> std::string
{
if ( p ) return make_memory_string( p );
else return "NULL";
}
template<typename C, typename R>
auto make_string( R C::* p ) -> std::string
{
if ( p ) return make_memory_string( p );
else return "NULL";
}
template<typename T1, typename T2>
auto make_string( std::pair<T1,T2> const & pair ) -> std::string
{
std::ostringstream oss;
oss << "{ " << to_string( pair.first ) << ", " << to_string( pair.second ) << " }";
return oss.str();
}
template<typename TU, std::size_t N>
struct make_tuple_string
{
static std::string make( TU const & tuple )
{
std::ostringstream os;
os << to_string( std::get<N - 1>( tuple ) ) << ( N < std::tuple_size<TU>::value ? ", ": " ");
return make_tuple_string<TU, N - 1>::make( tuple ) + os.str();
}
};
template<typename TU>
struct make_tuple_string<TU, 0>
{
static std::string make( TU const & ) { return ""; }
};
template<typename ...TS>
auto make_string( std::tuple<TS...> const & tuple ) -> std::string
{
return "{ " + make_tuple_string<std::tuple<TS...>, sizeof...(TS)>::make( tuple ) + "}";
}
template<typename T>
auto to_string( T const & item ) -> ForNonContainer<T, std::string>
{
return make_string( item );
}
template<typename C>
auto to_string( C const & cont ) -> ForContainer<C, std::string>
{
std::ostringstream os;
os << "{ ";
for ( auto & x : cont )
{
os << to_string( x ) << ", ";
}
os << "}";
return os.str();
}
inline
auto to_string( std::wstring const & text ) -> std::string
{
std::string result; result.reserve( text.size() );
for( auto & chr : text )
{
result += chr <= 0xff ? static_cast<char>( chr ) : '?';
}
return to_string( result );
}
template<typename T>
auto make_value_string( T const & value ) -> std::string
{
std::ostringstream os; os << value; return os.str();
}
inline
auto make_memory_string( void const * item, std::size_t size ) -> std::string
{
// reverse order for little endian architectures:
auto is_little_endian = []
{
union U { int i = 1; char c[ sizeof(int) ]; };
return 1 != U{}.c[ sizeof(int) - 1 ];
};
int i = 0, end = static_cast<int>( size ), inc = 1;
if ( is_little_endian() ) { i = end - 1; end = inc = -1; }
unsigned char const * bytes = static_cast<unsigned char const *>( item );
std::ostringstream os;
os << "0x" << std::setfill( '0' ) << std::hex;
for ( ; i != end; i += inc )
{
os << std::setw(2) << static_cast<unsigned>( bytes[i] ) << " ";
}
return os.str();
}
template<typename T>
auto make_memory_string( T const & item ) -> std::string
{
return make_memory_string( &item, sizeof item );
}
inline
auto to_string( approx const & appr ) -> std::string
{
return to_string( appr.magnitude() );
}
template <typename L, typename R>
auto to_string( L const & lhs, std::string op, R const & rhs ) -> std::string
{
std::ostringstream os; os << to_string( lhs ) << " " << op << " " << to_string( rhs ); return os.str();
}
template <typename L>
struct expression_lhs
{
const L lhs;
expression_lhs( L lhs ) : lhs( lhs ) {}
operator result() { return result{ !!lhs, to_string( lhs ) }; }
template <typename R> result operator==( R const & rhs ) { return result{ lhs == rhs, to_string( lhs, "==", rhs ) }; }
template <typename R> result operator!=( R const & rhs ) { return result{ lhs != rhs, to_string( lhs, "!=", rhs ) }; }
template <typename R> result operator< ( R const & rhs ) { return result{ lhs < rhs, to_string( lhs, "<" , rhs ) }; }
template <typename R> result operator<=( R const & rhs ) { return result{ lhs <= rhs, to_string( lhs, "<=", rhs ) }; }
template <typename R> result operator> ( R const & rhs ) { return result{ lhs > rhs, to_string( lhs, ">" , rhs ) }; }
template <typename R> result operator>=( R const & rhs ) { return result{ lhs >= rhs, to_string( lhs, ">=", rhs ) }; }
};
struct expression_decomposer
{
template <typename L>
expression_lhs<L const &> operator<< ( L const & operand )
{
return expression_lhs<L const &>( operand );
}
};
// Reporter:
#if lest_FEATURE_COLOURISE
inline text red ( text words ) { return "\033[1;31m" + words + "\033[0m"; }
inline text green( text words ) { return "\033[1;32m" + words + "\033[0m"; }
inline text gray ( text words ) { return "\033[1;30m" + words + "\033[0m"; }
inline bool starts_with( text words, text with )
{
return 0 == words.find( with );
}
inline text replace( text words, text from, text to )
{
size_t pos = words.find( from );
return pos == std::string::npos ? words : words.replace( pos, from.length(), to );
}
inline text colour( text words )
{
if ( starts_with( words, "failed" ) ) return replace( words, "failed", red ( "failed" ) );
else if ( starts_with( words, "passed" ) ) return replace( words, "passed", green( "passed" ) );
return replace( words, "for", gray( "for" ) );
}
inline bool is_cout( std::ostream & os ) { return &os == &std::cout; }
struct colourise
{
const text words;
colourise( text words )
: words( words ) {}
// only colourise for std::cout, not for a stringstream as used in tests:
std::ostream & operator()( std::ostream & os ) const
{
return is_cout( os ) ? os << colour( words ) : os << words;
}
};
inline std::ostream & operator<<( std::ostream & os, colourise words ) { return words( os ); }
#else
inline text colourise( text words ) { return words; }
#endif
inline text pluralise( text word, int n )
{
return n == 1 ? word : word + "s";
}
inline std::ostream & operator<<( std::ostream & os, comment note )
{
return os << (note ? " " + note.info : "" );
}
inline std::ostream & operator<<( std::ostream & os, location where )
{
#ifdef __GNUG__
return os << where.file << ":" << where.line;
#else
return os << where.file << "(" << where.line << ")";
#endif
}
inline void report( std::ostream & os, message const & e, text test )
{
os << e.where << ": " << colourise( e.kind ) << e.note << ": " << test << ": " << colourise( e.what() ) << std::endl;
}
// Test runner:
#if lest_FEATURE_REGEX_SEARCH
inline bool search( text re, text line )
{
return std::regex_search( line, std::regex( re ) );
}
#else
inline bool search( text part, text line )
{
auto case_insensitive_equal = []( char a, char b )
{
return tolower( a ) == tolower( b );
};
return std::search(
line.begin(), line.end(),
part.begin(), part.end(), case_insensitive_equal ) != line.end();
}
#endif
inline bool match( texts whats, text line )
{
for ( auto & what : whats )
{
if ( search( what, line ) )
return true;
}
return false;
}
inline bool select( text name, texts include )
{
auto none = []( texts args ) { return args.size() == 0; };
#if lest_FEATURE_REGEX_SEARCH
auto hidden = []( text name ){ return match( { "\\[\\..*", "\\[hide\\]" }, name ); };
#else
auto hidden = []( text name ){ return match( { "[.", "[hide]" }, name ); };
#endif
if ( none( include ) )
{
return ! hidden( name );
}
bool any = false;
for ( auto pos = include.rbegin(); pos != include.rend(); ++pos )
{
auto & part = *pos;
if ( part == "@" || part == "*" )
return true;
if ( search( part, name ) )
return true;
if ( '!' == part[0] )
{
any = true;
if ( search( part.substr(1), name ) )
return false;
}
else
{
any = false;
}
}
return any && ! hidden( name );
}
inline int indefinite( int repeat ) { return repeat == -1; }
using seed_t = unsigned long;
struct options
{
bool help = false;
bool abort = false;
bool count = false;
bool list = false;
bool tags = false;
bool time = false;
bool pass = false;
bool lexical = false;
bool random = false;
bool version = false;
int repeat = 1;
seed_t seed = 0;
};
struct env
{
std::ostream & os;
bool pass;
text testing;
env( std::ostream & os, bool pass )
: os( os ), pass( pass ), testing() {}
env & operator()( text test )
{
testing = test; return *this;
}
};
struct action
{
std::ostream & os;
action( std::ostream & os ) : os( os ) {}
action( action const & ) = delete;
void operator=( action const & ) = delete;
operator int() { return 0; }
bool abort() { return false; }
action & operator()( test ) { return *this; }
};
struct print : action
{
print( std::ostream & os ) : action( os ) {}
print & operator()( test testing )
{
os << testing.name << "\n"; return *this;
}
};
inline texts tags( text name, texts result = {} )
{
auto none = std::string::npos;
auto lb = name.find_first_of( "[" );
auto rb = name.find_first_of( "]" );
if ( lb == none || rb == none )
return result;
result.emplace_back( name.substr( lb, rb - lb + 1 ) );
return tags( name.substr( rb + 1 ), result );
}
struct ptags : action
{
std::set<text> result;
ptags( std::ostream & os ) : action( os ), result() {}
ptags & operator()( test testing )
{
for ( auto & tag : tags( testing.name ) )
result.insert( tag );
return *this;
}
~ptags()
{
std::copy( result.begin(), result.end(), std::ostream_iterator<text>( os, "\n" ) );
}
};
struct count : action
{
int n = 0;
count( std::ostream & os ) : action( os ) {}
count & operator()( test ) { ++n; return *this; }
~count()
{
os << n << " selected " << pluralise("test", n) << "\n";
}
};
struct timer
{
using time = std::chrono::high_resolution_clock;
time::time_point start = time::now();
double elapsed_seconds() const
{
return 1e-6 * std::chrono::duration_cast< std::chrono::microseconds >( time::now() - start ).count();
}
};
struct times : action
{
env output;
options option;
int selected = 0;
int failures = 0;
timer total;
times( std::ostream & os, options option )
: action( os ), output( os, option.pass ), option( option ), total()
{
os << std::setfill(' ') << std::fixed << std::setprecision( lest_FEATURE_TIME_PRECISION );
}
operator int() { return failures; }
bool abort() { return option.abort && failures > 0; }
times & operator()( test testing )
{
timer t;
try
{
testing.behaviour( output( testing.name ) );
}
catch( message const & )
{
++failures;
}
os << std::setw(3) << ( 1000 * t.elapsed_seconds() ) << " ms: " << testing.name << "\n";
return *this;
}
~times()
{
os << "Elapsed time: " << std::setprecision(1) << total.elapsed_seconds() << " s\n";
}
};
struct confirm : action
{
env output;
options option;
int selected = 0;
int failures = 0;
confirm( std::ostream & os, options option )
: action( os ), output( os, option.pass ), option( option ) {}
operator int() { return failures; }
bool abort() { return option.abort && failures > 0; }
confirm & operator()( test testing )
{
try
{
++selected; testing.behaviour( output( testing.name ) );
}
catch( message const & e )
{
++failures; report( os, e, testing.name );
}
return *this;
}
~confirm()
{
if ( failures > 0 )
{
os << failures << " out of " << selected << " selected " << pluralise("test", selected) << " " << colourise( "failed.\n" );
}
else if ( option.pass )
{
os << "All " << selected << " selected " << pluralise("test", selected) << " " << colourise( "passed.\n" );
}
}
};
template<typename Action>
bool abort( Action & perform )
{
return perform.abort();
}
template< typename Action >
Action && for_test( tests specification, texts in, Action && perform, int n = 1 )
{
for ( int i = 0; indefinite( n ) || i < n; ++i )
{
for ( auto & testing : specification )
{
if ( select( testing.name, in ) )
if ( abort( perform( testing ) ) )
return std::move( perform );
}
}
return std::move( perform );
}
inline void sort( tests & specification )
{
auto test_less = []( test const & a, test const & b ) { return a.name < b.name; };
std::sort( specification.begin(), specification.end(), test_less );
}
inline void shuffle( tests & specification, options option )
{
std::shuffle( specification.begin(), specification.end(), std::mt19937( option.seed ) );
}
// workaround MinGW bug, http://stackoverflow.com/a/16132279:
inline int stoi( text num )
{
return static_cast<int>( std::strtol( num.c_str(), NULL, 10 ) );
}
inline bool is_number( text arg )
{
return std::all_of( arg.begin(), arg.end(), ::isdigit );
}
inline seed_t seed( text opt, text arg )
{
if ( is_number( arg ) )
return static_cast<seed_t>( lest::stoi( arg ) );
if ( arg == "time" )
return static_cast<seed_t>( std::chrono::high_resolution_clock::now().time_since_epoch().count() );
throw std::runtime_error( "expecting 'time' or positive number with option '" + opt + "', got '" + arg + "' (try option --help)" );
}
inline int repeat( text opt, text arg )
{
const int num = lest::stoi( arg );
if ( indefinite( num ) || num >= 0 )
return num;
throw std::runtime_error( "expecting '-1' or positive number with option '" + opt + "', got '" + arg + "' (try option --help)" );
}
inline auto split_option( text arg ) -> std::tuple<text, text>
{
auto pos = arg.rfind( '=' );
return pos == text::npos
? std::make_tuple( arg, "" )
: std::make_tuple( arg.substr( 0, pos ), arg.substr( pos + 1 ) );
}
inline auto split_arguments( texts args ) -> std::tuple<options, texts>
{
options option; texts in;
bool in_options = true;
for ( auto & arg : args )
{
if ( in_options )
{
text opt, val;
std::tie( opt, val ) = split_option( arg );
if ( opt[0] != '-' ) { in_options = false; }
else if ( opt == "--" ) { in_options = false; continue; }
else if ( opt == "-h" || "--help" == opt ) { option.help = true; continue; }
else if ( opt == "-a" || "--abort" == opt ) { option.abort = true; continue; }
else if ( opt == "-c" || "--count" == opt ) { option.count = true; continue; }
else if ( opt == "-g" || "--list-tags" == opt ) { option.tags = true; continue; }
else if ( opt == "-l" || "--list-tests" == opt ) { option.list = true; continue; }
else if ( opt == "-t" || "--time" == opt ) { option.time = true; continue; }
else if ( opt == "-p" || "--pass" == opt ) { option.pass = true; continue; }
else if ( "--version" == opt ) { option.version = true; continue; }
else if ( opt == "--order" && "declared" == val ) { /* by definition */ ; continue; }
else if ( opt == "--order" && "lexical" == val ) { option.lexical = true; continue; }
else if ( opt == "--order" && "random" == val ) { option.random = true; continue; }
else if ( opt == "--random-seed" ) { option.seed = seed ( "--random-seed", val ); continue; }
else if ( opt == "--repeat" ) { option.repeat = repeat( "--repeat" , val ); continue; }
else throw std::runtime_error( "unrecognised option '" + arg + "' (try option --help)" );
}
in.push_back( arg );
}
return std::make_tuple( option, in );
}
inline int usage( std::ostream & os )
{
os <<
"\nUsage: test [options] [test-spec ...]\n"
"\n"
"Options:\n"
" -h, --help this help message\n"
" -a, --abort abort at first failure\n"
" -c, --count count selected tests\n"
" -g, --list-tags list tags of selected tests\n"
" -l, --list-tests list selected tests\n"
" -p, --pass also report passing tests\n"
" -t, --time list duration of selected tests\n"
" --order=declared use source code test order (default)\n"
" --order=lexical use lexical sort test order\n"
" --order=random use random test order\n"
" --random-seed=n use n for random generator seed\n"
" --random-seed=time use time for random generator seed\n"
" --repeat=n repeat selected tests n times (-1: indefinite)\n"
" --version report lest version and compiler used\n"
" -- end options\n"
"\n"
"Test specification:\n"
" \"@\", \"*\" all tests, unless excluded\n"
" empty all tests, unless tagged [hide] or [.optional-name]\n"
#if lest_FEATURE_REGEX_SEARCH
" \"re\" select tests that match regular expression\n"
" \"!re\" omit tests that match regular expression\n"
#else
" \"text\" select tests that contain text (case insensitive)\n"
" \"!text\" omit tests that contain text (case insensitive)\n"
#endif
;
return 0;
}
inline text compiler()
{
std::ostringstream os;
#if defined (__clang__ )
os << "clang " << __clang_version__;
#elif defined (__GNUC__ )
os << "gcc " << __GNUC__ << "." << __GNUC_MINOR__ << "." << __GNUC_PATCHLEVEL__;
#elif defined ( _MSC_VER )
os << "MSVC " << (_MSC_VER / 100 - 5 - (_MSC_VER < 1900)) << " (" << _MSC_VER << ")";
#else
os << "[compiler]";
#endif
return os.str();
}
inline int version( std::ostream & os )
{
os << "lest version " << lest_VERSION << "\n"
<< "Compiled with " << compiler() << " on " << __DATE__ << " at " << __TIME__ << ".\n"
<< "For more information, see https://github.com/martinmoene/lest.\n";
return 0;
}
inline int run( tests specification, texts arguments, std::ostream & os = std::cout )
{
try
{
options option; texts in;
std::tie( option, in ) = split_arguments( arguments );
if ( option.lexical ) { sort( specification ); }
if ( option.random ) { shuffle( specification, option ); }
if ( option.help ) { return usage ( os ); }
if ( option.version ) { return version ( os ); }
if ( option.count ) { return for_test( specification, in, count( os ) ); }
if ( option.list ) { return for_test( specification, in, print( os ) ); }
if ( option.tags ) { return for_test( specification, in, ptags( os ) ); }
if ( option.time ) { return for_test( specification, in, times( os, option ) ); }
return for_test( specification, in, confirm( os, option ), option.repeat );
}
catch ( std::exception const & e )
{
os << "Error: " << e.what() << "\n";
return 1;
}
}
inline int run( tests specification, int argc, char * argv[], std::ostream & os = std::cout )
{
return run( specification, texts( argv + 1, argv + argc ), os );
}
template <std::size_t N>
int run( test const (&specification)[N], texts arguments, std::ostream & os = std::cout )
{
return run( tests( specification, specification + N ), arguments, os );
}
template <std::size_t N>
int run( test const (&specification)[N], std::ostream & os = std::cout )
{
return run( tests( specification, specification + N ), {}, os );
}
template <std::size_t N>
int run( test const (&specification)[N], int argc, char * argv[], std::ostream & os = std::cout )
{
return run( tests( specification, specification + N ), texts( argv + 1, argv + argc ), os );
}
} // namespace lest
#endif // LEST_LEST_HPP_INCLUDED