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656 lines
25 KiB
C++
656 lines
25 KiB
C++
///////////////////////////////////////////////////////////////
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// Copyright 2012 John Maddock. Distributed under the Boost
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// Software License, Version 1.0. (See accompanying file
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// LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_
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//
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// Comparison operators for cpp_int_backend:
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//
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#ifndef BOOST_MP_CPP_INT_DIV_HPP
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#define BOOST_MP_CPP_INT_DIV_HPP
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namespace boost{ namespace multiprecision{ namespace backends{
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template <class CppInt1, class CppInt2, class CppInt3>
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void divide_unsigned_helper(
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CppInt1* result,
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const CppInt2& x,
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const CppInt3& y,
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CppInt1& r)
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{
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if(((void*)result == (void*)&x) || ((void*)&r == (void*)&x))
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{
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CppInt2 t(x);
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divide_unsigned_helper(result, t, y, r);
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return;
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}
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if(((void*)result == (void*)&y) || ((void*)&r == (void*)&y))
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{
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CppInt3 t(y);
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divide_unsigned_helper(result, x, t, r);
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return;
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}
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/*
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Very simple, fairly braindead long division.
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Start by setting the remainder equal to x, and the
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result equal to 0. Then in each loop we calculate our
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"best guess" for how many times y divides into r,
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add our guess to the result, and subtract guess*y
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from the remainder r. One wrinkle is that the remainder
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may go negative, in which case we subtract the current guess
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from the result rather than adding. The value of the guess
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is determined by dividing the most-significant-limb of the
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current remainder by the most-significant-limb of y.
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Note that there are more efficient algorithms than this
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available, in particular see Knuth Vol 2. However for small
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numbers of limbs this generally outperforms the alternatives
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and avoids the normalisation step which would require extra storage.
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*/
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using default_ops::eval_subtract;
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if(result == &r)
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{
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CppInt1 rem;
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divide_unsigned_helper(result, x, y, rem);
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r = rem;
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return;
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}
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//
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// Find the most significant words of numerator and denominator.
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//
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limb_type y_order = y.size() - 1;
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if(y_order == 0)
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{
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//
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// Only a single non-zero limb in the denominator, in this case
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// we can use a specialized divide-by-single-limb routine which is
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// much faster. This also handles division by zero:
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//
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divide_unsigned_helper(result, x, y.limbs()[y_order], r);
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return;
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}
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typename CppInt2::const_limb_pointer px = x.limbs();
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typename CppInt3::const_limb_pointer py = y.limbs();
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limb_type r_order = x.size() - 1;
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if((r_order == 0) && (*px == 0))
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{
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// x is zero, so is the result:
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r = x;
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if(result)
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*result = x;
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return;
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}
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r = x;
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r.sign(false);
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if(result)
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*result = static_cast<limb_type>(0u);
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//
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// Check if the remainder is already less than the divisor, if so
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// we already have the result. Note we try and avoid a full compare
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// if we can:
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//
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if(r_order <= y_order)
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{
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if((r_order < y_order) || (r.compare_unsigned(y) < 0))
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{
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return;
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}
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}
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CppInt1 t;
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bool r_neg = false;
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//
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// See if we can short-circuit long division, and use basic arithmetic instead:
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//
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if(r_order == 0)
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{
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if(result)
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{
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*result = px[0] / py[0];
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}
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r = px[0] % py[0];
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return;
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}
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else if(r_order == 1)
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{
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double_limb_type a, b;
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a = (static_cast<double_limb_type>(px[1]) << CppInt1::limb_bits) | px[0];
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b = y_order ?
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(static_cast<double_limb_type>(py[1]) << CppInt1::limb_bits) | py[0]
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: py[0];
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if(result)
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{
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*result = a / b;
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}
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r = a % b;
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return;
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}
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//
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// prepare result:
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//
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if(result)
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result->resize(1 + r_order - y_order, 1 + r_order - y_order);
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typename CppInt1::const_limb_pointer prem = r.limbs();
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// This is initialised just to keep the compiler from emitting useless warnings later on:
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typename CppInt1::limb_pointer pr
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= typename CppInt1::limb_pointer();
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if(result)
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{
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pr = result->limbs();
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for(unsigned i = 1; i < 1 + r_order - y_order; ++i)
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pr[i] = 0;
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}
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bool first_pass = true;
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do
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{
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//
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// Calculate our best guess for how many times y divides into r:
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//
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limb_type guess;
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if((prem[r_order] <= py[y_order]) && (r_order > 0))
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{
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double_limb_type a, b, v;
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a = (static_cast<double_limb_type>(prem[r_order]) << CppInt1::limb_bits) | prem[r_order - 1];
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b = py[y_order];
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v = a / b;
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if(v > CppInt1::max_limb_value)
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guess = 1;
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else
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{
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guess = static_cast<limb_type>(v);
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--r_order;
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}
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}
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else if(r_order == 0)
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{
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guess = prem[0] / py[y_order];
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}
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else
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{
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double_limb_type a, b, v;
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a = (static_cast<double_limb_type>(prem[r_order]) << CppInt1::limb_bits) | prem[r_order - 1];
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b = (y_order > 0) ? (static_cast<double_limb_type>(py[y_order]) << CppInt1::limb_bits) | py[y_order - 1] : (static_cast<double_limb_type>(py[y_order]) << CppInt1::limb_bits);
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v = a / b;
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guess = static_cast<limb_type>(v);
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}
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BOOST_ASSERT(guess); // If the guess ever gets to zero we go on forever....
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//
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// Update result:
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//
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limb_type shift = r_order - y_order;
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if(result)
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{
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if(r_neg)
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{
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if(pr[shift] > guess)
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pr[shift] -= guess;
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else
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{
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t.resize(shift + 1, shift + 1);
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t.limbs()[shift] = guess;
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for(unsigned i = 0; i < shift; ++i)
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t.limbs()[i] = 0;
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eval_subtract(*result, t);
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}
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}
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else if(CppInt1::max_limb_value - pr[shift] > guess)
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pr[shift] += guess;
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else
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{
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t.resize(shift + 1, shift + 1);
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t.limbs()[shift] = guess;
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for(unsigned i = 0; i < shift; ++i)
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t.limbs()[i] = 0;
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eval_add(*result, t);
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}
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}
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//
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// Calculate guess * y, we use a fused mutiply-shift O(N) for this
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// rather than a full O(N^2) multiply:
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//
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double_limb_type carry = 0;
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t.resize(y.size() + shift + 1, y.size() + shift);
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bool truncated_t = !CppInt1::variable && (t.size() != y.size() + shift + 1);
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typename CppInt1::limb_pointer pt = t.limbs();
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for(unsigned i = 0; i < shift; ++i)
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pt[i] = 0;
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for(unsigned i = 0; i < y.size(); ++i)
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{
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carry += static_cast<double_limb_type>(py[i]) * static_cast<double_limb_type>(guess);
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#ifdef __MSVC_RUNTIME_CHECKS
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pt[i + shift] = static_cast<limb_type>(carry & ~static_cast<limb_type>(0));
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#else
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pt[i + shift] = static_cast<limb_type>(carry);
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#endif
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carry >>= CppInt1::limb_bits;
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}
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if(carry && !truncated_t)
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{
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#ifdef __MSVC_RUNTIME_CHECKS
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pt[t.size() - 1] = static_cast<limb_type>(carry & ~static_cast<limb_type>(0));
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#else
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pt[t.size() - 1] = static_cast<limb_type>(carry);
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#endif
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}
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else if(!truncated_t)
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{
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t.resize(t.size() - 1, t.size() - 1);
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}
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//
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// Update r in a way that won't actually produce a negative result
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// in case the argument types are unsigned:
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//
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if(truncated_t && carry)
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{
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// We need to calculate 2^n + t - r
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// where n is the number of bits in this type.
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// Simplest way is to get 2^n - r by complementing
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// r, then add t to it. Note that we can't call eval_complement
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// in case this is a signed checked type:
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for(unsigned i = 0; i <= r_order; ++i)
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r.limbs()[i] = ~prem[i];
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r.normalize();
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eval_increment(r);
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eval_add(r, t);
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r_neg = !r_neg;
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}
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else if(r.compare(t) > 0)
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{
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eval_subtract(r, t);
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}
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else
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{
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r.swap(t);
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eval_subtract(r, t);
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prem = r.limbs();
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r_neg = !r_neg;
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}
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//
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// First time through we need to strip any leading zero, otherwise
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// the termination condition goes belly-up:
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//
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if(result && first_pass)
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{
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first_pass = false;
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while(pr[result->size() - 1] == 0)
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result->resize(result->size() - 1, result->size() - 1);
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}
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//
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// Update r_order:
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//
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r_order = r.size() - 1;
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if(r_order < y_order)
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break;
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}
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// Termination condition is really just a check that r > y, but with a common
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// short-circuit case handled first:
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while((r_order > y_order) || (r.compare_unsigned(y) >= 0));
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//
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// We now just have to normalise the result:
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//
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if(r_neg && eval_get_sign(r))
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{
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// We have one too many in the result:
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if(result)
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eval_decrement(*result);
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if(y.sign())
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{
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r.negate();
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eval_subtract(r, y);
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}
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else
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eval_subtract(r, y, r);
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}
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BOOST_ASSERT(r.compare_unsigned(y) < 0); // remainder must be less than the divisor or our code has failed
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}
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template <class CppInt1, class CppInt2>
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void divide_unsigned_helper(
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CppInt1* result,
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const CppInt2& x,
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limb_type y,
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CppInt1& r)
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{
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if(((void*)result == (void*)&x) || ((void*)&r == (void*)&x))
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{
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CppInt2 t(x);
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divide_unsigned_helper(result, t, y, r);
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return;
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}
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if(result == &r)
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{
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CppInt1 rem;
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divide_unsigned_helper(result, x, y, rem);
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r = rem;
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return;
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}
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// As above, but simplified for integer divisor:
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using default_ops::eval_subtract;
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if(y == 0)
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{
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BOOST_THROW_EXCEPTION(std::overflow_error("Integer Division by zero."));
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}
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//
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// Find the most significant word of numerator.
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//
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limb_type r_order = x.size() - 1;
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//
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// Set remainder and result to their initial values:
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//
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r = x;
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r.sign(false);
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typename CppInt1::limb_pointer pr = r.limbs();
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//
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// check for x < y, try to do this without actually having to
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// do a full comparison:
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//
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if((r_order == 0) && (*pr < y))
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{
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if(result)
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*result = static_cast<limb_type>(0u);
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return;
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}
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//
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// See if we can short-circuit long division, and use basic arithmetic instead:
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//
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if(r_order == 0)
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{
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if(result)
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{
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*result = *pr / y;
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result->sign(x.sign());
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}
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*pr %= y;
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r.sign(x.sign());
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return;
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}
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else if(r_order == 1)
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{
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double_limb_type a;
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a = (static_cast<double_limb_type>(pr[r_order]) << CppInt1::limb_bits) | pr[0];
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if(result)
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{
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*result = a / y;
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result->sign(x.sign());
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}
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r = a % y;
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r.sign(x.sign());
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return;
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}
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// This is initialised just to keep the compiler from emitting useless warnings later on:
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typename CppInt1::limb_pointer pres = typename CppInt1::limb_pointer();
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if(result)
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{
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result->resize(r_order + 1, r_order + 1);
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pres = result->limbs();
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if(result->size() > r_order)
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pres[r_order] = 0; // just in case we don't set the most significant limb below.
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}
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do
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{
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//
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// Calculate our best guess for how many times y divides into r:
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//
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if((pr[r_order] < y) && r_order)
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{
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double_limb_type a, b;
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a = (static_cast<double_limb_type>(pr[r_order]) << CppInt1::limb_bits) | pr[r_order - 1];
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b = a % y;
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r.resize(r.size() - 1, r.size() - 1);
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--r_order;
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pr[r_order] = static_cast<limb_type>(b);
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if(result)
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pres[r_order] = static_cast<limb_type>(a / y);
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if(r_order && pr[r_order] == 0)
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{
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--r_order; // No remainder, division was exact.
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r.resize(r.size() - 1, r.size() - 1);
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if(result)
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pres[r_order] = static_cast<limb_type>(0u);
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}
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}
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else
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{
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if(result)
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pres[r_order] = pr[r_order] / y;
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pr[r_order] %= y;
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if(r_order && pr[r_order] == 0)
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{
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--r_order; // No remainder, division was exact.
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r.resize(r.size() - 1, r.size() - 1);
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if(result)
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pres[r_order] = static_cast<limb_type>(0u);
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}
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}
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}
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// Termination condition is really just a check that r >= y, but with two common
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// short-circuit cases handled first:
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while(r_order || (pr[r_order] >= y));
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if(result)
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{
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result->normalize();
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result->sign(x.sign());
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}
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r.normalize();
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r.sign(x.sign());
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BOOST_ASSERT(r.compare(y) < 0); // remainder must be less than the divisor or our code has failed
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2, unsigned MinBits3, unsigned MaxBits3, cpp_integer_type SignType3, cpp_int_check_type Checked3, class Allocator3>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits3, MaxBits3, SignType3, Checked3, Allocator3> >::value >::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a,
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const cpp_int_backend<MinBits3, MaxBits3, SignType3, Checked3, Allocator3>& b)
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{
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> r;
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bool s = a.sign() != b.sign();
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divide_unsigned_helper(&result, a, b, r);
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result.sign(s);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a,
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limb_type& b)
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{
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> r;
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bool s = a.sign();
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divide_unsigned_helper(&result, a, b, r);
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result.sign(s);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a,
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signed_limb_type& b)
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{
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> r;
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bool s = a.sign() != (b < 0);
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divide_unsigned_helper(&result, a, static_cast<limb_type>(boost::multiprecision::detail::unsigned_abs(b)), r);
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result.sign(s);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& b)
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{
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// There is no in place divide:
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
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eval_divide(result, a, b);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value>::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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limb_type b)
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{
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// There is no in place divide:
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
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eval_divide(result, a, b);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value>::type
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eval_divide(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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signed_limb_type b)
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{
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// There is no in place divide:
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
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eval_divide(result, a, b);
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}
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2, unsigned MinBits3, unsigned MaxBits3, cpp_integer_type SignType3, cpp_int_check_type Checked3, class Allocator3>
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BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits3, MaxBits3, SignType3, Checked3, Allocator3> >::value >::type
|
|
eval_modulus(
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cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
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const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a,
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const cpp_int_backend<MinBits3, MaxBits3, SignType3, Checked3, Allocator3>& b)
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{
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bool s = a.sign();
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divide_unsigned_helper(static_cast<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>* >(0), a, b, result);
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result.sign(s);
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}
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|
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
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|
BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a, limb_type b)
|
|
{
|
|
bool s = a.sign();
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divide_unsigned_helper(static_cast<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>* >(0), a, b, result);
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result.sign(s);
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|
}
|
|
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& a,
|
|
signed_limb_type b)
|
|
{
|
|
bool s = a.sign();
|
|
divide_unsigned_helper(static_cast<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>* >(0), a, static_cast<limb_type>(boost::multiprecision::detail::unsigned_abs(b)), result);
|
|
result.sign(s);
|
|
}
|
|
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template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1, unsigned MinBits2, unsigned MaxBits2, cpp_integer_type SignType2, cpp_int_check_type Checked2, class Allocator2>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value && !is_trivial_cpp_int<cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2> >::value >::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits2, MaxBits2, SignType2, Checked2, Allocator2>& b)
|
|
{
|
|
// There is no in place divide:
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
|
|
eval_modulus(result, a, b);
|
|
}
|
|
|
|
template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value>::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
limb_type b)
|
|
{
|
|
// There is no in place divide:
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
|
|
eval_modulus(result, a, b);
|
|
}
|
|
|
|
template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<!is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value>::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
signed_limb_type b)
|
|
{
|
|
// There is no in place divide:
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> a(result);
|
|
eval_modulus(result, a, b);
|
|
}
|
|
|
|
//
|
|
// Over again for trivial cpp_int's:
|
|
//
|
|
template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<
|
|
is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& (is_signed_number<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
|| is_signed_number<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value)
|
|
>::type
|
|
eval_divide(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& o)
|
|
{
|
|
if(!*o.limbs())
|
|
BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero."));
|
|
*result.limbs() /= *o.limbs();
|
|
result.sign(result.sign() != o.sign());
|
|
}
|
|
|
|
template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<
|
|
is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& is_unsigned_number<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& is_unsigned_number<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
>::type
|
|
eval_divide(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& o)
|
|
{
|
|
if(!*o.limbs())
|
|
BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero."));
|
|
*result.limbs() /= *o.limbs();
|
|
}
|
|
|
|
template <unsigned MinBits1, unsigned MaxBits1, cpp_integer_type SignType1, cpp_int_check_type Checked1, class Allocator1>
|
|
BOOST_MP_FORCEINLINE typename enable_if_c<
|
|
is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
&& is_trivial_cpp_int<cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1> >::value
|
|
>::type
|
|
eval_modulus(
|
|
cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& result,
|
|
const cpp_int_backend<MinBits1, MaxBits1, SignType1, Checked1, Allocator1>& o)
|
|
{
|
|
if(!*o.limbs())
|
|
BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero."));
|
|
*result.limbs() %= *o.limbs();
|
|
result.sign(result.sign());
|
|
}
|
|
|
|
}}} // namespaces
|
|
|
|
#endif
|