mailiverse/cpp/Lib/xcode-botan/Botan-1.10.3-clean/doc/examples/factor.cpp

/*
* (C) 2009-2010 Jack Lloyd
*
* Distributed under the terms of the Botan license
*
* Factor integers using a combination of trial division by small
* primes, and Pollard's Rho algorithm
*/

#include <botan/botan.h>
#include <botan/reducer.h>
#include <botan/numthry.h>
using namespace Botan;

#include <algorithm>
#include <iostream>
#include <iterator>

namespace {

/*
* Pollard's Rho algorithm, as described in the MIT algorithms book. We
* use (x^2+x) mod n instead of (x*2-1) mod n as the random function,
* it _seems_ to lead to faster factorization for the values I tried.
*/
BigInt rho(const BigInt& n, RandomNumberGenerator& rng)
   {
   BigInt x = BigInt::random_integer(rng, 0, n-1);
   BigInt y = x;
   BigInt d = 0;

   Modular_Reducer mod_n(n);

   u32bit i = 1, k = 2;
   while(true)
      {
      i++;

      if(i == 0) // overflow, bail out
         break;

      x = mod_n.multiply((x + 1), x);

      d = gcd(y - x, n);
      if(d != 1 && d != n)
         return d;

      if(i == k)
         {
         y = x;
         k = 2*k;
         }
      }
   return 0;
   }

// Remove (and return) any small (< 2^16) factors
std::vector<BigInt> remove_small_factors(BigInt& n)
   {
   std::vector<BigInt> factors;

   while(n.is_even())
      {
      factors.push_back(2);
      n /= 2;
      }

   for(u32bit j = 0; j != PRIME_TABLE_SIZE; j++)
      {
      if(n < PRIMES[j])
         break;

      BigInt x = gcd(n, PRIMES[j]);

      if(x != 1)
         {
         n /= x;

         u32bit occurs = 0;
         while(x != 1)
            {
            x /= PRIMES[j];
            occurs++;
            }

         for(u32bit k = 0; k != occurs; k++)
            factors.push_back(PRIMES[j]);
         }
      }

   return factors;
   }

std::vector<BigInt> factorize(const BigInt& n_in,
                              RandomNumberGenerator& rng)
   {
   BigInt n = n_in;
   std::vector<BigInt> factors = remove_small_factors(n);

   while(n != 1)
      {
      if(check_prime(n, rng))
         {
         factors.push_back(n);
         break;
         }

      BigInt a_factor = 0;
      while(a_factor == 0)
         a_factor = rho(n, rng);

      std::vector<BigInt> rho_factored = factorize(a_factor, rng);
      for(u32bit j = 0; j != rho_factored.size(); j++)
         factors.push_back(rho_factored[j]);

      n /= a_factor;
      }
   return factors;
   }

}

int main(int argc, char* argv[])
   {
   if(argc != 2)
      {
      std::cerr << "Usage: " << argv[0] << " integer\n";
      return 1;
      }

   Botan::LibraryInitializer init;

   try
      {
      BigInt n(argv[1]);

      AutoSeeded_RNG rng;

      std::vector<BigInt> factors = factorize(n, rng);
      std::sort(factors.begin(), factors.end());

      std::cout << n << ": ";
      std::copy(factors.begin(),
                factors.end(),
                std::ostream_iterator<BigInt>(std::cout, " "));
      std::cout << "\n";
      }
   catch(std::exception& e)
      {
      std::cout << e.what() << std::endl;
      return 1;
      }
   return 0;
   }
adds the cpp files 2013-07-25 22:51:23 -04:00			`/*`
			`* (C) 2009-2010 Jack Lloyd`
			`*`
			`* Distributed under the terms of the Botan license`
			`*`
			`* Factor integers using a combination of trial division by small`
			`* primes, and Pollard's Rho algorithm`
			`*/`

			`#include <botan/botan.h>`
			`#include <botan/reducer.h>`
			`#include <botan/numthry.h>`
			`using namespace Botan;`

			`#include <algorithm>`
			`#include <iostream>`
			`#include <iterator>`

			`namespace {`

			`/*`
			`* Pollard's Rho algorithm, as described in the MIT algorithms book. We`
			`* use (x^2+x) mod n instead of (x*2-1) mod n as the random function,`
			`* it _seems_ to lead to faster factorization for the values I tried.`
			`*/`
			`BigInt rho(const BigInt& n, RandomNumberGenerator& rng)`
			`{`
			`BigInt x = BigInt::random_integer(rng, 0, n-1);`
			`BigInt y = x;`
			`BigInt d = 0;`

			`Modular_Reducer mod_n(n);`

			`u32bit i = 1, k = 2;`
			`while(true)`
			`{`
			`i++;`

			`if(i == 0) // overflow, bail out`
			`break;`

			`x = mod_n.multiply((x + 1), x);`

			`d = gcd(y - x, n);`
			`if(d != 1 && d != n)`
			`return d;`

			`if(i == k)`
			`{`
			`y = x;`
			`k = 2*k;`
			`}`
			`}`
			`return 0;`
			`}`

			`// Remove (and return) any small (< 2^16) factors`
			`std::vector<BigInt> remove_small_factors(BigInt& n)`
			`{`
			`std::vector<BigInt> factors;`

			`while(n.is_even())`
			`{`
			`factors.push_back(2);`
			`n /= 2;`
			`}`

			`for(u32bit j = 0; j != PRIME_TABLE_SIZE; j++)`
			`{`
			`if(n < PRIMES[j])`
			`break;`

			`BigInt x = gcd(n, PRIMES[j]);`

			`if(x != 1)`
			`{`
			`n /= x;`

			`u32bit occurs = 0;`
			`while(x != 1)`
			`{`
			`x /= PRIMES[j];`
			`occurs++;`
			`}`

			`for(u32bit k = 0; k != occurs; k++)`
			`factors.push_back(PRIMES[j]);`
			`}`
			`}`

			`return factors;`
			`}`

			`std::vector<BigInt> factorize(const BigInt& n_in,`
			`RandomNumberGenerator& rng)`
			`{`
			`BigInt n = n_in;`
			`std::vector<BigInt> factors = remove_small_factors(n);`

			`while(n != 1)`
			`{`
			`if(check_prime(n, rng))`
			`{`
			`factors.push_back(n);`
			`break;`
			`}`

			`BigInt a_factor = 0;`
			`while(a_factor == 0)`
			`a_factor = rho(n, rng);`

			`std::vector<BigInt> rho_factored = factorize(a_factor, rng);`
			`for(u32bit j = 0; j != rho_factored.size(); j++)`
			`factors.push_back(rho_factored[j]);`

			`n /= a_factor;`
			`}`
			`return factors;`
			`}`

			`}`

			`int main(int argc, char* argv[])`
			`{`
			`if(argc != 2)`
			`{`
			`std::cerr << "Usage: " << argv[0] << " integer\n";`
			`return 1;`
			`}`

			`Botan::LibraryInitializer init;`

			`try`
			`{`
			`BigInt n(argv[1]);`

			`AutoSeeded_RNG rng;`

			`std::vector<BigInt> factors = factorize(n, rng);`
			`std::sort(factors.begin(), factors.end());`

			`std::cout << n << ": ";`
			`std::copy(factors.begin(),`
			`factors.end(),`
			`std::ostream_iterator<BigInt>(std::cout, " "));`
			`std::cout << "\n";`
			`}`
			`catch(std::exception& e)`
			`{`
			`std::cout << e.what() << std::endl;`
			`return 1;`
			`}`
			`return 0;`
			`}`