/* $Id$ */ # ifndef CPPAD_ADD_OP_INCLUDED # define CPPAD_ADD_OP_INCLUDED /* -------------------------------------------------------------------------- CppAD: C++ Algorithmic Differentiation: Copyright (C) 2003-14 Bradley M. Bell CppAD is distributed under multiple licenses. This distribution is under the terms of the GNU General Public License Version 3. A copy of this license is included in the COPYING file of this distribution. Please visit http://www.coin-or.org/CppAD/ for information on other licenses. -------------------------------------------------------------------------- */ namespace CppAD { // BEGIN_CPPAD_NAMESPACE /*! \file add_op.hpp Forward and reverse mode calculations for z = x + y. */ // --------------------------- Addvv ----------------------------------------- /*! Compute forward mode Taylor coefficients for result of op = AddvvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where both x and y are variables and the argument \a parameter is not used. \copydetails forward_binary_op */ template inline void forward_addvv_op( size_t p , size_t q , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddvvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddvvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); CPPAD_ASSERT_UNKNOWN( p <= q ); // Taylor coefficients corresponding to arguments and result Base* x = taylor + arg[0] * cap_order; Base* y = taylor + arg[1] * cap_order; Base* z = taylor + i_z * cap_order; for(size_t j = p; j <= q; j++) z[j] = x[j] + y[j]; } /*! Multiple directions forward mode Taylor coefficients for op = AddvvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where both x and y are variables and the argument \a parameter is not used. \copydetails forward_binary_op_dir */ template inline void forward_addvv_op_dir( size_t q , size_t r , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddvvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddvvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); CPPAD_ASSERT_UNKNOWN( 0 < q ); // Taylor coefficients corresponding to arguments and result size_t num_taylor_per_var = (cap_order-1) * r + 1; Base* x = taylor + arg[0] * num_taylor_per_var; Base* y = taylor + arg[1] * num_taylor_per_var; Base* z = taylor + i_z * num_taylor_per_var; size_t m = (q-1)*r + 1 ; for(size_t ell = 0; ell < r; ell++) z[m+ell] = x[m+ell] + y[m+ell]; } /*! Compute zero order forward mode Taylor coefficients for result of op = AddvvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where both x and y are variables and the argument \a parameter is not used. \copydetails forward_binary_op_0 */ template inline void forward_addvv_op_0( size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddvvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddvvOp) == 1 ); // Taylor coefficients corresponding to arguments and result Base* x = taylor + arg[0] * cap_order; Base* y = taylor + arg[1] * cap_order; Base* z = taylor + i_z * cap_order; z[0] = x[0] + y[0]; } /*! Compute reverse mode partial derivatives for result of op = AddvvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where both x and y are variables and the argument \a parameter is not used. \copydetails reverse_binary_op */ template inline void reverse_addvv_op( size_t d , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , const Base* taylor , size_t nc_partial , Base* partial ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddvvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddvvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( d < cap_order ); CPPAD_ASSERT_UNKNOWN( d < nc_partial ); // Partial derivatives corresponding to arguments and result Base* px = partial + arg[0] * nc_partial; Base* py = partial + arg[1] * nc_partial; Base* pz = partial + i_z * nc_partial; // number of indices to access size_t i = d + 1; while(i) { --i; px[i] += pz[i]; py[i] += pz[i]; } } // --------------------------- Addpv ----------------------------------------- /*! Compute forward mode Taylor coefficients for result of op = AddpvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where x is a parameter and y is a variable. \copydetails forward_binary_op */ template inline void forward_addpv_op( size_t p , size_t q , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddpvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddpvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); CPPAD_ASSERT_UNKNOWN( p <= q ); // Taylor coefficients corresponding to arguments and result Base* y = taylor + arg[1] * cap_order; Base* z = taylor + i_z * cap_order; if( p == 0 ) { // Paraemter value Base x = parameter[ arg[0] ]; z[0] = x + y[0]; p++; } for(size_t j = p; j <= q; j++) z[j] = y[j]; } /*! Multiple directions forward mode Taylor coefficients for op = AddpvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where x is a parameter and y is a variable. \copydetails forward_binary_op_dir */ template inline void forward_addpv_op_dir( size_t q , size_t r , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddpvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddpvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( 0 < q ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); // Taylor coefficients corresponding to arguments and result size_t num_taylor_per_var = (cap_order-1) * r + 1; size_t m = (q-1) * r + 1; Base* y = taylor + arg[1] * num_taylor_per_var + m; Base* z = taylor + i_z * num_taylor_per_var + m; for(size_t ell = 0; ell < r; ell++) z[ell] = y[ell]; } /*! Compute zero order forward mode Taylor coefficient for result of op = AddpvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where x is a parameter and y is a variable. \copydetails forward_binary_op_0 */ template inline void forward_addpv_op_0( size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddpvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddpvOp) == 1 ); // Paraemter value Base x = parameter[ arg[0] ]; // Taylor coefficients corresponding to arguments and result Base* y = taylor + arg[1] * cap_order; Base* z = taylor + i_z * cap_order; z[0] = x + y[0]; } /*! Compute reverse mode partial derivative for result of op = AddpvOp. The C++ source code corresponding to this operation is \verbatim z = x + y \endverbatim In the documentation below, this operations is for the case where x is a parameter and y is a variable. \copydetails reverse_binary_op */ template inline void reverse_addpv_op( size_t d , size_t i_z , const addr_t* arg , const Base* parameter , size_t cap_order , const Base* taylor , size_t nc_partial , Base* partial ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AddvvOp) == 2 ); CPPAD_ASSERT_UNKNOWN( NumRes(AddvvOp) == 1 ); CPPAD_ASSERT_UNKNOWN( d < cap_order ); CPPAD_ASSERT_UNKNOWN( d < nc_partial ); // Partial derivatives corresponding to arguments and result Base* py = partial + arg[1] * nc_partial; Base* pz = partial + i_z * nc_partial; // number of indices to access size_t i = d + 1; while(i) { --i; py[i] += pz[i]; } } } // END_CPPAD_NAMESPACE # endif