/* $Id$ */ # ifndef CPPAD_ATAN_OP_INCLUDED # define CPPAD_ATAN_OP_INCLUDED /* -------------------------------------------------------------------------- CppAD: C++ Algorithmic Differentiation: Copyright (C) 2003-15 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 atan_op.hpp Forward and reverse mode calculations for z = atan(x). */ /*! Forward mode Taylor coefficient for result of op = AtanOp. The C++ source code corresponding to this operation is \verbatim z = atan(x) \endverbatim The auxillary result is \verbatim y = 1 + x * x \endverbatim The value of y, and its derivatives, are computed along with the value and derivatives of z. \copydetails forward_unary2_op */ template inline void forward_atan_op( size_t p , size_t q , size_t i_z , size_t i_x , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AtanOp) == 1 ); CPPAD_ASSERT_UNKNOWN( NumRes(AtanOp) == 2 ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); CPPAD_ASSERT_UNKNOWN( p <= q ); // Taylor coefficients corresponding to argument and result Base* x = taylor + i_x * cap_order; Base* z = taylor + i_z * cap_order; Base* b = z - cap_order; // called y in documentation size_t k; if( p == 0 ) { z[0] = atan( x[0] ); b[0] = Base(1) + x[0] * x[0]; p++; } for(size_t j = p; j <= q; j++) { b[j] = Base(2) * x[0] * x[j]; z[j] = Base(0); for(k = 1; k < j; k++) { b[j] += x[k] * x[j-k]; z[j] -= Base(k) * z[k] * b[j-k]; } z[j] /= Base(j); z[j] += x[j]; z[j] /= b[0]; } } /*! Multiple direction Taylor coefficient for op = AtanOp. The C++ source code corresponding to this operation is \verbatim z = atan(x) \endverbatim The auxillary result is \verbatim y = 1 + x * x \endverbatim The value of y, and its derivatives, are computed along with the value and derivatives of z. \copydetails forward_unary2_op_dir */ template inline void forward_atan_op_dir( size_t q , size_t r , size_t i_z , size_t i_x , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AtanOp) == 1 ); CPPAD_ASSERT_UNKNOWN( NumRes(AtanOp) == 2 ); CPPAD_ASSERT_UNKNOWN( 0 < q ); CPPAD_ASSERT_UNKNOWN( q < cap_order ); // Taylor coefficients corresponding to argument and result size_t num_taylor_per_var = (cap_order-1) * r + 1; Base* x = taylor + i_x * num_taylor_per_var; Base* z = taylor + i_z * num_taylor_per_var; Base* b = z - num_taylor_per_var; // called y in documentation size_t m = (q-1) * r + 1; for(size_t ell = 0; ell < r; ell++) { b[m+ell] = Base(2) * x[m+ell] * x[0]; z[m+ell] = Base(q) * x[m+ell]; for(size_t k = 1; k < q; k++) { b[m+ell] += x[(k-1)*r+1+ell] * x[(q-k-1)*r+1+ell]; z[m+ell] -= Base(k) * z[(k-1)*r+1+ell] * b[(q-k-1)*r+1+ell]; } z[m+ell] /= ( Base(q) * b[0] ); } } /*! Zero order forward mode Taylor coefficient for result of op = AtanOp. The C++ source code corresponding to this operation is \verbatim z = atan(x) \endverbatim The auxillary result is \verbatim y = 1 + x * x \endverbatim The value of y is computed along with the value of z. \copydetails forward_unary2_op_0 */ template inline void forward_atan_op_0( size_t i_z , size_t i_x , size_t cap_order , Base* taylor ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AtanOp) == 1 ); CPPAD_ASSERT_UNKNOWN( NumRes(AtanOp) == 2 ); CPPAD_ASSERT_UNKNOWN( 0 < cap_order ); // Taylor coefficients corresponding to argument and result Base* x = taylor + i_x * cap_order; Base* z = taylor + i_z * cap_order; Base* b = z - cap_order; // called y in documentation z[0] = atan( x[0] ); b[0] = Base(1) + x[0] * x[0]; } /*! Reverse mode partial derivatives for result of op = AtanOp. The C++ source code corresponding to this operation is \verbatim z = atan(x) \endverbatim The auxillary result is \verbatim y = 1 + x * x \endverbatim The value of y is computed along with the value of z. \copydetails reverse_unary2_op */ template inline void reverse_atan_op( size_t d , size_t i_z , size_t i_x , size_t cap_order , const Base* taylor , size_t nc_partial , Base* partial ) { // check assumptions CPPAD_ASSERT_UNKNOWN( NumArg(AtanOp) == 1 ); CPPAD_ASSERT_UNKNOWN( NumRes(AtanOp) == 2 ); CPPAD_ASSERT_UNKNOWN( d < cap_order ); CPPAD_ASSERT_UNKNOWN( d < nc_partial ); // Taylor coefficients and partials corresponding to argument const Base* x = taylor + i_x * cap_order; Base* px = partial + i_x * nc_partial; // Taylor coefficients and partials corresponding to first result const Base* z = taylor + i_z * cap_order; Base* pz = partial + i_z * nc_partial; // Taylor coefficients and partials corresponding to auxillary result const Base* b = z - cap_order; // called y in documentation Base* pb = pz - nc_partial; // If pz is zero, make sure this operation has no effect // (zero times infinity or nan would be non-zero). bool skip(true); for(size_t i_d = 0; i_d <= d; i_d++) skip &= IdenticalZero(pz[i_d]); if( skip ) return; // number of indices to access size_t j = d; size_t k; while(j) { // scale partials w.r.t z[j] and b[j] pz[j] /= b[0]; pb[j] *= Base(2); pb[0] -= pz[j] * z[j]; px[j] += pz[j] + pb[j] * x[0]; px[0] += pb[j] * x[j]; // more scaling of partials w.r.t z[j] pz[j] /= Base(j); for(k = 1; k < j; k++) { pb[j-k] -= pz[j] * Base(k) * z[k]; pz[k] -= pz[j] * Base(k) * b[j-k]; px[k] += pb[j] * x[j-k]; } --j; } px[0] += pz[0] / b[0] + pb[0] * Base(2) * x[0]; } } // END_CPPAD_NAMESPACE # endif