Sacado Package Browser (Single Doxygen Collection): dfad_sfc

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00001 // $Id$ 
00002 // $Source$ 
00003 // @HEADER
00004 // ***********************************************************************
00005 // 
00006 //                           Sacado Package
00007 //                 Copyright (2006) Sandia Corporation
00008 // 
00009 // Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation,
00010 // the U.S. Government retains certain rights in this software.
00011 // 
00012 // This library is free software; you can redistribute it and/or modify
00013 // it under the terms of the GNU Lesser General Public License as
00014 // published by the Free Software Foundation; either version 2.1 of the
00015 // License, or (at your option) any later version.
00016 //  
00017 // This library is distributed in the hope that it will be useful, but
00018 // WITHOUT ANY WARRANTY; without even the implied warranty of
00019 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
00020 // Lesser General Public License for more details.
00021 //  
00022 // You should have received a copy of the GNU Lesser General Public
00023 // License along with this library; if not, write to the Free Software
00024 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
00025 // USA
00026 // Questions? Contact David M. Gay (dmgay@sandia.gov) or Eric T. Phipps
00027 // (etphipp@sandia.gov).
00028 // 
00029 // ***********************************************************************
00030 // @HEADER
00031 
00032 // dfad_sfc_example
00033 //
00034 //  usage: 
00035 //     dfad_sfc_example
00036 //
00037 //  output:  
00038 //     Uses the scalar flop counter to count the flops for a derivative
00039 //     of a simple function using DFad
00040 
00041 #include <iostream>
00042 #include <iomanip>
00043 
00044 #include "Sacado.hpp"
00045 
00046 // The function to differentiate
00047 template <typename ScalarT>
00048 ScalarT func(const ScalarT& a, const ScalarT& b, const ScalarT& c) {
00049   ScalarT r = c*std::log(b+1.)/std::sin(a);
00050 
00051   return r;
00052 }
00053 
00054 // The analytic derivative of func(a,b,c) with respect to a and b
00055 template <typename ScalarT>
00056 void func_deriv(const ScalarT& a, const ScalarT& b, const ScalarT& c, 
00057     ScalarT& drda, ScalarT& drdb)
00058 {
00059   drda = -(c*std::log(b+1.)/std::pow(std::sin(a),2))*std::cos(a);
00060   drdb = c / ((b+1.)*std::sin(a));
00061 }
00062 
00063 typedef Sacado::FlopCounterPack::ScalarFlopCounter<double> SFC;
00064 typedef Sacado::Fad::DFad<SFC> FAD_SFC;
00065 
00066 int main(int argc, char **argv)
00067 {
00068   double pi = std::atan(1.0)*4.0;
00069 
00070   // Values of function arguments
00071   double a = pi/4;
00072   double b = 2.0;
00073   double c = 3.0;
00074 
00075   // Number of independent variables
00076   int num_deriv = 2;
00077 
00078   // Compute function
00079   SFC as(a);
00080   SFC bs(b);
00081   SFC cs(c);
00082   SFC::resetCounters();
00083   SFC rs = func(as, bs, cs);
00084   SFC::finalizeCounters();
00085 
00086   std::cout << "Flop counts for function evaluation:";
00087   SFC::printCounters(std::cout);
00088 
00089   // Compute derivative analytically
00090   SFC drdas, drdbs;
00091   SFC::resetCounters();
00092   func_deriv(as, bs, cs, drdas, drdbs);
00093   SFC::finalizeCounters();
00094 
00095   std::cout << "\nFlop counts for analytic derivative evaluation:";
00096   SFC::printCounters(std::cout);
00097 
00098   // Compute function and derivative with AD
00099   FAD_SFC afad(num_deriv, 0, a); 
00100   FAD_SFC bfad(num_deriv, 1, b); 
00101   FAD_SFC cfad(c);               
00102   SFC::resetCounters();
00103   FAD_SFC rfad = func(afad, bfad, cfad);
00104   SFC::finalizeCounters();
00105 
00106   std::cout << "\nFlop counts for AD function and derivative evaluation:";
00107   SFC::printCounters(std::cout);
00108 
00109   // Extract value and derivatives
00110   double r = rs.val();               // r
00111   double drda = drdas.val();         // dr/da
00112   double drdb = drdbs.val();         // dr/db
00113 
00114   double r_ad = rfad.val().val();     // r
00115   double drda_ad = rfad.dx(0).val();  // dr/da
00116   double drdb_ad = rfad.dx(1).val();  // dr/db
00117 
00118   // Print the results
00119   int p = 4;
00120   int w = p+7;
00121   std::cout.setf(std::ios::scientific);
00122   std::cout.precision(p);
00123   std::cout << "\nValues/derivatives of computation" << std::endl
00124       << "    r =  " << r << " (original) == " << std::setw(w) << r_ad
00125       << " (AD) Error = " << std::setw(w) << r - r_ad << std::endl
00126       << "dr/da = " << std::setw(w) << drda << " (analytic) == " 
00127       << std::setw(w) << drda_ad << " (AD) Error = " << std::setw(w) 
00128       << drda - drda_ad << std::endl
00129       << "dr/db = " << std::setw(w) << drdb << " (analytic) == " 
00130       << std::setw(w) << drdb_ad << " (AD) Error = " << std::setw(w) 
00131       << drdb - drdb_ad << std::endl;
00132 
00133   double tol = 1.0e-14;
00134   Sacado::FlopCounterPack::FlopCounts fc = SFC::getCounters();
00135   // The Solaris and Irix CC compilers get higher counts for operator=
00136   // than does g++, which avoids an extra copy when returning a function value.
00137   // The test on fc.totalFlopCount allows for this variation.
00138   if (std::fabs(r - r_ad)       < tol &&
00139       std::fabs(drda - drda_ad) < tol &&
00140       std::fabs(drdb - drdb_ad) < tol &&
00141       (fc.totalFlopCount == 40)) {
00142     std::cout << "\nExample passed!" << std::endl;
00143     return 0;
00144   }
00145   else {
00146     std::cout <<"\nSomething is wrong, example failed!" << std::endl;
00147     return 1;
00148   }
00149 }