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+// Copyright 2018 vDaniel Parker
+// Distributed under the Boost 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/danielaparker/jsoncons for latest version
+
+#ifndef JSONCONS_BIGINT_HPP
+#define JSONCONS_BIGINT_HPP
+
+#include <cstdint>
+#include <vector> // std::vector
+#include <iostream>
+#include <climits>
+#include <cassert> // assert
+#include <limits> // std::numeric_limits
+#include <algorithm> // std::max, std::min, std::reverse
+#include <string> // std::string
+#include <cstring> // std::memcpy
+#include <cmath> // std::fmod
+#include <memory> // std::allocator
+#include <initializer_list> // std::initializer_list
+#include <type_traits> // std::enable_if
+#include <jsoncons/config/jsoncons_config.hpp>
+
+namespace jsoncons {
+
+/*
+This implementation is based on Chapter 2 and Appendix A of
+Ammeraal, L. (1996) Algorithms and Data Structures in C++,
+Chichester: John Wiley.
+
+*/
+
+
+namespace detail {
+
+ template <class Allocator>
+ class basic_bigint_base
+ {
+ public:
+ using allocator_type = Allocator;
+ using basic_type_allocator_type = typename std::allocator_traits<allocator_type>:: template rebind_alloc<uint64_t>;
+
+ private:
+ basic_type_allocator_type alloc_;
+ public:
+ using allocator_traits_type = std::allocator_traits<allocator_type>;
+ using stored_allocator_type = allocator_type;
+ using pointer = typename allocator_traits_type::pointer;
+ using value_type = typename allocator_traits_type::value_type;
+ using size_type = typename allocator_traits_type::size_type;
+ using pointer_traits = std::pointer_traits<pointer>;
+
+ basic_bigint_base()
+ : alloc_()
+ {
+ }
+ explicit basic_bigint_base(const allocator_type& alloc)
+ : alloc_(basic_type_allocator_type(alloc))
+ {
+ }
+
+ basic_type_allocator_type get_allocator() const
+ {
+ return alloc_;
+ }
+ };
+
+} // namespace detail
+
+template <class Allocator = std::allocator<uint64_t>>
+class basic_bigint : protected detail::basic_bigint_base<Allocator>
+{
+ using base_t = detail::basic_bigint_base<Allocator>;
+
+public:
+
+ using size_type = typename base_t::size_type;
+ using value_type = typename base_t::value_type;
+ using base_t::get_allocator;
+ using bigint_type = basic_bigint<Allocator>;
+
+ static constexpr uint64_t max_basic_type = (std::numeric_limits<uint64_t>::max)();
+ static constexpr uint64_t basic_type_bits = sizeof(uint64_t) * 8; // Number of bits
+ static constexpr uint64_t basic_type_halfBits = basic_type_bits/2;
+
+ static constexpr uint16_t word_length = 4; // Use multiples of word_length words
+ static constexpr uint64_t r_mask = (uint64_t(1) << basic_type_halfBits) - 1;
+ static constexpr uint64_t l_mask = max_basic_type - r_mask;
+ static constexpr uint64_t l_bit = max_basic_type - (max_basic_type >> 1);
+
+private:
+
+ struct common_storage
+ {
+ uint8_t is_dynamic_:1;
+ uint8_t is_negative_:1;
+ size_type length_;
+ };
+
+ struct short_storage
+ {
+ uint8_t is_dynamic_:1;
+ uint8_t is_negative_:1;
+ size_type length_;
+ uint64_t values_[2];
+
+ short_storage()
+ : is_dynamic_(false),
+ is_negative_(false),
+ length_(0),
+ values_{0,0}
+ {
+ }
+
+ template <class T>
+ short_storage(T n,
+ typename std::enable_if<std::is_integral<T>::value &&
+ sizeof(T) <= sizeof(int64_t) &&
+ std::is_signed<T>::value>::type* = 0)
+ : is_dynamic_(false),
+ is_negative_(n < 0),
+ length_(n == 0 ? 0 : 1)
+ {
+ values_[0] = n < 0 ? (uint64_t(0)-static_cast<uint64_t>(n)) : static_cast<uint64_t>(n);
+ values_[1] = 0;
+ }
+
+ template <class T>
+ short_storage(T n,
+ typename std::enable_if<std::is_integral<T>::value &&
+ sizeof(T) <= sizeof(int64_t) &&
+ !std::is_signed<T>::value>::type* = 0)
+ : is_dynamic_(false),
+ is_negative_(false),
+ length_(n == 0 ? 0 : 1)
+ {
+ values_[0] = n;
+ values_[1] = 0;
+ }
+
+ template <class T>
+ short_storage(T n,
+ typename std::enable_if<std::is_integral<T>::value &&
+ sizeof(int64_t) < sizeof(T) &&
+ std::is_signed<T>::value>::type* = 0)
+ : is_dynamic_(false),
+ is_negative_(n < 0),
+ length_(n == 0 ? 0 : 2)
+ {
+ using unsigned_type = typename std::make_unsigned<T>::type;
+
+ auto u = n < 0 ? (unsigned_type(0)-static_cast<unsigned_type>(n)) : static_cast<unsigned_type>(n);
+ values_[0] = uint64_t(u & max_basic_type);;
+ u >>= basic_type_bits;
+ values_[1] = uint64_t(u & max_basic_type);;
+ }
+
+ template <class T>
+ short_storage(T n,
+ typename std::enable_if<std::is_integral<T>::value &&
+ sizeof(int64_t) < sizeof(T) &&
+ !std::is_signed<T>::value>::type* = 0)
+ : is_dynamic_(false),
+ is_negative_(false),
+ length_(n == 0 ? 0 : 2)
+ {
+ values_[0] = uint64_t(n & max_basic_type);;
+ n >>= basic_type_bits;
+ values_[1] = uint64_t(n & max_basic_type);;
+ }
+
+ short_storage(const short_storage& stor)
+ : is_dynamic_(false),
+ is_negative_(stor.is_negative_),
+ length_(stor.length_)
+ {
+ values_[0] = stor.values_[0];
+ values_[1] = stor.values_[1];
+ }
+
+ short_storage& operator=(const short_storage& stor) = delete;
+ };
+
+ struct dynamic_storage
+ {
+ using real_allocator_type = typename std::allocator_traits<Allocator>:: template rebind_alloc<uint64_t>;
+ using pointer = typename std::allocator_traits<real_allocator_type>::pointer;
+
+ uint8_t is_dynamic_:1;
+ uint8_t is_negative_:1;
+ size_type length_;
+ size_type capacity_;
+ pointer data_;
+
+ dynamic_storage()
+ : is_dynamic_(true),
+ is_negative_(false),
+ length_(0),
+ capacity_(0),
+ data_(nullptr)
+ {
+ }
+
+ dynamic_storage(const dynamic_storage& stor, const real_allocator_type& alloc)
+ : is_dynamic_(true),
+ is_negative_(stor.is_negative_),
+ length_(stor.length_),
+ capacity_(0),
+ data_(nullptr)
+ {
+ create(stor.length_, alloc);
+ std::memcpy(data_, stor.data_, stor.length_*sizeof(uint64_t));
+ }
+
+ dynamic_storage(dynamic_storage&& stor) noexcept
+ : is_dynamic_(true),
+ is_negative_(stor.is_negative_),
+ length_(stor.length_),
+ capacity_(stor.capacity_),
+ data_(stor.data_)
+ {
+ stor.length_ = 0;
+ stor.capacity_ = 0;
+ stor.data_ = nullptr;
+ }
+
+ void create(size_type length, real_allocator_type alloc)
+ {
+ capacity_ = round_up(length);
+ data_ = std::allocator_traits<real_allocator_type>::allocate(alloc, capacity_);
+ JSONCONS_TRY
+ {
+ std::allocator_traits<real_allocator_type>::construct(alloc, type_traits::to_plain_pointer(data_));
+ }
+ JSONCONS_CATCH(...)
+ {
+ std::allocator_traits<real_allocator_type>::deallocate(alloc, data_, capacity_);
+ JSONCONS_RETHROW;
+ }
+ }
+
+ void destroy(const real_allocator_type& a) noexcept
+ {
+ if (data_ != nullptr)
+ {
+ real_allocator_type alloc(a);
+
+ std::allocator_traits<real_allocator_type>::destroy(alloc, type_traits::to_plain_pointer(data_));
+ std::allocator_traits<real_allocator_type>::deallocate(alloc, data_,capacity_);
+ }
+ }
+
+ void reserve(size_type n, const real_allocator_type& a)
+ {
+ real_allocator_type alloc(a);
+
+ size_type capacity_new = round_up(n);
+ uint64_t* data_old = data_;
+ data_ = std::allocator_traits<real_allocator_type>::allocate(alloc, capacity_new);
+ if (length_ > 0)
+ {
+ std::memcpy( data_, data_old, length_*sizeof(uint64_t));
+ }
+ if (capacity_ > 0 && data_ != nullptr)
+ {
+ std::allocator_traits<real_allocator_type>::deallocate(alloc, data_old, capacity_);
+ }
+ capacity_ = capacity_new;
+ }
+
+ // Find suitable new block size
+ constexpr size_type round_up(size_type i) const
+ {
+ return (i/word_length + 1) * word_length;
+ }
+ };
+
+ union
+ {
+ common_storage common_stor_;
+ short_storage short_stor_;
+ dynamic_storage dynamic_stor_;
+ };
+
+public:
+ basic_bigint()
+ {
+ ::new (&short_stor_) short_storage();
+ }
+
+ explicit basic_bigint(const Allocator& alloc)
+ : base_t(alloc)
+ {
+ ::new (&short_stor_) short_storage();
+ }
+
+
+ basic_bigint(const basic_bigint<Allocator>& n)
+ : base_t(n.get_allocator())
+ {
+ if (!n.is_dynamic())
+ {
+ ::new (&short_stor_) short_storage(n.short_stor_);
+ }
+ else
+ {
+ ::new (&dynamic_stor_) dynamic_storage(n.dynamic_stor_, get_allocator());
+ }
+ }
+
+ basic_bigint(basic_bigint<Allocator>&& other) noexcept
+ : base_t(other.get_allocator())
+ {
+ if (!other.is_dynamic())
+ {
+ ::new (&short_stor_) short_storage(other.short_stor_);
+ }
+ else
+ {
+ ::new (&dynamic_stor_) dynamic_storage(std::move(other.dynamic_stor_));
+ }
+ }
+
+ template <class Integer>
+ basic_bigint(Integer n,
+ typename std::enable_if<std::is_integral<Integer>::value>::type* = 0)
+ {
+ ::new (&short_stor_) short_storage(n);
+ }
+
+ ~basic_bigint() noexcept
+ {
+ destroy();
+ }
+
+ constexpr bool is_dynamic() const
+ {
+ return common_stor_.is_dynamic_;
+ }
+
+ constexpr size_type length() const
+ {
+ return common_stor_.length_;
+ }
+
+ constexpr size_type capacity() const
+ {
+ return is_dynamic() ? dynamic_stor_.capacity_ : 2;
+ }
+
+ bool is_negative() const
+ {
+ return common_stor_.is_negative_;
+ }
+
+ void is_negative(bool value)
+ {
+ common_stor_.is_negative_ = value;
+ }
+
+ constexpr const uint64_t* data() const
+ {
+ return is_dynamic() ? dynamic_stor_.data_ : short_stor_.values_;
+ }
+
+ uint64_t* data()
+ {
+ return is_dynamic() ? dynamic_stor_.data_ : short_stor_.values_;
+ }
+
+ template <class CharT>
+ static basic_bigint<Allocator> from_string(const std::basic_string<CharT>& s)
+ {
+ return from_string(s.data(), s.length());
+ }
+
+ template <class CharT>
+ static basic_bigint<Allocator> from_string(const CharT* s)
+ {
+ return from_string(s, std::char_traits<CharT>::length(s));
+ }
+
+ template <class CharT>
+ static basic_bigint<Allocator> from_string(const CharT* data, size_type length)
+ {
+ bool neg;
+ if (*data == '-')
+ {
+ neg = true;
+ data++;
+ --length;
+ }
+ else
+ {
+ neg = false;
+ }
+
+ basic_bigint<Allocator> v = 0;
+ for (size_type i = 0; i < length; i++)
+ {
+ CharT c = data[i];
+ switch (c)
+ {
+ case '0':case '1':case '2':case '3':case '4':case '5':case '6':case '7':case '8': case '9':
+ v = (v * 10) + (uint64_t)(c - '0');
+ break;
+ default:
+ JSONCONS_THROW(std::runtime_error(std::string("Invalid digit ") + "\'" + (char)c + "\'"));
+ }
+ }
+
+ if (neg)
+ {
+ v.common_stor_.is_negative_ = true;
+ }
+
+ return v;
+ }
+
+ template <class CharT>
+ static basic_bigint<Allocator> from_string_radix(const CharT* data, size_type length, uint8_t radix)
+ {
+ if (!(radix >= 2 && radix <= 16))
+ {
+ JSONCONS_THROW(std::runtime_error("Unsupported radix"));
+ }
+
+ bool neg;
+ if (*data == '-')
+ {
+ neg = true;
+ data++;
+ --length;
+ }
+ else
+ {
+ neg = false;
+ }
+
+ basic_bigint<Allocator> v = 0;
+ for (size_type i = 0; i < length; i++)
+ {
+ CharT c = data[i];
+ uint64_t d;
+ switch (c)
+ {
+ case '0':case '1':case '2':case '3':case '4':case '5':case '6':case '7':case '8': case '9':
+ d = (uint64_t)(c - '0');
+ break;
+ case 'a':case 'b':case 'c':case 'd':case 'e':case 'f':
+ d = (uint64_t)(c - ('a' - 10));
+ break;
+ case 'A':case 'B':case 'C':case 'D':case 'E':case 'F':
+ d = (uint64_t)(c - ('A' - 10));
+ break;
+ default:
+ JSONCONS_THROW(std::runtime_error(std::string("Invalid digit in radix ") + std::to_string(radix) + ": \'" + (char)c + "\'"));
+ }
+ if (d >= radix)
+ {
+ JSONCONS_THROW(std::runtime_error(std::string("Invalid digit in radix ") + std::to_string(radix) + ": \'" + (char)c + "\'"));
+ }
+ v = (v * radix) + d;
+ }
+
+ if ( neg )
+ {
+ v.common_stor_.is_negative_ = true;
+ }
+ return v;
+ }
+
+ static basic_bigint from_bytes_be(int signum, const uint8_t* str, std::size_t n)
+ {
+ static const double radix_log2 = std::log2(next_power_of_two(256));
+ // Estimate how big the result will be, so we can pre-allocate it.
+ double bits = radix_log2 * n;
+ double big_digits = std::ceil(bits / 64.0);
+ //std::cout << "ESTIMATED: " << big_digits << "\n";
+
+ bigint_type v = 0;
+ v.reserve(static_cast<std::size_t>(big_digits));
+
+ if (n > 0)
+ {
+ for (std::size_t i = 0; i < n; i++)
+ {
+ v = (v * 256) + (uint64_t)(str[i]);
+ }
+ }
+ //std::cout << "ACTUAL: " << v.length() << "\n";
+
+ if (signum < 0)
+ {
+ v.common_stor_.is_negative_ = true;
+ }
+
+ return v;
+ }
+
+ uint64_t* begin() { return is_dynamic() ? dynamic_stor_.data_ : short_stor_.values_; }
+ const uint64_t* begin() const { return is_dynamic() ? dynamic_stor_.data_ : short_stor_.values_; }
+ uint64_t* end() { return begin() + length(); }
+ const uint64_t* end() const { return begin() + length(); }
+
+ void resize(size_type n)
+ {
+ size_type len_old = common_stor_.length_;
+ reserve(n);
+ common_stor_.length_ = n;
+ if ( common_stor_.length_ > len_old )
+ {
+ memset( data()+len_old, 0, (common_stor_.length_ - len_old)*sizeof(uint64_t) );
+ }
+ }
+
+ void reserve(size_type n)
+ {
+ if (capacity() < n)
+ {
+ if (!is_dynamic())
+ {
+ size_type size = short_stor_.length_;
+ size_type is_neg = short_stor_.is_negative_;
+ uint64_t values[2] = {short_stor_.values_[0], short_stor_.values_[1]};
+
+ ::new (&dynamic_stor_) dynamic_storage();
+ dynamic_stor_.reserve(n, get_allocator());
+ dynamic_stor_.length_ = size;
+ dynamic_stor_.is_negative_ = is_neg;
+ dynamic_stor_.data_[0] = values[0];
+ dynamic_stor_.data_[1] = values[1];
+ }
+ else
+ {
+ dynamic_stor_.reserve(n, get_allocator());
+ }
+ }
+ }
+
+ // operators
+
+ bool operator!() const
+ {
+ return length() == 0 ? true : false;
+ }
+
+ basic_bigint operator-() const
+ {
+ basic_bigint<Allocator> v(*this);
+ v.common_stor_.is_negative_ = !v.is_negative();
+ return v;
+ }
+
+ basic_bigint& operator=( const basic_bigint<Allocator>& y )
+ {
+ if ( this != &y )
+ {
+ resize( y.length() );
+ common_stor_.is_negative_ = y.is_negative();
+ if ( y.length() > 0 )
+ {
+ std::memcpy( data(), y.data(), y.length()*sizeof(uint64_t) );
+ }
+ }
+ return *this;
+ }
+
+ basic_bigint& operator+=( const basic_bigint<Allocator>& y )
+ {
+ if ( is_negative() != y.is_negative() )
+ return *this -= -y;
+ uint64_t d;
+ uint64_t carry = 0;
+
+ resize( (std::max)(y.length(), length()) + 1 );
+
+ for (size_type i = 0; i < length(); i++ )
+ {
+ if ( i >= y.length() && carry == 0 )
+ break;
+ d = data()[i] + carry;
+ carry = d < carry;
+ if ( i < y.length() )
+ {
+ data()[i] = d + y.data()[i];
+ if ( data()[i] < d )
+ carry = 1;
+ }
+ else
+ data()[i] = d;
+ }
+ reduce();
+ return *this;
+ }
+
+ basic_bigint& operator-=( const basic_bigint<Allocator>& y )
+ {
+ if ( is_negative() != y.is_negative() )
+ return *this += -y;
+ if ( (!is_negative() && y > *this) || (is_negative() && y < *this) )
+ return *this = -(y - *this);
+ uint64_t borrow = 0;
+ uint64_t d;
+ for (size_type i = 0; i < length(); i++ )
+ {
+ if ( i >= y.length() && borrow == 0 )
+ break;
+ d = data()[i] - borrow;
+ borrow = d > data()[i];
+ if ( i < y.length())
+ {
+ data()[i] = d - y.data()[i];
+ if ( data()[i] > d )
+ borrow = 1;
+ }
+ else
+ data()[i] = d;
+ }
+ reduce();
+ return *this;
+ }
+
+ basic_bigint& operator*=( int64_t y )
+ {
+ *this *= uint64_t(y < 0 ? -y : y);
+ if ( y < 0 )
+ common_stor_.is_negative_ = !is_negative();
+ return *this;
+ }
+
+ basic_bigint& operator*=( uint64_t y )
+ {
+ size_type len0 = length();
+ uint64_t hi;
+ uint64_t lo;
+ uint64_t dig = data()[0];
+ uint64_t carry = 0;
+
+ resize( length() + 1 );
+
+ size_type i = 0;
+ for (i = 0; i < len0; i++ )
+ {
+ DDproduct( dig, y, hi, lo );
+ data()[i] = lo + carry;
+ dig = data()[i+1];
+ carry = hi + (data()[i] < lo);
+ }
+ data()[i] = carry;
+ reduce();
+ return *this;
+ }
+
+ basic_bigint& operator*=( basic_bigint<Allocator> y )
+ {
+ if ( length() == 0 || y.length() == 0 )
+ return *this = 0;
+ bool difSigns = is_negative() != y.is_negative();
+ if ( length() + y.length() == 2 ) // length() = y.length() = 1
+ {
+ uint64_t a = data()[0], b = y.data()[0];
+ data()[0] = a * b;
+ if ( data()[0] / a != b )
+ {
+ resize( 2 );
+ DDproduct( a, b, data()[1], data()[0] );
+ }
+ common_stor_.is_negative_ = difSigns;
+ return *this;
+ }
+ if ( length() == 1 ) // && y.length() > 1
+ {
+ uint64_t digit = data()[0];
+ *this = y;
+ *this *= digit;
+ }
+ else
+ {
+ if ( y.length() == 1 )
+ *this *= y.data()[0];
+ else
+ {
+ size_type lenProd = length() + y.length(), jA, jB;
+ uint64_t sumHi = 0, sumLo, hi, lo,
+ sumLo_old, sumHi_old, carry=0;
+ basic_bigint<Allocator> x = *this;
+ resize( lenProd ); // Give *this length lenProd
+
+ for (size_type i = 0; i < lenProd; i++ )
+ {
+ sumLo = sumHi;
+ sumHi = carry;
+ carry = 0;
+ for ( jA=0; jA < x.length(); jA++ )
+ {
+ jB = i - jA;
+ if ( jB >= 0 && jB < y.length() )
+ {
+ DDproduct( x.data()[jA], y.data()[jB], hi, lo );
+ sumLo_old = sumLo;
+ sumHi_old = sumHi;
+ sumLo += lo;
+ if ( sumLo < sumLo_old )
+ sumHi++;
+ sumHi += hi;
+ carry += (sumHi < sumHi_old);
+ }
+ }
+ data()[i] = sumLo;
+ }
+ }
+ }
+ reduce();
+ common_stor_.is_negative_ = difSigns;
+ return *this;
+ }
+
+ basic_bigint& operator/=( const basic_bigint<Allocator>& divisor )
+ {
+ basic_bigint<Allocator> r;
+ divide( divisor, *this, r, false );
+ return *this;
+ }
+
+ basic_bigint& operator%=( const basic_bigint<Allocator>& divisor )
+ {
+ basic_bigint<Allocator> q;
+ divide( divisor, q, *this, true );
+ return *this;
+ }
+
+ basic_bigint& operator<<=( uint64_t k )
+ {
+ size_type q = (size_type)(k / basic_type_bits);
+ if ( q ) // Increase common_stor_.length_ by q:
+ {
+ resize(length() + q);
+ for (size_type i = length(); i-- > 0; )
+ data()[i] = ( i < q ? 0 : data()[i - q]);
+ k %= basic_type_bits;
+ }
+ if ( k ) // 0 < k < basic_type_bits:
+ {
+ uint64_t k1 = basic_type_bits - k;
+ uint64_t mask = (uint64_t(1) << k) - uint64_t(1);
+ resize( length() + 1 );
+ for (size_type i = length(); i-- > 0; )
+ {
+ data()[i] <<= k;
+ if ( i > 0 )
+ data()[i] |= (data()[i-1] >> k1) & mask;
+ }
+ }
+ reduce();
+ return *this;
+ }
+
+ basic_bigint& operator>>=(uint64_t k)
+ {
+ size_type q = (size_type)(k / basic_type_bits);
+ if ( q >= length() )
+ {
+ resize( 0 );
+ return *this;
+ }
+ if (q > 0)
+ {
+ memmove( data(), data()+q, (size_type)((length() - q)*sizeof(uint64_t)) );
+ resize( length() - q );
+ k %= basic_type_bits;
+ if ( k == 0 )
+ {
+ reduce();
+ return *this;
+ }
+ }
+
+ size_type n = (size_type)(length() - 1);
+ int64_t k1 = basic_type_bits - k;
+ uint64_t mask = (uint64_t(1) << k) - 1;
+ for (size_type i = 0; i <= n; i++)
+ {
+ data()[i] >>= k;
+ if ( i < n )
+ data()[i] |= ((data()[i+1] & mask) << k1);
+ }
+ reduce();
+ return *this;
+ }
+
+ basic_bigint& operator++()
+ {
+ *this += 1;
+ return *this;
+ }
+
+ basic_bigint<Allocator> operator++(int)
+ {
+ basic_bigint<Allocator> old = *this;
+ ++(*this);
+ return old;
+ }
+
+ basic_bigint<Allocator>& operator--()
+ {
+ *this -= 1;
+ return *this;
+ }
+
+ basic_bigint<Allocator> operator--(int)
+ {
+ basic_bigint<Allocator> old = *this;
+ --(*this);
+ return old;
+ }
+
+ basic_bigint& operator|=( const basic_bigint<Allocator>& a )
+ {
+ if ( length() < a.length() )
+ {
+ resize( a.length() );
+ }
+
+ const uint64_t* qBegin = a.begin();
+ const uint64_t* q = a.end() - 1;
+ uint64_t* p = begin() + a.length() - 1;
+
+ while ( q >= qBegin )
+ {
+ *p-- |= *q--;
+ }
+
+ reduce();
+
+ return *this;
+ }
+
+ basic_bigint& operator^=( const basic_bigint<Allocator>& a )
+ {
+ if ( length() < a.length() )
+ {
+ resize( a.length() );
+ }
+
+ const uint64_t* qBegin = a.begin();
+ const uint64_t* q = a.end() - 1;
+ uint64_t* p = begin() + a.length() - 1;
+
+ while ( q >= qBegin )
+ {
+ *p-- ^= *q--;
+ }
+
+ reduce();
+
+ return *this;
+ }
+
+ basic_bigint& operator&=( const basic_bigint<Allocator>& a )
+ {
+ size_type old_length = length();
+
+ resize( (std::min)( length(), a.length() ) );
+
+ const uint64_t* pBegin = begin();
+ uint64_t* p = end() - 1;
+ const uint64_t* q = a.begin() + length() - 1;
+
+ while ( p >= pBegin )
+ {
+ *p-- &= *q--;
+ }
+
+ if ( old_length > length() )
+ {
+ memset( data() + length(), 0, old_length - length() );
+ }
+
+ reduce();
+
+ return *this;
+ }
+
+ explicit operator bool() const
+ {
+ return length() != 0 ? true : false;
+ }
+
+ explicit operator int64_t() const
+ {
+ int64_t x = 0;
+ if ( length() > 0 )
+ {
+ x = data() [0];
+ }
+
+ return is_negative() ? -x : x;
+ }
+
+ explicit operator uint64_t() const
+ {
+ uint64_t u = 0;
+ if ( length() > 0 )
+ {
+ u = data() [0];
+ }
+
+ return u;
+ }
+
+ explicit operator double() const
+ {
+ double x = 0.0;
+ double factor = 1.0;
+ double values = (double)max_basic_type + 1.0;
+
+ const uint64_t* p = begin();
+ const uint64_t* pEnd = end();
+ while ( p < pEnd )
+ {
+ x += *p*factor;
+ factor *= values;
+ ++p;
+ }
+
+ return is_negative() ? -x : x;
+ }
+
+ explicit operator long double() const
+ {
+ long double x = 0.0;
+ long double factor = 1.0;
+ long double values = (long double)max_basic_type + 1.0;
+
+ const uint64_t* p = begin();
+ const uint64_t* pEnd = end();
+ while ( p < pEnd )
+ {
+ x += *p*factor;
+ factor *= values;
+ ++p;
+ }
+
+ return is_negative() ? -x : x;
+ }
+
+ template <typename Alloc>
+ void write_bytes_be(int& signum, std::vector<uint8_t,Alloc>& data) const
+ {
+ basic_bigint<Allocator> n(*this);
+ signum = (n < 0) ? -1 : (n > 0 ? 1 : 0);
+
+ basic_bigint<Allocator> divisor(256);
+
+ while (n >= 256)
+ {
+ basic_bigint<Allocator> q;
+ basic_bigint<Allocator> r;
+ n.divide(divisor, q, r, true);
+ n = q;
+ data.push_back((uint8_t)(uint64_t)r);
+ }
+ if (n >= 0)
+ {
+ data.push_back((uint8_t)(uint64_t)n);
+ }
+ std::reverse(data.begin(),data.end());
+ }
+
+ std::string to_string() const
+ {
+ std::string s;
+ write_string(s);
+ return s;
+ }
+
+ template <typename Ch, typename Traits, typename Alloc>
+ void write_string(std::basic_string<Ch,Traits,Alloc>& data) const
+ {
+ basic_bigint<Allocator> v(*this);
+
+ size_t len = (v.length() * basic_type_bits / 3) + 2;
+ data.reserve(len);
+
+ static uint64_t p10 = 1;
+ static uint64_t ip10 = 0;
+
+ if ( v.length() == 0 )
+ {
+ data.push_back('0');
+ }
+ else
+ {
+ uint64_t r;
+ if ( p10 == 1 )
+ {
+ while ( p10 <= (std::numeric_limits<uint64_t>::max)()/10 )
+ {
+ p10 *= 10;
+ ip10++;
+ }
+ }
+ // p10 is max unsigned power of 10
+ basic_bigint<Allocator> R;
+ basic_bigint<Allocator> LP10 = p10; // LP10 = p10 = ::pow(10, ip10)
+
+ do
+ {
+ v.divide( LP10, v, R, true );
+ r = (R.length() ? R.data()[0] : 0);
+ for ( size_type j=0; j < ip10; j++ )
+ {
+ data.push_back(char(r % 10 + '0'));
+ r /= 10;
+ if ( r + v.length() == 0 )
+ break;
+ }
+ }
+ while ( v.length() );
+ if (is_negative())
+ {
+ data.push_back('-');
+ }
+ std::reverse(data.begin(),data.end());
+ }
+ }
+
+ std::string to_string_hex() const
+ {
+ std::string s;
+ write_string_hex(s);
+ return s;
+ }
+
+ template <typename Ch, typename Traits, typename Alloc>
+ void write_string_hex(std::basic_string<Ch,Traits,Alloc>& data) const
+ {
+ basic_bigint<Allocator> v(*this);
+
+ std::size_t len = (v.length() * basic_bigint<Allocator>::basic_type_bits / 3) + 2;
+ data.reserve(len);
+ // 1/3 > ln(2)/ln(10)
+ static uint64_t p10 = 1;
+ static uint64_t ip10 = 0;
+
+ if ( v.length() == 0 )
+ {
+ data.push_back('0');
+ }
+ else
+ {
+ uint64_t r;
+ if ( p10 == 1 )
+ {
+ while ( p10 <= (std::numeric_limits<uint64_t>::max)()/16 )
+ {
+ p10 *= 16;
+ ip10++;
+ }
+ } // p10 is max unsigned power of 16
+ basic_bigint<Allocator> R;
+ basic_bigint<Allocator> LP10 = p10; // LP10 = p10 = ::pow(16, ip10)
+ do
+ {
+ v.divide( LP10, v, R, true );
+ r = (R.length() ? R.data()[0] : 0);
+ for ( size_type j=0; j < ip10; j++ )
+ {
+ uint8_t c = r % 16;
+ data.push_back((c < 10) ? ('0' + c) : ('A' - 10 + c));
+ r /= 16;
+ if ( r + v.length() == 0 )
+ break;
+ }
+ }
+ while (v.length());
+
+ if (is_negative())
+ {
+ data.push_back('-');
+ }
+ std::reverse(data.begin(),data.end());
+ }
+ }
+
+// Global Operators
+
+ friend bool operator==( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) == 0 ? true : false;
+ }
+
+ friend bool operator==( const basic_bigint<Allocator>& x, int y ) noexcept
+ {
+ return x.compare(y) == 0 ? true : false;
+ }
+
+ friend bool operator!=( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) != 0 ? true : false;
+ }
+
+ friend bool operator!=( const basic_bigint<Allocator>& x, int y ) noexcept
+ {
+ return x.compare(basic_bigint<Allocator>(y)) != 0 ? true : false;
+ }
+
+ friend bool operator<( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) < 0 ? true : false;
+ }
+
+ friend bool operator<( const basic_bigint<Allocator>& x, int64_t y ) noexcept
+ {
+ return x.compare(y) < 0 ? true : false;
+ }
+
+ friend bool operator>( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) > 0 ? true : false;
+ }
+
+ friend bool operator>( const basic_bigint<Allocator>& x, int y ) noexcept
+ {
+ return x.compare(basic_bigint<Allocator>(y)) > 0 ? true : false;
+ }
+
+ friend bool operator<=( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) <= 0 ? true : false;
+ }
+
+ friend bool operator<=( const basic_bigint<Allocator>& x, int y ) noexcept
+ {
+ return x.compare(y) <= 0 ? true : false;
+ }
+
+ friend bool operator>=( const basic_bigint<Allocator>& x, const basic_bigint<Allocator>& y ) noexcept
+ {
+ return x.compare(y) >= 0 ? true : false;
+ }
+
+ friend bool operator>=( const basic_bigint<Allocator>& x, int y ) noexcept
+ {
+ return x.compare(y) >= 0 ? true : false;
+ }
+
+ friend basic_bigint<Allocator> operator+( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x += y;
+ }
+
+ friend basic_bigint<Allocator> operator+( basic_bigint<Allocator> x, int64_t y )
+ {
+ return x += y;
+ }
+
+ friend basic_bigint<Allocator> operator-( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x -= y;
+ }
+
+ friend basic_bigint<Allocator> operator-( basic_bigint<Allocator> x, int64_t y )
+ {
+ return x -= y;
+ }
+
+ friend basic_bigint<Allocator> operator*( int64_t x, const basic_bigint<Allocator>& y )
+ {
+ return basic_bigint<Allocator>(y) *= x;
+ }
+
+ friend basic_bigint<Allocator> operator*( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x *= y;
+ }
+
+ friend basic_bigint<Allocator> operator*( basic_bigint<Allocator> x, int64_t y )
+ {
+ return x *= y;
+ }
+
+ friend basic_bigint<Allocator> operator/( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x /= y;
+ }
+
+ friend basic_bigint<Allocator> operator/( basic_bigint<Allocator> x, int y )
+ {
+ return x /= y;
+ }
+
+ friend basic_bigint<Allocator> operator%( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x %= y;
+ }
+
+ friend basic_bigint<Allocator> operator<<( basic_bigint<Allocator> u, unsigned k )
+ {
+ return u <<= k;
+ }
+
+ friend basic_bigint<Allocator> operator<<( basic_bigint<Allocator> u, int k )
+ {
+ return u <<= k;
+ }
+
+ friend basic_bigint<Allocator> operator>>( basic_bigint<Allocator> u, unsigned k )
+ {
+ return u >>= k;
+ }
+
+ friend basic_bigint<Allocator> operator>>( basic_bigint<Allocator> u, int k )
+ {
+ return u >>= k;
+ }
+
+ friend basic_bigint<Allocator> operator|( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x |= y;
+ }
+
+ friend basic_bigint<Allocator> operator|( basic_bigint<Allocator> x, int y )
+ {
+ return x |= y;
+ }
+
+ friend basic_bigint<Allocator> operator|( basic_bigint<Allocator> x, unsigned y )
+ {
+ return x |= y;
+ }
+
+ friend basic_bigint<Allocator> operator^( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x ^= y;
+ }
+
+ friend basic_bigint<Allocator> operator^( basic_bigint<Allocator> x, int y )
+ {
+ return x ^= y;
+ }
+
+ friend basic_bigint<Allocator> operator^( basic_bigint<Allocator> x, unsigned y )
+ {
+ return x ^= y;
+ }
+
+ friend basic_bigint<Allocator> operator&( basic_bigint<Allocator> x, const basic_bigint<Allocator>& y )
+ {
+ return x &= y;
+ }
+
+ friend basic_bigint<Allocator> operator&( basic_bigint<Allocator> x, int y )
+ {
+ return x &= y;
+ }
+
+ friend basic_bigint<Allocator> operator&( basic_bigint<Allocator> x, unsigned y )
+ {
+ return x &= y;
+ }
+
+ friend basic_bigint<Allocator> abs( const basic_bigint<Allocator>& a )
+ {
+ if ( a.is_negative() )
+ {
+ return -a;
+ }
+ return a;
+ }
+
+ friend basic_bigint<Allocator> power( basic_bigint<Allocator> x, unsigned n )
+ {
+ basic_bigint<Allocator> y = 1;
+
+ while ( n )
+ {
+ if ( n & 1 )
+ {
+ y *= x;
+ }
+ x *= x;
+ n >>= 1;
+ }
+
+ return y;
+ }
+
+ friend basic_bigint<Allocator> sqrt( const basic_bigint<Allocator>& a )
+ {
+ basic_bigint<Allocator> x = a;
+ basic_bigint<Allocator> b = a;
+ basic_bigint<Allocator> q;
+
+ b <<= 1;
+ while ( b >>= 2, b > 0 )
+ {
+ x >>= 1;
+ }
+ while ( x > (q = a/x) + 1 || x < q - 1 )
+ {
+ x += q;
+ x >>= 1;
+ }
+ return x < q ? x : q;
+ }
+
+ template <class CharT>
+ friend std::basic_ostream<CharT>& operator<<(std::basic_ostream<CharT>& os, const basic_bigint<Allocator>& v)
+ {
+ std::basic_string<CharT> s;
+ v.write_string(s);
+ os << s;
+
+ return os;
+ }
+
+ int compare( const basic_bigint<Allocator>& y ) const noexcept
+ {
+ if ( is_negative() != y.is_negative() )
+ return y.is_negative() - is_negative();
+ int code = 0;
+ if ( length() == 0 && y.length() == 0 )
+ code = 0;
+ else if ( length() < y.length() )
+ code = -1;
+ else if ( length() > y.length() )
+ code = +1;
+ else
+ {
+ for (size_type i = length(); i-- > 0; )
+ {
+ if (data()[i] > y.data()[i])
+ {
+ code = 1;
+ break;
+ }
+ else if (data()[i] < y.data()[i])
+ {
+ code = -1;
+ break;
+ }
+ }
+ }
+ return is_negative() ? -code : code;
+ }
+
+ void divide( basic_bigint<Allocator> denom, basic_bigint<Allocator>& quot, basic_bigint<Allocator>& rem, bool remDesired ) const
+ {
+ if ( denom.length() == 0 )
+ {
+ JSONCONS_THROW(std::runtime_error( "Zero divide." ));
+ }
+ bool quot_neg = is_negative() ^ denom.is_negative();
+ bool rem_neg = is_negative();
+ int x = 0;
+ basic_bigint<Allocator> num = *this;
+ num.common_stor_.is_negative_ = denom.common_stor_.is_negative_ = false;
+ if ( num < denom )
+ {
+ quot = uint64_t(0);
+ rem = num;
+ rem.common_stor_.is_negative_ = rem_neg;
+ return;
+ }
+ if ( denom.length() == 1 && num.length() == 1 )
+ {
+ quot = uint64_t( num.data()[0]/denom.data()[0] );
+ rem = uint64_t( num.data()[0]%denom.data()[0] );
+ quot.common_stor_.is_negative_ = quot_neg;
+ rem.common_stor_.is_negative_ = rem_neg;
+ return;
+ }
+ else if (denom.length() == 1 && (denom.data()[0] & l_mask) == 0 )
+ {
+ // Denominator fits into a half word
+ uint64_t divisor = denom.data()[0], dHi = 0,
+ q1, r, q2, dividend;
+ quot.resize(length());
+ for (size_type i=length(); i-- > 0; )
+ {
+ dividend = (dHi << basic_type_halfBits) | (data()[i] >> basic_type_halfBits);
+ q1 = dividend/divisor;
+ r = dividend % divisor;
+ dividend = (r << basic_type_halfBits) | (data()[i] & r_mask);
+ q2 = dividend/divisor;
+ dHi = dividend % divisor;
+ quot.data()[i] = (q1 << basic_type_halfBits) | q2;
+ }
+ quot.reduce();
+ rem = dHi;
+ quot.common_stor_.is_negative_ = quot_neg;
+ rem.common_stor_.is_negative_ = rem_neg;
+ return;
+ }
+ basic_bigint<Allocator> num0 = num, denom0 = denom;
+ int second_done = normalize(denom, num, x);
+ size_type l = denom.length() - 1;
+ size_type n = num.length() - 1;
+ quot.resize(n - l);
+ for (size_type i=quot.length(); i-- > 0; )
+ quot.data()[i] = 0;
+ rem = num;
+ if ( rem.data()[n] >= denom.data()[l] )
+ {
+ rem.resize(rem.length() + 1);
+ n++;
+ quot.resize(quot.length() + 1);
+ }
+ uint64_t d = denom.data()[l];
+ for ( size_type k = n; k > l; k-- )
+ {
+ uint64_t q = DDquotient(rem.data()[k], rem.data()[k-1], d);
+ subtractmul( rem.data() + k - l - 1, denom.data(), l + 1, q );
+ quot.data()[k - l - 1] = q;
+ }
+ quot.reduce();
+ quot.common_stor_.is_negative_ = quot_neg;
+ if ( remDesired )
+ {
+ unnormalize(rem, x, second_done);
+ rem.common_stor_.is_negative_ = rem_neg;
+ }
+ }
+private:
+ void destroy() noexcept
+ {
+ if (is_dynamic())
+ {
+ dynamic_stor_.destroy(get_allocator());
+ }
+ }
+ void DDproduct( uint64_t A, uint64_t B,
+ uint64_t& hi, uint64_t& lo ) const
+ // Multiplying two digits: (hi, lo) = A * B
+ {
+ uint64_t hiA = A >> basic_type_halfBits, loA = A & r_mask,
+ hiB = B >> basic_type_halfBits, loB = B & r_mask,
+ mid1, mid2, old;
+
+ lo = loA * loB;
+ hi = hiA * hiB;
+ mid1 = loA * hiB;
+ mid2 = hiA * loB;
+ old = lo;
+ lo += mid1 << basic_type_halfBits;
+ hi += (lo < old) + (mid1 >> basic_type_halfBits);
+ old = lo;
+ lo += mid2 << basic_type_halfBits;
+ hi += (lo < old) + (mid2 >> basic_type_halfBits);
+ }
+
+ uint64_t DDquotient( uint64_t A, uint64_t B, uint64_t d ) const
+ // Divide double word (A, B) by d. Quotient = (qHi, qLo)
+ {
+ uint64_t left, middle, right, qHi, qLo, x, dLo1,
+ dHi = d >> basic_type_halfBits, dLo = d & r_mask;
+ qHi = A/(dHi + 1);
+ // This initial guess of qHi may be too small.
+ middle = qHi * dLo;
+ left = qHi * dHi;
+ x = B - (middle << basic_type_halfBits);
+ A -= (middle >> basic_type_halfBits) + left + (x > B);
+ B = x;
+ dLo1 = dLo << basic_type_halfBits;
+ // Increase qHi if necessary:
+ while ( A > dHi || (A == dHi && B >= dLo1) )
+ {
+ x = B - dLo1;
+ A -= dHi + (x > B);
+ B = x;
+ qHi++;
+ }
+ qLo = ((A << basic_type_halfBits) | (B >> basic_type_halfBits))/(dHi + 1);
+ // This initial guess of qLo may be too small.
+ right = qLo * dLo;
+ middle = qLo * dHi;
+ x = B - right;
+ A -= (x > B);
+ B = x;
+ x = B - (middle << basic_type_halfBits);
+ A -= (middle >> basic_type_halfBits) + (x > B);
+ B = x;
+ // Increase qLo if necessary:
+ while ( A || B >= d )
+ {
+ x = B - d;
+ A -= (x > B);
+ B = x;
+ qLo++;
+ }
+ return (qHi << basic_type_halfBits) + qLo;
+ }
+
+ void subtractmul( uint64_t* a, uint64_t* b, size_type n, uint64_t& q ) const
+ // a -= q * b: b in n positions; correct q if necessary
+ {
+ uint64_t hi, lo, d, carry = 0;
+ size_type i;
+ for ( i = 0; i < n; i++ )
+ {
+ DDproduct( b[i], q, hi, lo );
+ d = a[i];
+ a[i] -= lo;
+ if ( a[i] > d )
+ carry++;
+ d = a[i + 1];
+ a[i + 1] -= hi + carry;
+ carry = a[i + 1] > d;
+ }
+ if ( carry ) // q was too large
+ {
+ q--;
+ carry = 0;
+ for ( i = 0; i < n; i++ )
+ {
+ d = a[i] + carry;
+ carry = d < carry;
+ a[i] = d + b[i];
+ if ( a[i] < d )
+ carry = 1;
+ }
+ a[n] = 0;
+ }
+ }
+
+ int normalize( basic_bigint<Allocator>& denom, basic_bigint<Allocator>& num, int& x ) const
+ {
+ size_type r = denom.length() - 1;
+ uint64_t y = denom.data()[r];
+
+ x = 0;
+ while ( (y & l_bit) == 0 )
+ {
+ y <<= 1;
+ x++;
+ }
+ denom <<= x;
+ num <<= x;
+ if ( r > 0 && denom.data()[r] < denom.data()[r-1] )
+ {
+ denom *= max_basic_type;
+ num *= max_basic_type;
+ return 1;
+ }
+ return 0;
+ }
+
+ void unnormalize( basic_bigint<Allocator>& rem, int x, int secondDone ) const
+ {
+ if ( secondDone )
+ {
+ rem /= max_basic_type;
+ }
+ if ( x > 0 )
+ {
+ rem >>= x;
+ }
+ else
+ {
+ rem.reduce();
+ }
+ }
+
+ size_type round_up(size_type i) const // Find suitable new block size
+ {
+ return (i/word_length + 1) * word_length;
+ }
+
+ void reduce()
+ {
+ uint64_t* p = end() - 1;
+ uint64_t* pBegin = begin();
+ while ( p >= pBegin )
+ {
+ if ( *p )
+ {
+ break;
+ }
+ --common_stor_.length_;
+ --p;
+ }
+ if ( length() == 0 )
+ {
+ common_stor_.is_negative_ = false;
+ }
+ }
+
+ static uint64_t next_power_of_two(uint64_t n) {
+ n = n - 1;
+ n |= n >> 1;
+ n |= n >> 2;
+ n |= n >> 4;
+ n |= n >> 8;
+ n |= n >> 16;
+ n |= n >> 32;
+ return n + 1;
+ }
+};
+
+using bigint = basic_bigint<std::allocator<uint8_t>>;
+
+#if !defined(JSONCONS_NO_DEPRECATED)
+JSONCONS_DEPRECATED_MSG("Instead, use bigint") typedef bigint bignum;
+#endif
+
+}
+
+#endif