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/*
LA : linear algebra C + + interface library
Copyright ( C ) 2008 Jiri Pittner < jiri . pittner @ jh - inst . cas . cz > or < jiri @ pittnerovi . com >
This program is free software : you can redistribute it and / or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation , either version 3 of the License , or
( at your option ) any later version .
This program is distributed in the hope that it will be useful ,
but WITHOUT ANY WARRANTY ; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
GNU General Public License for more details .
You should have received a copy of the GNU General Public License
along with this program . If not , see < http : //www.gnu.org/licenses/>.
*/
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# ifndef _MATEXP_H_
# define _MATEXP_H_
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//general routine for polynomial of a matrix, tuned to minimize the number
//of matrix-matrix multiplications on cost of additions and memory
// the polynom and exp routines will work on any type, for which traits class
// is defined containing definition of an element type, norm and axpy operation
# include "la_traits.h"
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# include "laerror.h"
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# include <math.h>
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namespace LA {
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template < class T , class R >
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const T polynom0 ( const T & x , const NRVec < R > & c )
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{
int order = c . size ( ) - 1 ;
T z , y ;
//trivial reference implementation by horner scheme
if ( order = = 0 ) { y = x ; y = c [ 0 ] ; } //to avoid the problem: we do not know the size of the matrix to contruct a scalar one
else
{
int i ;
z = x * c [ order ] ;
for ( i = order - 1 ; i > = 0 ; i - - )
{
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//std::cerr<<"TEST polynom0 "<<i<<'\n';
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if ( i < order - 1 ) { LA_traits < T > : : deallocate ( z ) ; z = y * x ; } //for large matrices avoid storing 4 ones simultaneously
LA_traits < T > : : deallocate ( y ) ; y = z + c [ i ] ;
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}
}
return y ;
}
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//algorithm which minimazes number of multiplications, at the cost of storage
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template < class T , class R >
const T polynom ( const T & x , const NRVec < R > & c )
{
int n = c . size ( ) - 1 ;
int i , j , k , m = 0 , t ;
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if ( n < = 4 ) return polynom0 ( x , c ) ; //here the horner scheme is optimal
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//first find m which minimizes the number of multiplications
j = 10 * n ;
for ( i = 2 ; i < = n + 1 ; i + + )
{
t = i - 2 + 2 * ( n / i ) - ( n % i ) ? 0 : 1 ;
if ( t < j )
{
j = t ;
m = i ;
}
}
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//allocate array for powers up to m
T * xpows = new T [ m ] ;
xpows [ 0 ] = x ;
for ( i = 1 ; i < m ; i + + ) xpows [ i ] = xpows [ i - 1 ] * x ;
//run the summation loop
T r , s , f ;
k = - 1 ;
for ( i = 0 ; i < = n / m ; i + + )
{
for ( j = 0 ; j < m ; j + + )
{
k + + ;
if ( k > n ) break ;
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if ( j = = 0 ) {
if ( i = = 0 ) s = x ; /*just to get the dimensions of the matrix*/
s = c [ k ] ; /*create diagonal matrix*/
}
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else
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LA_traits < T > : : axpy ( s , xpows [ j - 1 ] , c [ k ] ) ; //general s+=xpows[j-1]*c[k]; but more efficient for matrices
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}
if ( i = = 0 ) { r = s ; f = xpows [ m - 1 ] ; }
else
{
r + = s * f ;
f = f * xpows [ m - 1 ] ;
}
}
delete [ ] xpows ;
return r ;
}
//for general objects
template < class T >
const T ncommutator ( const T & x , const T & y , int nest = 1 , const bool right = 1 )
{
T z ;
if ( right ) { z = x ; while ( - - nest > = 0 ) z = z * y - y * z ; }
else { z = y ; while ( - - nest > = 0 ) z = x * z - z * x ; }
return z ;
}
template < class T >
const T nanticommutator ( const T & x , const T & y , int nest = 1 , const bool right = 1 )
{
T z ;
if ( right ) { z = x ; while ( - - nest > = 0 ) z = z * y + y * z ; }
else { z = y ; while ( - - nest > = 0 ) z = x * z + z * x ; }
return z ;
}
//general BCH expansion (can be written more efficiently in a specialization for matrices)
template < class T >
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const T BCHexpansion ( const T & h , const T & t , const int nmax , const bool verbose = 0 , const bool right = 1 )
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{
T result = h ;
double factor = 1. ;
T z = h ;
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for ( int i = 1 ; i < = nmax ; + + i )
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{
factor / = i ;
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if ( right ) z = z * t - t * z ; else z = t * z - z * t ;
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if ( verbose ) std : : cerr < < " BCH contribution at order " < < i < < " : " < < z . norm ( ) * factor < < std : : endl ;
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result + = z * factor ;
}
return result ;
}
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//implementation of nested commutators and BCH expansion applied to a certain ket recursively
//for a class which has only a gemv operation rather than explicit storage of the objects (direct operation like in Davidson)
//exp(-T) H exp(T) |x> = H |x> + [H,T] |x> + 1/2 [[H,T],T] |x> +1/3! [[[H,T],T],T] |x> + ... (for right=1)
//defining C_n^j(x) = [...[H,T],...T]_n T^j |x>
//we precompute C_0^j(x) = H T^j |x> up to j=nmax
//and then recursively C_n^j(x) = C_{n-1}^{j+1}(x) - T C_{n-1}^j(x)
//we overwrite C_{n-1} by C_n in place and free the last one to save memory
//and accumulate the final results on the fly
//for left, C_0^j(x) remains same
//definition is C_n^j(x) = [T,...[T,H]]_n T^j |x>
//and the recursion is C_n^j(x) = T C_{n-1}^j(x) - C_{n-1}^{j+1}(x)
template < typename V , typename M1 , typename M2 >
const V BCHtimes ( const M1 & H , const char transH , const M2 & T , const char transT , const V & x , const int nmax , const bool right = 1 )
{
double factor = 1. ;
NRVec < V > c ( nmax + 1 ) ;
c [ 0 ] = x ;
for ( int j = 1 ; j < = nmax ; + + j )
{
c [ j ] . resize ( x . size ( ) ) ;
T . gemv ( 0 , c [ j ] , transT , 1 , c [ j - 1 ] ) ;
}
for ( int j = 0 ; j < = nmax ; + + j )
{
V tmp ( x . size ( ) ) ;
H . gemv ( 0 , tmp , transH , 1 , c [ j ] ) ;
c [ j ] = tmp ;
}
V result = c [ 0 ] ;
for ( int i = 1 ; i < = nmax ; + + i )
{
//recursive step in the dummy n index of c, overwriting on the fly
for ( int j = 0 ; j < = nmax - i ; + + j )
{
V tmp = c [ j + 1 ] ;
if ( right ) T . gemv ( 1 , tmp , transT , - 1 , c [ j ] ) ;
else T . gemv ( - 1 , tmp , transT , 1 , c [ j ] ) ;
c [ j ] = tmp ;
}
c [ nmax - i + 1 ] . resize ( 0 ) ; //free unnecessary memory
//accumulate the series
factor / = i ;
result + = c [ 0 ] * factor ;
}
return result ;
}
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template < class T >
const T ipow ( const T & x , int i )
{
if ( i < 0 ) laerror ( " negative exponent in ipow " ) ;
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if ( i = = 0 ) { T r = x ; r = ( typename LA_traits < T > : : elementtype ) 1 ; return r ; } //trick for matrix dimension
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if ( i = = 1 ) return x ;
T y , z ;
z = x ;
while ( ! ( i & 1 ) )
{
z = z * z ;
i > > = 1 ;
}
y = z ;
while ( ( i > > = 1 ) /*!=0*/ )
{
z = z * z ;
if ( i & 1 ) y = y * z ;
}
return y ;
}
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inline int mynextpow2 ( const double n )
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{
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const double log2 = std : : log ( 2. ) ;
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if ( n < = .75 ) return 0 ; //try to keep the taylor expansion short
if ( n < = 1. ) return 1 ;
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return int ( std : : ceil ( std : : log ( n ) / log2 - std : : log ( .75 ) ) ) ;
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}
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//should better be computed by mathematica to have accurate last digits, perhaps chebyshev instead, see exp in glibc
//is shared also for sine and cosine now
static const double exptaylor [ ] = {
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1. ,
1. ,
0.5 ,
0.1666666666666666666666 ,
0.0416666666666666666666 ,
0.0083333333333333333333 ,
0.0013888888888888888888 ,
0.00019841269841269841253 ,
2.4801587301587301566e-05 ,
2.7557319223985892511e-06 ,
2.7557319223985888276e-07 ,
2.5052108385441720224e-08 ,
2.0876756987868100187e-09 ,
1.6059043836821613341e-10 ,
1.1470745597729724507e-11 ,
7.6471637318198164055e-13 ,
4.7794773323873852534e-14 ,
2.8114572543455205981e-15 ,
1.5619206968586225271e-16 ,
8.2206352466243294955e-18 ,
4.1103176233121648441e-19 ,
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1.9572941063391262595e-20 ,
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0. } ;
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//S is element type of T, but T may be any user-defined
template < class T , class C , class S >
NRVec < C > exp_aux ( const T & x , int & power , int maxpower , int maxtaylor , S prescale )
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{
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double mnorm = x . norm ( ) * std : : abs ( prescale ) ;
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power = mynextpow2 ( mnorm ) ;
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if ( maxpower > = 0 & & power > maxpower ) power = maxpower ;
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double scale = std : : exp ( - std : : log ( 2. ) * power ) ;
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//find how long taylor expansion will be necessary
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const double precision = 1e-14 ; //further decreasing brings nothing
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double s , t ;
s = mnorm * scale ;
int n = 0 ;
t = 1. ;
do {
n + + ;
t * = s ;
}
while ( t * exptaylor [ n ] > precision ) ; //taylor 0 will terminate in any case
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if ( maxtaylor > = 0 & & n > maxtaylor ) n = maxtaylor ; //useful e.g. if the matrix is nilpotent in order n+1 as the CC T operator for n electrons
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int i ; //adjust the coefficients in order to avoid scaling the argument
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NRVec < C > taylor2 ( n + 1 ) ;
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for ( i = 0 , t = 1. ; i < = n ; i + + )
{
taylor2 [ i ] = exptaylor [ i ] * t ;
t * = scale ;
}
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//std::cout <<"TEST power, scale "<<power<<" "<<scale<<std::endl;
//std::cout <<"TEST taylor2 "<<taylor2<<std::endl;
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return taylor2 ;
}
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template < class T , class C , class S >
void sincos_aux ( NRVec < C > & si , NRVec < C > & co , const T & x , int & power , int maxpower , int maxtaylor , const S prescale )
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{
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double mnorm = x . norm ( ) * std : : abs ( prescale ) ;
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power = mynextpow2 ( mnorm ) ;
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if ( maxpower > = 0 & & power > maxpower ) power = maxpower ;
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double scale = std : : exp ( - std : : log ( 2. ) * power ) ;
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//find how long taylor expansion will be necessary
const double precision = 1e-14 ; //further decreasing brings nothing
double s , t ;
s = mnorm * scale ;
int n = 0 ;
t = 1. ;
do {
n + + ;
t * = s ;
}
while ( t * exptaylor [ n ] > precision ) ; //taylor 0 will terminate in any case
if ( maxtaylor > = 0 & & n > maxtaylor ) n = maxtaylor ; //useful e.g. if the matrix is nilpotent in order n+1 as the CC T operator for n electrons
if ( ( n & 1 ) = = 0 ) + + n ; //force it to be odd to have same length in sine and cosine
si . resize ( ( n + 1 ) / 2 ) ;
co . resize ( ( n + 1 ) / 2 ) ;
int i ; //adjust the coefficients in order to avoid scaling the argument
for ( i = 0 , t = 1. ; i < = n ; i + + )
{
if ( i & 1 ) si [ i > > 1 ] = exptaylor [ i ] * ( i & 2 ? - t : t ) ;
else co [ i > > 1 ] = exptaylor [ i ] * ( i & 2 ? - t : t ) ;
t * = scale ;
}
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//std::cout <<"TEST sin "<<si<<std::endl;
//std::cout <<"TEST cos "<<co<<std::endl;
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}
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//it seems that we do not gain anything by polynom vs polynom0, check the m-optimization!
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template < class T >
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const T exp ( const T & x , bool horner = true , int maxpower = - 1 , int maxtaylor = - 1 )
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{
int power ;
//prepare the polynom of and effectively scale T
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NRVec < typename LA_traits < T > : : normtype > taylor2 = exp_aux < T , typename LA_traits < T > : : normtype , double > ( x , power , maxpower , maxtaylor , 1. ) ;
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//std::cerr <<"TEST power "<<power<<std::endl;
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T r = horner ? polynom0 ( x , taylor2 ) : polynom ( x , taylor2 ) ;
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//for accuracy summing from the smallest terms up would be better, but this is more efficient for matrices
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//power the result back
for ( int i = 0 ; i < power ; i + + ) r = r * r ;
return r ;
}
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//make exp(iH) with real H in real arithmetics
template < class T >
void sincos ( T & s , T & c , const T & x , bool horner = true , int maxpower = - 1 , int maxtaylor = - 1 )
{
int power ;
NRVec < typename LA_traits < T > : : normtype > taylors , taylorc ;
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sincos_aux < T , typename LA_traits < T > : : normtype > ( taylors , taylorc , x , power , maxpower , maxtaylor , 1. ) ;
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//could we save something by computing both polynoms simultaneously?
{
T x2 = x * x ;
s = horner ? polynom0 ( x2 , taylors ) : polynom ( x2 , taylors ) ;
c = horner ? polynom0 ( x2 , taylorc ) : polynom ( x2 , taylorc ) ;
}
s = s * x ;
//power the results back
for ( int i = 0 ; i < power ; i + + )
{
T tmp = c * c - s * s ;
s = s * c ; s * = 2. ;
c = tmp ;
}
}
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//this simple implementation seems not to be numerically stable enough
//and probably not efficient either
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template < class M , class V , class MEL >
void exptimesdestructive ( const M & mat , V & result , V & rhs , bool transpose , const MEL scale , int maxpower = - 1 , int maxtaylor = - 1 , bool mat_is_0 = false ) //uses just matrix vector multiplication
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{
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if ( mat_is_0 ) { result = rhs ; LA_traits < V > : : copyonwrite ( result ) ; return ; } //prevent returning a shallow copy of rhs
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if ( mat . nrows ( ) ! = mat . ncols ( ) | | ( unsigned int ) mat . nrows ( ) ! = ( unsigned int ) rhs . size ( ) ) laerror ( " inappropriate sizes in exptimes " ) ;
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int power ;
//prepare the polynom of and effectively scale the matrix
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NRVec < typename LA_traits < V > : : normtype > taylor2 = exp_aux < M , typename LA_traits < V > : : normtype > ( mat , power , maxpower , maxtaylor , scale ) ;
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V tmp ;
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bool washere = 0 ;
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for ( int i = 1 ; i < = ( 1 < < power ) ; + + i ) //unfortunatelly, here we have to repeat it many times, unlike if the matrix is stored explicitly
{
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washere = 1 ;
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if ( i > 1 ) rhs = result ; //apply again to the result of previous application
else result = rhs ;
tmp = rhs ; //now rhs can be used as scratch
result * = taylor2 [ 0 ] ;
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for ( int j = 1 ; j < taylor2 . size ( ) ; + + j )
{
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mat . gemv ( 0. , rhs , transpose ? ' t ' : ' n ' , scale , tmp ) ;
tmp = rhs ;
result . axpy ( taylor2 [ j ] , tmp ) ;
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}
}
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if ( ! washere ) laerror ( " integer overflow due to unrealistically big power - use maxpower argument in exptimes() " ) ;
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return ;
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}
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//actually scale should be elementtype of M, but we do not have it since M can be anything user-defined
//and template paramter for it does not work due to optional arguments
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//undecent solution: exptimesreal
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//
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template < class M , class V >
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const V exptimes ( const M & mat , V rhs , bool transpose = false , const typename LA_traits < V > : : elementtype scale = 1. , int maxpower = - 1 , int maxtaylor = - 1 , bool mat_is_0 = false )
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{
V result ;
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exptimesdestructive ( mat , result , rhs , transpose , scale , maxpower , maxtaylor , mat_is_0 ) ;
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return result ;
}
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template < class M , class V >
const V exptimesreal ( const M & mat , V rhs , bool transpose = false , const typename LA_traits < V > : : normtype scale = 1. , int maxpower = - 1 , int maxtaylor = - 1 , bool mat_is_0 = false )
{
V result ;
exptimesdestructive ( mat , result , rhs , transpose , scale , maxpower , maxtaylor , mat_is_0 ) ;
return result ;
}
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template < class M , class V , class S >
void sincostimes_simple ( const M & mat , V & si , V & co , const V & rhs , const NRVec < typename LA_traits < V > : : normtype > & taylors , const NRVec < typename LA_traits < V > : : normtype > & taylorc , bool transpose , const S scale )
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{
si = rhs * taylors [ 0 ] ;
co = rhs * taylorc [ 0 ] ;
V tmp = rhs ;
for ( int j = 1 ; j < taylors . size ( ) ; + + j )
{
V tmp2 ( tmp . size ( ) ) ;
//multiply by a square of the matrix
mat . gemv ( 0. , tmp2 , transpose ? ' t ' : ' n ' , scale , tmp ) ;
mat . gemv ( 0. , tmp , transpose ? ' t ' : ' n ' , scale , tmp2 ) ;
si . axpy ( taylors [ j ] , tmp ) ;
co . axpy ( taylorc [ j ] , tmp ) ;
}
mat . gemv ( 0. , tmp , transpose ? ' t ' : ' n ' , scale , si ) ;
si = tmp ;
}
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//this recursion is very inefficient, it is better to use complex exptimes!
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template < class M , class V , class S >
void sincostimes_aux ( const M & mat , V & si , V & co , const V & rhs , const NRVec < typename LA_traits < V > : : normtype > & taylors , const NRVec < typename LA_traits < V > : : normtype > & taylorc , bool transpose , const S scale , int power )
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{
if ( power = = 0 ) sincostimes_simple ( mat , si , co , rhs , taylors , taylorc , transpose , scale ) ;
else
{
V si2 , co2 ; //no large memory allocated yet - size 0
sincostimes_aux ( mat , si2 , co2 , rhs , taylors , taylorc , transpose , scale , power - 1 ) ;
sincostimes_aux ( mat , si , co , co2 , taylors , taylorc , transpose , scale , power - 1 ) ;
V ss , cs ;
sincostimes_aux ( mat , ss , cs , si2 , taylors , taylorc , transpose , scale , power - 1 ) ;
co - = ss ;
si + = cs ;
}
}
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//inefficient, it is better to use complex exptimes!
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//again scale should actually be elementtype of M which is inaccessible
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template < class M , class V >
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void sincostimes ( const M & mat , V & si , V & co , const V & rhs , bool transpose = false , const typename LA_traits < V > : : normtype scale = 1. , int maxpower = - 1 , int maxtaylor = - 1 , bool mat_is_0 = false ) //uses just matrix vector multiplication
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{
if ( mat_is_0 ) //prevent returning a shallow copy of rhs
{
co = rhs ;
LA_traits < V > : : copyonwrite ( co ) ;
LA_traits < V > : : clearme ( si ) ;
return ;
}
if ( mat . nrows ( ) ! = mat . ncols ( ) | | ( unsigned int ) mat . nrows ( ) ! = ( unsigned int ) rhs . size ( ) ) laerror ( " inappropriate sizes in sincostimes " ) ;
//prepare the polynom of and effectively scale the matrix
int power ;
NRVec < typename LA_traits < V > : : normtype > taylors , taylorc ;
sincos_aux < M , typename LA_traits < V > : : normtype > ( taylors , taylorc , mat , power , maxpower , maxtaylor , scale ) ;
if ( taylors . size ( ) ! = taylorc . size ( ) ) laerror ( " internal error - same size of sin and cos expansions assumed " ) ;
//the actual computation and resursive "squaring"
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//std::cout <<"TEST power "<<power<<std::endl;
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sincostimes_aux ( mat , si , co , rhs , taylors , taylorc , transpose , scale , power ) ;
return ;
}
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//@@@ power series matrix logarithm?
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} //namespace
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# endif