6 if(matA.
n!=matB.
n || matA.
m!=matB.
m){
8 std::cerr <<
"These two matrises can not make a summation." << std::endl
9 <<
"Your input was (" << matA.
m <<
"x" << matA.
n <<
") + (" << matB.
m <<
"x" << matB.
n <<
")." << std::endl;
14 for(CPPL_INT
i=0;
i<matB.
m;
i++){
15 const CPPL_INT jmax =std::min(matB.
n,
i+matB.
ku+1);
16 for(CPPL_INT j=std::max(CPPL_INT(0),
i-matB.
kl); j<jmax; j++){
17 matA(
i,j) += matB(
i,j);
29 if(matA.
n!=matB.
n || matA.
m!=matB.
m){
31 std::cerr <<
"These two matrises can not make a summation." << std::endl
32 <<
"Your input was (" << matA.
m <<
"x" << matA.
n <<
") + (" << matB.
m <<
"x" << matB.
n <<
")." << std::endl;
37 for(CPPL_INT
i=0;
i<matB.
m;
i++){
38 const CPPL_INT jmax =std::min(matB.
n,
i+matB.
ku+1);
39 for(CPPL_INT j=std::max(CPPL_INT(0),
i-matB.
kl); j<jmax; j++){
40 matA(
i,j) -= matB(
i,j);
54 std::cerr <<
"These two matrises can not make a product." << std::endl
55 <<
"Your input was (" << matA.
m <<
"x" << matA.
n <<
") * (" << matB.
m <<
"x" << matB.
n <<
")." << std::endl;
63 for(CPPL_INT
i=0;
i<newmat.
m;
i++){
64 for(CPPL_INT j=0; j<newmat.
n; j++){
65 const CPPL_INT kmax =std::min(matB.
m,j+matB.
kl+1);
66 for(CPPL_INT k=std::max(CPPL_INT(0),j-matB.
ku); k<kmax; k++){
67 newmat(
i,j) += matA(
i,k)*matB(k,j);
CPPL_INT m
matrix row size
_dgematrix i(const _dgbmatrix &mat)
CPPL_INT n
matrix column size
CPPL_INT ku
upper band width
CPPL_INT n
matrix column size
Complex Double-precision General Dence Matrix Class.
(DO NOT USE) Smart-temporary Complex Double-precision General Dence Matrix Class
_zgematrix operator-(const _zgematrix &matA, const zgbmatrix &matB)
CPPL_INT m
matrix row size
Complex Double-precision General Band Matrix Class.
_zgematrix operator+(const _zgematrix &matA, const zgbmatrix &matB)
CPPL_INT m
matrix row size
CPPL_INT kl
lower band width
_zgematrix operator*(const _zgematrix &matA, const zgbmatrix &matB)
_dcovector _(dcovector &vec)
CPPL_INT n
matrix column size
1.8.6
