Mercurial > hg > vamp-build-and-test
view DEPENDENCIES/generic/include/boost/math/policies/error_handling.hpp @ 103:ccaadfc1e6d1
Ignore some more stuff
| author | Chris Cannam |
|---|---|
| date | Mon, 07 Sep 2015 11:15:24 +0100 |
| parents | c530137014c0 |
| children |
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// Copyright John Maddock 2007. // Copyright Paul A. Bristow 2007. // Use, modification and distribution are subject to 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 BOOST_MATH_POLICY_ERROR_HANDLING_HPP #define BOOST_MATH_POLICY_ERROR_HANDLING_HPP #include <stdexcept> #include <iomanip> #include <string> #include <cerrno> #include <boost/config/no_tr1/complex.hpp> #include <boost/config/no_tr1/cmath.hpp> #include <stdexcept> #include <boost/math/tools/config.hpp> #include <boost/math/policies/policy.hpp> #include <boost/math/tools/precision.hpp> #include <boost/cstdint.hpp> #ifdef BOOST_MSVC # pragma warning(push) // Quiet warnings in boost/format.hpp # pragma warning(disable: 4996) // _SCL_SECURE_NO_DEPRECATE # pragma warning(disable: 4512) // assignment operator could not be generated. // And warnings in error handling: # pragma warning(disable: 4702) // unreachable code. // Note that this only occurs when the compiler can deduce code is unreachable, // for example when policy macros are used to ignore errors rather than throw. #endif #include <boost/format.hpp> namespace boost{ namespace math{ class evaluation_error : public std::runtime_error { public: evaluation_error(const std::string& s) : std::runtime_error(s){} }; class rounding_error : public std::runtime_error { public: rounding_error(const std::string& s) : std::runtime_error(s){} }; namespace policies{ // // Forward declarations of user error handlers, // it's up to the user to provide the definition of these: // template <class T> T user_domain_error(const char* function, const char* message, const T& val); template <class T> T user_pole_error(const char* function, const char* message, const T& val); template <class T> T user_overflow_error(const char* function, const char* message, const T& val); template <class T> T user_underflow_error(const char* function, const char* message, const T& val); template <class T> T user_denorm_error(const char* function, const char* message, const T& val); template <class T> T user_evaluation_error(const char* function, const char* message, const T& val); template <class T, class TargetType> T user_rounding_error(const char* function, const char* message, const T& val, const TargetType& t); template <class T> T user_indeterminate_result_error(const char* function, const char* message, const T& val); namespace detail { // // Helper function to avoid binding rvalue to non-const-reference, // in other words a warning suppression mechanism: // template <class Formatter, class Group> inline std::string do_format(Formatter f, const Group& g) { return (f % g).str(); } template <class T> inline const char* name_of() { #ifndef BOOST_NO_RTTI return typeid(T).name(); #else return "unknown"; #endif } template <> inline const char* name_of<float>(){ return "float"; } template <> inline const char* name_of<double>(){ return "double"; } template <> inline const char* name_of<long double>(){ return "long double"; } #ifdef BOOST_MATH_USE_FLOAT128 template <> inline const char* name_of<BOOST_MATH_FLOAT128_TYPE>() { return "__float128"; } #endif template <class E, class T> void raise_error(const char* function, const char* message) { if(function == 0) function = "Unknown function operating on type %1%"; if(message == 0) message = "Cause unknown"; std::string msg("Error in function "); #ifndef BOOST_NO_RTTI msg += (boost::format(function) % boost::math::policies::detail::name_of<T>()).str(); #else msg += function; #endif msg += ": "; msg += message; E e(msg); boost::throw_exception(e); } template <class E, class T> void raise_error(const char* function, const char* message, const T& val) { if(function == 0) function = "Unknown function operating on type %1%"; if(message == 0) message = "Cause unknown: error caused by bad argument with value %1%"; std::string msg("Error in function "); #ifndef BOOST_NO_RTTI msg += (boost::format(function) % boost::math::policies::detail::name_of<T>()).str(); #else msg += function; #endif msg += ": "; msg += message; int prec = 2 + (boost::math::policies::digits<T, boost::math::policies::policy<> >() * 30103UL) / 100000UL; msg = do_format(boost::format(msg), boost::io::group(std::setprecision(prec), val)); E e(msg); boost::throw_exception(e); } template <class T> inline T raise_domain_error( const char* function, const char* message, const T& val, const ::boost::math::policies::domain_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::domain_error, T>(function, message, val); // we never get here: return std::numeric_limits<T>::quiet_NaN(); } template <class T> inline T raise_domain_error( const char* , const char* , const T& , const ::boost::math::policies::domain_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return std::numeric_limits<T>::quiet_NaN(); } template <class T> inline T raise_domain_error( const char* , const char* , const T& , const ::boost::math::policies::domain_error< ::boost::math::policies::errno_on_error>&) { errno = EDOM; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return std::numeric_limits<T>::quiet_NaN(); } template <class T> inline T raise_domain_error( const char* function, const char* message, const T& val, const ::boost::math::policies::domain_error< ::boost::math::policies::user_error>&) { return user_domain_error(function, message, val); } template <class T> inline T raise_pole_error( const char* function, const char* message, const T& val, const ::boost::math::policies::pole_error< ::boost::math::policies::throw_on_error>&) { return boost::math::policies::detail::raise_domain_error(function, message, val, ::boost::math::policies::domain_error< ::boost::math::policies::throw_on_error>()); } template <class T> inline T raise_pole_error( const char* function, const char* message, const T& val, const ::boost::math::policies::pole_error< ::boost::math::policies::ignore_error>&) { return ::boost::math::policies::detail::raise_domain_error(function, message, val, ::boost::math::policies::domain_error< ::boost::math::policies::ignore_error>()); } template <class T> inline T raise_pole_error( const char* function, const char* message, const T& val, const ::boost::math::policies::pole_error< ::boost::math::policies::errno_on_error>&) { return ::boost::math::policies::detail::raise_domain_error(function, message, val, ::boost::math::policies::domain_error< ::boost::math::policies::errno_on_error>()); } template <class T> inline T raise_pole_error( const char* function, const char* message, const T& val, const ::boost::math::policies::pole_error< ::boost::math::policies::user_error>&) { return user_pole_error(function, message, val); } template <class T> inline T raise_overflow_error( const char* function, const char* message, const ::boost::math::policies::overflow_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::overflow_error, T>(function, message ? message : "numeric overflow"); // We should never get here: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* function, const char* message, const T& val, const ::boost::math::policies::overflow_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::overflow_error, T>(function, message ? message : "numeric overflow", val); // We should never get here: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* , const char* , const ::boost::math::policies::overflow_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* , const char* , const T&, const ::boost::math::policies::overflow_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* , const char* , const ::boost::math::policies::overflow_error< ::boost::math::policies::errno_on_error>&) { errno = ERANGE; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* , const char* , const T&, const ::boost::math::policies::overflow_error< ::boost::math::policies::errno_on_error>&) { errno = ERANGE; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return std::numeric_limits<T>::has_infinity ? std::numeric_limits<T>::infinity() : boost::math::tools::max_value<T>(); } template <class T> inline T raise_overflow_error( const char* function, const char* message, const ::boost::math::policies::overflow_error< ::boost::math::policies::user_error>&) { return user_overflow_error(function, message, std::numeric_limits<T>::infinity()); } template <class T> inline T raise_overflow_error( const char* function, const char* message, const T& val, const ::boost::math::policies::overflow_error< ::boost::math::policies::user_error>&) { std::string fmsg("Error in function "); #ifndef BOOST_NO_RTTI fmsg += (boost::format(function) % boost::math::policies::detail::name_of<T>()).str(); #else fmsg += function; #endif int prec = 2 + (boost::math::policies::digits<T, boost::math::policies::policy<> >() * 30103UL) / 100000UL; std::string msg = do_format(boost::format(message), boost::io::group(std::setprecision(prec), val)); return user_overflow_error(fmsg.c_str(), msg.c_str(), std::numeric_limits<T>::infinity()); } template <class T> inline T raise_underflow_error( const char* function, const char* message, const ::boost::math::policies::underflow_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::underflow_error, T>(function, message ? message : "numeric underflow"); // We should never get here: return 0; } template <class T> inline T raise_underflow_error( const char* , const char* , const ::boost::math::policies::underflow_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return T(0); } template <class T> inline T raise_underflow_error( const char* /* function */, const char* /* message */, const ::boost::math::policies::underflow_error< ::boost::math::policies::errno_on_error>&) { errno = ERANGE; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return T(0); } template <class T> inline T raise_underflow_error( const char* function, const char* message, const ::boost::math::policies::underflow_error< ::boost::math::policies::user_error>&) { return user_underflow_error(function, message, T(0)); } template <class T> inline T raise_denorm_error( const char* function, const char* message, const T& /* val */, const ::boost::math::policies::denorm_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::underflow_error, T>(function, message ? message : "denormalised result"); // we never get here: return T(0); } template <class T> inline T raise_denorm_error( const char* , const char* , const T& val, const ::boost::math::policies::denorm_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return val; } template <class T> inline T raise_denorm_error( const char* , const char* , const T& val, const ::boost::math::policies::denorm_error< ::boost::math::policies::errno_on_error>&) { errno = ERANGE; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return val; } template <class T> inline T raise_denorm_error( const char* function, const char* message, const T& val, const ::boost::math::policies::denorm_error< ::boost::math::policies::user_error>&) { return user_denorm_error(function, message, val); } template <class T> inline T raise_evaluation_error( const char* function, const char* message, const T& val, const ::boost::math::policies::evaluation_error< ::boost::math::policies::throw_on_error>&) { raise_error<boost::math::evaluation_error, T>(function, message, val); // we never get here: return T(0); } template <class T> inline T raise_evaluation_error( const char* , const char* , const T& val, const ::boost::math::policies::evaluation_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return val; } template <class T> inline T raise_evaluation_error( const char* , const char* , const T& val, const ::boost::math::policies::evaluation_error< ::boost::math::policies::errno_on_error>&) { errno = EDOM; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return val; } template <class T> inline T raise_evaluation_error( const char* function, const char* message, const T& val, const ::boost::math::policies::evaluation_error< ::boost::math::policies::user_error>&) { return user_evaluation_error(function, message, val); } template <class T, class TargetType> inline TargetType raise_rounding_error( const char* function, const char* message, const T& val, const TargetType&, const ::boost::math::policies::rounding_error< ::boost::math::policies::throw_on_error>&) { raise_error<boost::math::rounding_error, T>(function, message, val); // we never get here: return TargetType(0); } template <class T, class TargetType> inline TargetType raise_rounding_error( const char* , const char* , const T& val, const TargetType&, const ::boost::math::policies::rounding_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: BOOST_STATIC_ASSERT(std::numeric_limits<TargetType>::is_specialized); return val > 0 ? (std::numeric_limits<TargetType>::max)() : (std::numeric_limits<TargetType>::is_integer ? (std::numeric_limits<TargetType>::min)() : -(std::numeric_limits<TargetType>::max)()); } template <class T, class TargetType> inline TargetType raise_rounding_error( const char* , const char* , const T& val, const TargetType&, const ::boost::math::policies::rounding_error< ::boost::math::policies::errno_on_error>&) { errno = ERANGE; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: BOOST_STATIC_ASSERT(std::numeric_limits<TargetType>::is_specialized); return val > 0 ? (std::numeric_limits<TargetType>::max)() : (std::numeric_limits<TargetType>::is_integer ? (std::numeric_limits<TargetType>::min)() : -(std::numeric_limits<TargetType>::max)()); } template <class T, class TargetType> inline TargetType raise_rounding_error( const char* function, const char* message, const T& val, const TargetType& t, const ::boost::math::policies::rounding_error< ::boost::math::policies::user_error>&) { return user_rounding_error(function, message, val, t); } template <class T, class R> inline T raise_indeterminate_result_error( const char* function, const char* message, const T& val, const R& , const ::boost::math::policies::indeterminate_result_error< ::boost::math::policies::throw_on_error>&) { raise_error<std::domain_error, T>(function, message, val); // we never get here: return std::numeric_limits<T>::quiet_NaN(); } template <class T, class R> inline T raise_indeterminate_result_error( const char* , const char* , const T& , const R& result, const ::boost::math::policies::indeterminate_result_error< ::boost::math::policies::ignore_error>&) { // This may or may not do the right thing, but the user asked for the error // to be ignored so here we go anyway: return result; } template <class T, class R> inline T raise_indeterminate_result_error( const char* , const char* , const T& , const R& result, const ::boost::math::policies::indeterminate_result_error< ::boost::math::policies::errno_on_error>&) { errno = EDOM; // This may or may not do the right thing, but the user asked for the error // to be silent so here we go anyway: return result; } template <class T, class R> inline T raise_indeterminate_result_error( const char* function, const char* message, const T& val, const R& , const ::boost::math::policies::indeterminate_result_error< ::boost::math::policies::user_error>&) { return user_indeterminate_result_error(function, message, val); } } // namespace detail template <class T, class Policy> inline T raise_domain_error(const char* function, const char* message, const T& val, const Policy&) { typedef typename Policy::domain_error_type policy_type; return detail::raise_domain_error( function, message ? message : "Domain Error evaluating function at %1%", val, policy_type()); } template <class T, class Policy> inline T raise_pole_error(const char* function, const char* message, const T& val, const Policy&) { typedef typename Policy::pole_error_type policy_type; return detail::raise_pole_error( function, message ? message : "Evaluation of function at pole %1%", val, policy_type()); } template <class T, class Policy> inline T raise_overflow_error(const char* function, const char* message, const Policy&) { typedef typename Policy::overflow_error_type policy_type; return detail::raise_overflow_error<T>( function, message ? message : "Overflow Error", policy_type()); } template <class T, class Policy> inline T raise_overflow_error(const char* function, const char* message, const T& val, const Policy&) { typedef typename Policy::overflow_error_type policy_type; return detail::raise_overflow_error( function, message ? message : "Overflow evaluating function at %1%", val, policy_type()); } template <class T, class Policy> inline T raise_underflow_error(const char* function, const char* message, const Policy&) { typedef typename Policy::underflow_error_type policy_type; return detail::raise_underflow_error<T>( function, message ? message : "Underflow Error", policy_type()); } template <class T, class Policy> inline T raise_denorm_error(const char* function, const char* message, const T& val, const Policy&) { typedef typename Policy::denorm_error_type policy_type; return detail::raise_denorm_error<T>( function, message ? message : "Denorm Error", val, policy_type()); } template <class T, class Policy> inline T raise_evaluation_error(const char* function, const char* message, const T& val, const Policy&) { typedef typename Policy::evaluation_error_type policy_type; return detail::raise_evaluation_error( function, message ? message : "Internal Evaluation Error, best value so far was %1%", val, policy_type()); } template <class T, class TargetType, class Policy> inline TargetType raise_rounding_error(const char* function, const char* message, const T& val, const TargetType& t, const Policy&) { typedef typename Policy::rounding_error_type policy_type; return detail::raise_rounding_error( function, message ? message : "Value %1% can not be represented in the target integer type.", val, t, policy_type()); } template <class T, class R, class Policy> inline T raise_indeterminate_result_error(const char* function, const char* message, const T& val, const R& result, const Policy&) { typedef typename Policy::indeterminate_result_error_type policy_type; return detail::raise_indeterminate_result_error( function, message ? message : "Indeterminate result with value %1%", val, result, policy_type()); } // // checked_narrowing_cast: // namespace detail { template <class R, class T, class Policy> inline bool check_overflow(T val, R* result, const char* function, const Policy& pol) { BOOST_MATH_STD_USING if(fabs(val) > tools::max_value<R>()) { boost::math::policies::detail::raise_overflow_error<R>(function, 0, pol); *result = static_cast<R>(val); return true; } return false; } template <class R, class T, class Policy> inline bool check_overflow(std::complex<T> val, R* result, const char* function, const Policy& pol) { typedef typename R::value_type r_type; r_type re, im; bool r = check_overflow<r_type>(val.real(), &re, function, pol); r = check_overflow<r_type>(val.imag(), &im, function, pol) || r; *result = R(re, im); return r; } template <class R, class T, class Policy> inline bool check_underflow(T val, R* result, const char* function, const Policy& pol) { if((val != 0) && (static_cast<R>(val) == 0)) { *result = static_cast<R>(boost::math::policies::detail::raise_underflow_error<R>(function, 0, pol)); return true; } return false; } template <class R, class T, class Policy> inline bool check_underflow(std::complex<T> val, R* result, const char* function, const Policy& pol) { typedef typename R::value_type r_type; r_type re, im; bool r = check_underflow<r_type>(val.real(), &re, function, pol); r = check_underflow<r_type>(val.imag(), &im, function, pol) || r; *result = R(re, im); return r; } template <class R, class T, class Policy> inline bool check_denorm(T val, R* result, const char* function, const Policy& pol) { BOOST_MATH_STD_USING if((fabs(val) < static_cast<T>(tools::min_value<R>())) && (static_cast<R>(val) != 0)) { *result = static_cast<R>(boost::math::policies::detail::raise_denorm_error<R>(function, 0, static_cast<R>(val), pol)); return true; } return false; } template <class R, class T, class Policy> inline bool check_denorm(std::complex<T> val, R* result, const char* function, const Policy& pol) { typedef typename R::value_type r_type; r_type re, im; bool r = check_denorm<r_type>(val.real(), &re, function, pol); r = check_denorm<r_type>(val.imag(), &im, function, pol) || r; *result = R(re, im); return r; } // Default instantiations with ignore_error policy. template <class R, class T> inline bool check_overflow(T /* val */, R* /* result */, const char* /* function */, const overflow_error<ignore_error>&){ return false; } template <class R, class T> inline bool check_overflow(std::complex<T> /* val */, R* /* result */, const char* /* function */, const overflow_error<ignore_error>&){ return false; } template <class R, class T> inline bool check_underflow(T /* val */, R* /* result */, const char* /* function */, const underflow_error<ignore_error>&){ return false; } template <class R, class T> inline bool check_underflow(std::complex<T> /* val */, R* /* result */, const char* /* function */, const underflow_error<ignore_error>&){ return false; } template <class R, class T> inline bool check_denorm(T /* val */, R* /* result*/, const char* /* function */, const denorm_error<ignore_error>&){ return false; } template <class R, class T> inline bool check_denorm(std::complex<T> /* val */, R* /* result*/, const char* /* function */, const denorm_error<ignore_error>&){ return false; } } // namespace detail template <class R, class Policy, class T> inline R checked_narrowing_cast(T val, const char* function) { typedef typename Policy::overflow_error_type overflow_type; typedef typename Policy::underflow_error_type underflow_type; typedef typename Policy::denorm_error_type denorm_type; // // Most of what follows will evaluate to a no-op: // R result = 0; if(detail::check_overflow<R>(val, &result, function, overflow_type())) return result; if(detail::check_underflow<R>(val, &result, function, underflow_type())) return result; if(detail::check_denorm<R>(val, &result, function, denorm_type())) return result; return static_cast<R>(val); } template <class T, class Policy> inline void check_series_iterations(const char* function, boost::uintmax_t max_iter, const Policy& pol) { if(max_iter >= policies::get_max_series_iterations<Policy>()) raise_evaluation_error<T>( function, "Series evaluation exceeded %1% iterations, giving up now.", static_cast<T>(static_cast<double>(max_iter)), pol); } template <class T, class Policy> inline void check_root_iterations(const char* function, boost::uintmax_t max_iter, const Policy& pol) { if(max_iter >= policies::get_max_root_iterations<Policy>()) raise_evaluation_error<T>( function, "Root finding evaluation exceeded %1% iterations, giving up now.", static_cast<T>(static_cast<double>(max_iter)), pol); } } //namespace policies namespace detail{ // // Simple helper function to assist in returning a pair from a single value, // that value usually comes from one of the error handlers above: // template <class T> std::pair<T, T> pair_from_single(const T& val) { return std::make_pair(val, val); } } #ifdef BOOST_MSVC # pragma warning(pop) #endif }} // namespaces boost/math #endif // BOOST_MATH_POLICY_ERROR_HANDLING_HPP