zsyconv function
void
zsyconv()
Implementation
void zsyconv(
final String UPLO,
final String WAY,
final int N,
final Matrix<Complex> A_,
final int LDA,
final Array<int> IPIV_,
final Array<Complex> E_,
final Box<int> INFO,
) {
final A = A_.having(ld: LDA);
final E = E_.having();
final IPIV = IPIV_.having();
bool UPPER, CONVERT;
int I, IP, J;
Complex TEMP;
INFO.value = 0;
UPPER = lsame(UPLO, 'U');
CONVERT = lsame(WAY, 'C');
if (!UPPER && !lsame(UPLO, 'L')) {
INFO.value = -1;
} else if (!CONVERT && !lsame(WAY, 'R')) {
INFO.value = -2;
} else if (N < 0) {
INFO.value = -3;
} else if (LDA < max(1, N)) {
INFO.value = -5;
}
if (INFO.value != 0) {
xerbla('ZSYCONV', -INFO.value);
return;
}
// Quick return if possible
if (N == 0) return;
if (UPPER) {
// A is UPPER
if (CONVERT) {
// Convert A (A is upper)
// Convert VALUE
I = N;
E[1] = Complex.zero;
while (I > 1) {
if (IPIV[I] < 0) {
E[I] = A[I - 1][I];
E[I - 1] = Complex.zero;
A[I - 1][I] = Complex.zero;
I--;
} else {
E[I] = Complex.zero;
}
I--;
}
// Convert PERMUTATIONS
I = N;
while (I >= 1) {
if (IPIV[I] > 0) {
IP = IPIV[I];
if (I < N) {
for (J = I + 1; J <= N; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I][J];
A[I][J] = TEMP;
}
}
} else {
IP = -IPIV[I];
if (I < N) {
for (J = I + 1; J <= N; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I - 1][J];
A[I - 1][J] = TEMP;
}
}
I--;
}
I--;
}
} else {
// Revert A (A is upper)
// Revert PERMUTATIONS
I = 1;
while (I <= N) {
if (IPIV[I] > 0) {
IP = IPIV[I];
if (I < N) {
for (J = I + 1; J <= N; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I][J];
A[I][J] = TEMP;
}
}
} else {
IP = -IPIV[I];
I++;
if (I < N) {
for (J = I + 1; J <= N; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I - 1][J];
A[I - 1][J] = TEMP;
}
}
}
I++;
}
// Revert VALUE
I = N;
while (I > 1) {
if (IPIV[I] < 0) {
A[I - 1][I] = E[I];
I--;
}
I--;
}
}
} else {
// A is LOWER
if (CONVERT) {
// Convert A (A is lower)
// Convert VALUE
I = 1;
E[N] = Complex.zero;
while (I <= N) {
if (I < N && IPIV[I] < 0) {
E[I] = A[I + 1][I];
E[I + 1] = Complex.zero;
A[I + 1][I] = Complex.zero;
I++;
} else {
E[I] = Complex.zero;
}
I++;
}
// Convert PERMUTATIONS
I = 1;
while (I <= N) {
if (IPIV[I] > 0) {
IP = IPIV[I];
if (I > 1) {
for (J = 1; J <= I - 1; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I][J];
A[I][J] = TEMP;
}
}
} else {
IP = -IPIV[I];
if (I > 1) {
for (J = 1; J <= I - 1; J++) {
TEMP = A[IP][J];
A[IP][J] = A[I + 1][J];
A[I + 1][J] = TEMP;
}
}
I++;
}
I++;
}
} else {
// Revert A (A is lower)
// Revert PERMUTATIONS
I = N;
while (I >= 1) {
if (IPIV[I] > 0) {
IP = IPIV[I];
if (I > 1) {
for (J = 1; J <= I - 1; J++) {
TEMP = A[I][J];
A[I][J] = A[IP][J];
A[IP][J] = TEMP;
}
}
} else {
IP = -IPIV[I];
I--;
if (I > 1) {
for (J = 1; J <= I - 1; J++) {
TEMP = A[I + 1][J];
A[I + 1][J] = A[IP][J];
A[IP][J] = TEMP;
}
}
}
I--;
}
// Revert VALUE
I = 1;
while (I <= N - 1) {
if (IPIV[I] < 0) {
A[I + 1][I] = E[I];
I++;
}
I++;
}
}
}
}