boost/multiprecision/cpp_int/import_export.hpp
/////////////////////////////////////////////////////////////// // Copyright 2015 John Maddock. Distributed under the Boost // Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at https://www.boost.org/LICENSE_1_0.txt #ifndef BOOST_MP_CPP_INT_IMPORT_EXPORT_HPP #define BOOST_MP_CPP_INT_IMPORT_EXPORT_HPP #include <climits> #include <cstring> #include <boost/multiprecision/detail/endian.hpp> namespace boost { namespace multiprecision { namespace detail { template <class Backend, class Unsigned> void assign_bits(Backend& val, Unsigned bits, std::size_t bit_location, std::size_t chunk_bits, const std::integral_constant<bool, false>& tag) { std::size_t limb = bit_location / (sizeof(limb_type) * CHAR_BIT); std::size_t shift = bit_location % (sizeof(limb_type) * CHAR_BIT); limb_type mask = chunk_bits >= sizeof(limb_type) * CHAR_BIT ? ~static_cast<limb_type>(0u) : (static_cast<limb_type>(1u) << chunk_bits) - 1; limb_type value = static_cast<limb_type>(bits & mask) << shift; if (value) { if (val.size() == limb) { val.resize(limb + 1, limb + 1); if (val.size() > limb) val.limbs()[limb] = value; } else if (val.size() > limb) val.limbs()[limb] |= value; } if (chunk_bits > sizeof(limb_type) * CHAR_BIT - shift) { shift = sizeof(limb_type) * CHAR_BIT - shift; chunk_bits -= shift; bit_location += shift; bits >>= shift; if (bits) assign_bits(val, bits, bit_location, chunk_bits, tag); } } template <class Backend, class Unsigned> void assign_bits(Backend& val, Unsigned bits, std::size_t bit_location, std::size_t chunk_bits, const std::integral_constant<bool, true>&) { using local_limb_type = typename Backend::local_limb_type; // // Check for possible overflow, this may trigger an exception, or have no effect // depending on whether this is a checked integer or not: // if ((bit_location >= sizeof(local_limb_type) * CHAR_BIT) && bits) val.resize(2, 2); else { local_limb_type mask = chunk_bits >= sizeof(local_limb_type) * CHAR_BIT ? ~static_cast<local_limb_type>(0u) : (static_cast<local_limb_type>(1u) << chunk_bits) - 1; local_limb_type value = (static_cast<local_limb_type>(bits) & mask) << bit_location; *val.limbs() |= value; // // Check for overflow bits: // bit_location = sizeof(local_limb_type) * CHAR_BIT - bit_location; if ((bit_location < sizeof(bits) * CHAR_BIT) && (bits >>= bit_location)) val.resize(2, 2); // May throw! } } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator> inline void resize_to_bit_size(cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>& newval, std::size_t bits, const std::integral_constant<bool, false>&) { std::size_t limb_count = static_cast<unsigned>(bits / (sizeof(limb_type) * CHAR_BIT)); if (bits % (sizeof(limb_type) * CHAR_BIT)) ++limb_count; constexpr std::size_t max_limbs = MaxBits ? MaxBits / (CHAR_BIT * sizeof(limb_type)) + ((MaxBits % (CHAR_BIT * sizeof(limb_type))) ? 1 : 0) : (std::numeric_limits<unsigned>::max)(); if (limb_count > max_limbs) limb_count = max_limbs; newval.resize(limb_count, limb_count); std::memset(newval.limbs(), 0, newval.size() * sizeof(limb_type)); } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator> inline void resize_to_bit_size(cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>& newval, unsigned, const std::integral_constant<bool, true>&) { *newval.limbs() = 0; } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class Iterator> number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& import_bits_generic( number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, Iterator i, Iterator j, std::size_t chunk_size = 0, bool msv_first = true) { typename number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>::backend_type newval; using value_type = typename std::iterator_traits<Iterator>::value_type ; using unsigned_value_type = typename boost::multiprecision::detail::make_unsigned<value_type>::type ; using difference_type = typename std::iterator_traits<Iterator>::difference_type ; using size_type = typename boost::multiprecision::detail::make_unsigned<difference_type>::type ; using tag_type = typename cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>::trivial_tag; if (!chunk_size) chunk_size = std::numeric_limits<value_type>::digits; size_type limbs = std::distance(i, j); size_type bits = limbs * chunk_size; detail::resize_to_bit_size(newval, static_cast<unsigned>(bits), tag_type()); difference_type bit_location = msv_first ? bits - chunk_size : 0; difference_type bit_location_change = msv_first ? -static_cast<difference_type>(chunk_size) : chunk_size; while (i != j) { detail::assign_bits(newval, static_cast<unsigned_value_type>(*i), static_cast<std::size_t>(bit_location), chunk_size, tag_type()); ++i; bit_location += bit_location_change; } newval.normalize(); val.backend().swap(newval); return val; } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class T> inline typename std::enable_if< !boost::multiprecision::backends::is_trivial_cpp_int<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator> >::value, number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>&>::type import_bits_fast( number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, T* i, T* j, std::size_t chunk_size = 0) { std::size_t byte_len = (j - i) * (chunk_size ? chunk_size / CHAR_BIT : sizeof(*i)); std::size_t limb_len = byte_len / sizeof(limb_type); if (byte_len % sizeof(limb_type)) ++limb_len; cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>& result = val.backend(); result.resize(static_cast<unsigned>(limb_len), static_cast<unsigned>(limb_len)); // checked types may throw here if they're not large enough to hold the data! result.limbs()[result.size() - 1] = 0u; std::memcpy(result.limbs(), i, (std::min)(byte_len, result.size() * sizeof(limb_type))); result.normalize(); // In case data has leading zeros. return val; } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class T> inline typename std::enable_if<boost::multiprecision::backends::is_trivial_cpp_int<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator> >::value, number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>&>::type import_bits_fast( number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, T* i, T* j, std::size_t chunk_size = 0) { cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>& result = val.backend(); std::size_t byte_len = (j - i) * (chunk_size ? chunk_size / CHAR_BIT : sizeof(*i)); std::size_t limb_len = byte_len / sizeof(result.limbs()[0]); if (byte_len % sizeof(result.limbs()[0])) ++limb_len; result.limbs()[0] = 0u; result.resize(static_cast<unsigned>(limb_len), static_cast<unsigned>(limb_len)); // checked types may throw here if they're not large enough to hold the data! std::memcpy(result.limbs(), i, (std::min)(byte_len, result.size() * sizeof(result.limbs()[0]))); result.normalize(); // In case data has leading zeros. return val; } } // namespace detail template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class Iterator> inline number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& import_bits( number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, Iterator i, Iterator j, std::size_t chunk_size = 0, bool msv_first = true) { return detail::import_bits_generic(val, i, j, chunk_size, msv_first); } template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class T> inline number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& import_bits( number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, T* i, T* j, std::size_t chunk_size = 0, bool msv_first = true) { #if BOOST_MP_ENDIAN_LITTLE_BYTE if (((chunk_size % CHAR_BIT) == 0) && !msv_first && (sizeof(*i) * CHAR_BIT == chunk_size)) return detail::import_bits_fast(val, i, j, chunk_size); #endif return detail::import_bits_generic(val, i, j, chunk_size, msv_first); } namespace detail { template <class Backend> std::uintmax_t extract_bits(const Backend& val, std::size_t location, std::size_t count, const std::integral_constant<bool, false>& tag) { std::size_t limb = location / (sizeof(limb_type) * CHAR_BIT); std::size_t shift = location % (sizeof(limb_type) * CHAR_BIT); std::uintmax_t result = 0; std::uintmax_t mask = count == std::numeric_limits<std::uintmax_t>::digits ? ~static_cast<std::uintmax_t>(0) : (static_cast<std::uintmax_t>(1u) << count) - 1; if (count > (sizeof(limb_type) * CHAR_BIT - shift)) { result = extract_bits(val, location + sizeof(limb_type) * CHAR_BIT - shift, count - sizeof(limb_type) * CHAR_BIT + shift, tag); result <<= sizeof(limb_type) * CHAR_BIT - shift; } if (limb < val.size()) result |= (val.limbs()[limb] >> shift) & mask; return result; } template <class Backend> inline std::uintmax_t extract_bits(const Backend& val, std::size_t location, std::size_t count, const std::integral_constant<bool, true>&) { typename Backend::local_limb_type result = *val.limbs(); typename Backend::local_limb_type mask = count >= std::numeric_limits<typename Backend::local_limb_type>::digits ? ~static_cast<typename Backend::local_limb_type>(0) : (static_cast<typename Backend::local_limb_type>(1u) << count) - 1; return (result >> location) & mask; } } // namespace detail template <std::size_t MinBits, std::size_t MaxBits, cpp_integer_type SignType, cpp_int_check_type Checked, class Allocator, expression_template_option ExpressionTemplates, class OutputIterator> OutputIterator export_bits( const number<cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>, ExpressionTemplates>& val, OutputIterator out, std::size_t chunk_size, bool msv_first = true) { #ifdef BOOST_MSVC #pragma warning(push) #pragma warning(disable : 4244) #endif using tag_type = typename cpp_int_backend<MinBits, MaxBits, SignType, Checked, Allocator>::trivial_tag; if (!val) { *out = 0; ++out; return out; } std::size_t bitcount = boost::multiprecision::backends::eval_msb_imp(val.backend()) + 1; std::ptrdiff_t bit_location = msv_first ? static_cast<std::ptrdiff_t>(bitcount - chunk_size) : 0; const std::ptrdiff_t bit_step = msv_first ? static_cast<std::ptrdiff_t>(-static_cast<std::ptrdiff_t>(chunk_size)) : static_cast<std::ptrdiff_t>(chunk_size); while (bit_location % bit_step) ++bit_location; do { *out = detail::extract_bits(val.backend(), bit_location, chunk_size, tag_type()); ++out; bit_location += bit_step; } while ((bit_location >= 0) && (bit_location < static_cast<int>(bitcount))); return out; #ifdef BOOST_MSVC #pragma warning(pop) #endif } } } // namespace boost::multiprecision #endif // BOOST_MP_CPP_INT_IMPORT_EXPORT_HPP