#ifndef BOOST_NUMERIC_UTILITY_HPP #define BOOST_NUMERIC_UTILITY_HPP // Copyright (c) 2015 Robert Ramey // // 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) #include // intmax_t, uintmax_t, uint8_t, ... #include #include // conditional #include #include #include // pair #include // (u)int_t<>::least, exact namespace boost { namespace safe_numerics { namespace utility { /////////////////////////////////////////////////////////////////////////////// // used for debugging // provokes warning message with names of type T // usage - print_types; // see https://cukic.co/2019/02/19/tmp-testing-and-debugging-templates /* template using print_type = typename Tx::error_message; */ template struct [[deprecated]] print_types {}; // display value of constexpr during compilation // usage print_value(N) pn; template struct print_value { enum test : char { value = N < 0 ? N - 256 : N + 256 }; }; #if 0 // static warning - same as static_assert but doesn't // stop compilation. template struct static_test{}; template <> struct static_test{ [[deprecated]] static_test(){} }; template constexpr void inline static_warning(const T){ //using x = static_test; const static_test x; } #endif /* // can be called by constexpr to produce a compile time // trap of parameter passed is false. // usage constexpr_assert(bool) constexpr int constexpr_assert(const bool tf){ return 1 / tf; } */ /////////////////////////////////////////////////////////////////////////////// // return an integral constant equal to the the number of bits // held by some integer type (including the sign bit) template using bits_type = std::integral_constant< int, std::numeric_limits::digits + (std::numeric_limits::is_signed ? 1 : 0) >; /* From http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogObvious Find the log base 2 of an integer with a lookup table static const char LogTable256[256] = { #define LT(n) n, n, n, n, n, n, n, n, n, n, n, n, n, n, n, n -1, 0, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, LT(4), LT(5), LT(5), LT(6), LT(6), LT(6), LT(6), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7) }; unsigned int v; // 32-bit word to find the log of unsigned r; // r will be lg(v) register unsigned int t, tt; // temporaries if (tt = v >> 16) { r = (t = tt >> 8) ? 24 + LogTable256[t] : 16 + LogTable256[tt]; } else { r = (t = v >> 8) ? 8 + LogTable256[t] : LogTable256[v]; } The lookup table method takes only about 7 operations to find the log of a 32-bit value. If extended for 64-bit quantities, it would take roughly 9 operations. Another operation can be trimmed off by using four tables, with the possible additions incorporated into each. Using int table elements may be faster, depending on your architecture. */ namespace ilog2_detail { template constexpr inline unsigned int ilog2(const typename boost::uint_t::exact & t){ using half_type = typename boost::uint_t::exact; const half_type upper_half = static_cast(t >> N/2); const half_type lower_half = static_cast(t); return upper_half == 0 ? ilog2(lower_half) : N/2 + ilog2(upper_half); } template<> constexpr inline unsigned int ilog2<8>(const typename boost::uint_t<8>::exact & t){ #define LT(n) n, n, n, n, n, n, n, n, n, n, n, n, n, n, n, n const char LogTable256[256] = { static_cast(-1), 0, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, LT(4), LT(5), LT(5), LT(6), LT(6), LT(6), LT(6), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7) }; return LogTable256[t]; } } // ilog2_detail template constexpr inline unsigned int ilog2(const T & t){ // log not defined for negative numbers // assert(t > 0); if(t == 0) return 0; return ilog2_detail::ilog2::value>( static_cast< typename boost::uint_t< bits_type::value >::least >(t) ); } // the number of bits required to render the value in x // including sign bit template constexpr inline unsigned int significant_bits(const T & t){ return 1 + ((t < 0) ? ilog2(~t) : ilog2(t)); } /* // give the value t, return the number which corresponds // to all 1's which is higher than that number template constexpr unsigned int bits_value(const T & t){ const unsigned int sb = significant_bits(t); const unsigned int sb_max = significant_bits(std::numeric_limits::max()); return sb < sb_max ? ((sb << 1) - 1) : std::numeric_limits::max(); } */ /////////////////////////////////////////////////////////////////////////////// // meta functions returning types // If we use std::max in here we get internal compiler errors // with MSVC (tested VC2017) ... // Notes from https://en.cppreference.com/w/cpp/algorithm/max // Capturing the result of std::max by reference if one of the parameters // is rvalue produces a dangling reference if that parameter is returned. template // turns out this problem crashes all versions of gcc compilers. So // make sure we return by value //constexpr const T & max( constexpr inline T max( const T & lhs, const T & rhs ){ return lhs > rhs ? lhs : rhs; } // given a signed range, return type required to hold all the values // in the range template< std::intmax_t Min, std::intmax_t Max > using signed_stored_type = typename boost::int_t< max( significant_bits(Min), significant_bits(Max) ) + 1 >::least ; // given an unsigned range, return type required to hold all the values // in the range template< std::uintmax_t Min, std::uintmax_t Max > // unsigned range using unsigned_stored_type = typename boost::uint_t< significant_bits(Max) >::least; /////////////////////////////////////////////////////////////////////////////// // constexpr functions // need our own version because official version // a) is not constexpr // b) is not guarenteed to handle non-assignable types template constexpr inline std::pair minmax(const std::initializer_list & l){ assert(l.size() > 0); const T * minimum = l.begin(); const T * maximum = l.begin(); for(const T * i = l.begin(); i != l.end(); ++i){ if(*i < * minimum) minimum = i; else if(* maximum < *i) maximum = i; } return std::pair{* minimum, * maximum}; } // for any given t // a) figure number of significant bits // b) return a value with all significant bits set // so for example: // 3 == round_out(2) because // 2 == 10 and 3 == 11 template constexpr inline T round_out(const T & t){ if(t >= 0){ const std::uint8_t sb = utility::significant_bits(t); return (sb < sizeof(T) * 8) ? ((T)1 << sb) - 1 : std::numeric_limits::max(); } else{ const std::uint8_t sb = utility::significant_bits(~t); return (sb < sizeof(T) * 8) ? ~(((T)1 << sb) - 1) : std::numeric_limits::min(); } } } // utility } // safe_numerics } // boost #endif // BOOST_NUMERIC_UTILITY_HPP