WGSLIB_DECL bool fft_crossvarmap_3d_declus(
VarOut& Yout,
const std::vector<double>& weigth1,
const std::vector<double>& data1,
const std::vector<int>& has_point1,
const std::vector<double>& data2,
const std::vector<int>& has_point2,
int N, int M, int K)
{
omp_set_num_threads(fft_get_num_threads());
fftw_plan_with_nthreads(fft_get_num_threads());
fftw_complex *i1i2, *I1I2;
fftw_complex *z1i2, *Z1I2;
fftw_complex *i1z2, *I1Z2;
fftw_complex *z1z2, *Z1Z2;
fftw_complex *w, *W;
fftw_complex *wz1, *WZ1;
fftw_complex *wz2, *WZ2;
fftw_complex *wz1z2, *WZ1Z2;
fftw_plan p;
int ZS = (2 * N + 1) * (2 * M + 1) * (2 * K + 1);
fft_lock();
i1i2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I1I2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z1i2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z1I2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
i1z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I1Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z1z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z1Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
w = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
W = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
wz1 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
WZ1 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
wz2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
WZ2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
wz1z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
WZ1Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
fft_unlock();
#pragma omp parallel for
for (int i = 0; i < ZS; ++i) {
i1i2[i][REAL] = i1i2[i][IMAG] = 0;
I1I2[i][REAL] = I1I2[i][IMAG] = 0;
z1i2[i][REAL] = z1i2[i][IMAG] = 0;
Z1I2[i][REAL] = Z1I2[i][IMAG] = 0;
i1z2[i][REAL] = i1z2[i][IMAG] = 0;
I1Z2[i][REAL] = I1Z2[i][IMAG] = 0;
z1z2[i][REAL] = z1z2[i][IMAG] = 0;
Z1Z2[i][REAL] = Z1Z2[i][IMAG] = 0;
w[i][REAL] = w[i][IMAG] = 0;
W[i][REAL] = W[i][IMAG] = 0;
wz1[i][REAL] = wz1[i][IMAG] = 0;
WZ1[i][REAL] = WZ1[i][IMAG] = 0;
wz2[i][REAL] = wz2[i][IMAG] = 0;
WZ2[i][REAL] = WZ2[i][IMAG] = 0;
wz1z2[i][REAL] = wz1z2[i][IMAG] = 0;
WZ1Z2[i][REAL] = WZ1Z2[i][IMAG] = 0;
}
#pragma omp parallel for
for (int i = 0; i < N; ++i) {
for (int j = 0; j < M; ++j) {
for (int k = 0; k < K; ++k) {
double v1 = data1 _p(i, j, k);
double w1_ = weigth1 _p(i, j, k);
int i1 = has_point1 _p(i, j, k);
double v2 = data2 _p(i, j, k);
int i2 = has_point2 _p(i, j, k);
i1i2 _p3(i, j, k)[REAL] = i1 * i2;
z1i2 _p3(i, j, k)[REAL] = v1 * i2;
i1z2 _p3(i, j, k)[REAL] = i1 * v2;
z1z2 _p3(i, j, k)[REAL] = v1 * v2;
w _p3(i, j, k)[REAL] = w1_;
wz1 _p3(i, j, k)[REAL] = w1_ * v1;
wz2 _p3(i, j, k)[REAL] = w1_ * v2;
wz1z2 _p3(i, j, k)[REAL] = w1_ * v1 * v2;
}
}
}
///////////////////////////////////////////////////////////////////
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, i1i2, I1I2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z1i2, Z1I2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, i1z2, I1Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z1z2, Z1Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
////////////////////////////////////////////////////////////////////////////////////
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, w, W, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, wz1, WZ1, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, wz2, WZ2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, wz1z2, WZ1Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int h = 0; h < ZS; ++h) {
fftw_complex W_I1I2;
fftw_complex I1I2_W;
fftw_complex WZ1Z2_I1I2;
fftw_complex I1I2_WZ1Z2;
fftw_complex WZ2_Z1I2;
fftw_complex Z1I2_WZ2;
fftw_complex WZ1_I1Z2;
fftw_complex I1Z2_WZ1;
fftw_complex W_Z1Z2;
fftw_complex Z1Z2_W;
mul_conj(W_I1I2, W[h], I1I2[h]);
mul_conj(I1I2_W, I1I2[h], W[h]);
mul_conj(WZ1Z2_I1I2, WZ1Z2[h], I1I2[h]);
mul_conj(I1I2_WZ1Z2, I1I2[h], WZ1Z2[h]);
mul_conj(WZ2_Z1I2, WZ2[h], Z1I2[h]);
mul_conj(Z1I2_WZ2, Z1I2[h], WZ2[h]);
mul_conj(WZ1_I1Z2, WZ1[h], I1Z2[h]);
mul_conj(I1Z2_WZ1, I1Z2[h], WZ1[h]);
mul_conj(W_Z1Z2, W[h], Z1Z2[h]);
mul_conj(Z1Z2_W, Z1Z2[h], W[h]);
Z1Z2[h][REAL] =
WZ1Z2_I1I2[REAL] -
WZ2_Z1I2[REAL] -
WZ1_I1Z2[REAL] +
W_Z1Z2[REAL] +
Z1Z2_W[REAL] -
I1Z2_WZ1[REAL] -
Z1I2_WZ2[REAL] +
I1I2_WZ1Z2[REAL];
Z1Z2[h][IMAG] =
WZ1Z2_I1I2[IMAG] -
WZ2_Z1I2[IMAG] -
WZ1_I1Z2[IMAG] +
W_Z1Z2[IMAG] +
Z1Z2_W[IMAG] -
I1Z2_WZ1[IMAG] -
Z1I2_WZ2[IMAG] +
I1I2_WZ1Z2[IMAG];
W[h][REAL] = 2 * (W_I1I2[REAL] + I1I2_W[REAL]);
W[h][IMAG] = 2 * (W_I1I2[IMAG] + I1I2_W[IMAG]);
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, Z1Z2, z1z2, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, W, w, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int hx = 0; hx < N; ++hx) {
for (int hy = 0; hy < M; ++hy) {
for (int hz = 0; hz < K; ++hz) {
double Y = z1z2 _p3(hx, hy, hz)[REAL] / ZS;
double N = w _p3(hx, hy, hz)[REAL] / ZS;
if (N > 0.01) {
Yout.varmap _p(hx, hy, hz) = Y / (N);
}
else {
Yout.varmap _p(hx, hy, hz) = 0;
}
Yout.ni _p(hx, hy, hz) = N;
}
}
}
fft_lock();
fftw_destroy_plan(p);
fftw_free(i1i2);
fftw_free(I1I2);
fftw_free(z1i2);
fftw_free(Z1I2);
fftw_free(i1z2);
fftw_free(I1Z2);
fftw_free(z1z2);
fftw_free(Z1Z2);
fftw_free(w);
fftw_free(W);
fftw_free(wz1);
fftw_free(WZ1);
fftw_free(wz2);
fftw_free(WZ2);
fftw_free(wz1z2);
fftw_free(WZ1Z2);
fft_unlock();
return true;
}
WGSLIB_DECL bool fft_varmap_3d(
VarOut& Yout,
const std::vector<double>& data,
const std::vector<int>& has_point,
int N, int M, int K)
{
omp_set_num_threads(fft_get_num_threads());
fftw_plan_with_nthreads(fft_get_num_threads());
fftw_complex *z, *Z, *ZI;
fftw_complex *z2, *Z2;
fftw_complex *ni, *NI, *INI;
fftw_plan p;
int ZS = (2 * N + 1) * (2 * M + 1) * (2 * K + 1);
fft_lock();
z = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
ZI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
ni = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
NI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
INI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
fft_unlock();
#pragma omp parallel for
for (int i = 0; i < ZS; ++i) {
z[i][REAL] = z[i][IMAG] = 0;
z2[i][REAL] = z2[i][IMAG] = 0;
ni[i][REAL] = ni[i][IMAG] = 0;
}
#pragma omp parallel for
for (int i = 0; i < N; ++i) {
for (int j = 0; j < M; ++j) {
for (int k = 0; k < K; ++k) {
double v = data _p(i, j, k);
int hp = has_point _p(i, j, k);
ni _p3(i, j, k)[REAL] = hp;
if (hp) {
z _p3(i, j, k)[REAL] = v;
z2 _p3(i, j, k)[REAL] = v * v;
}
}
}
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z, Z, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z2, Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, ni, NI, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int h = 0; h < ZS; ++h) {
fftw_complex Z2_I;
fftw_complex Z_Z;
fftw_complex I_Z2;
fftw_complex I_I;
mul_conj(Z2_I, Z2[h], NI[h]);
mul_conj(Z_Z, Z[h], Z[h]);
mul_conj(I_Z2, NI[h], Z2[h]);
mul_conj(I_I, NI[h], NI[h]);
Z[h][REAL] = Z2_I[REAL] - 2 * Z_Z[REAL] + I_Z2[REAL];
Z[h][IMAG] = Z2_I[IMAG] - 2 * Z_Z[IMAG] + I_Z2[IMAG];
NI[h][REAL] = I_I[REAL];
NI[h][IMAG] = I_I[IMAG];
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, Z, ZI, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, NI, INI, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int hx = 0; hx < N; ++hx) {
for (int hy = 0; hy < M; ++hy) {
for (int hz = 0; hz < K; ++hz) {
double Y = ZI _p3(hx, hy, hz)[REAL] / ZS;
double N = INI _p3(hx, hy, hz)[REAL] / ZS;
if (N > 0.01) {
Yout.varmap _p(hx, hy, hz) = Y / (2 * N);
} else {
Yout.varmap _p(hx, hy, hz) = 0;
}
Yout.ni _p(hx, hy, hz) = N;
}
}
}
fft_lock();
fftw_destroy_plan(p);
fftw_free(z);
fftw_free(Z);
fftw_free(ZI);
fftw_free(z2);
fftw_free(Z2);
fftw_free(ni);
fftw_free(NI);
fftw_free(INI);
fft_unlock();
return true;
}
WGSLIB_DECL bool fft_crossvarmap_3d(
VarOut& Yout,
const std::vector<double>& data1,
const std::vector<int>& has_point1,
const std::vector<double>& data2,
const std::vector<int>& has_point2,
int N, int M, int K)
{
omp_set_num_threads(fft_get_num_threads());
fftw_plan_with_nthreads(fft_get_num_threads());
fftw_complex *Z1I;
fftw_complex *I1I;
fftw_complex *z1z2, *Z1Z2;
fftw_complex *i2z1, *I2Z1;
fftw_complex *i1z2, *I1Z2;
fftw_complex *i1i2, *I1I2;
fftw_plan p;
int ZS = (2 * N + 1) * (2 * M + 1) * (2 * K + 1);
fft_lock();
Z1I = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I1I = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z1z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z1Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
i2z1 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I2Z1 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
i1z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I1Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
i1i2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
I1I2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
fft_unlock();
#pragma omp parallel for
for (int i = 0; i < ZS; ++i) {
z1z2[i][REAL] = z1z2[i][IMAG] = 0;
i1z2[i][REAL] = i1z2[i][IMAG] = 0;
i2z1[i][REAL] = i2z1[i][IMAG] = 0;
i1i2[i][REAL] = i1i2[i][IMAG] = 0;
}
#pragma omp parallel for
for (int i = 0; i < N; ++i) {
for (int j = 0; j < M; ++j) {
for (int k = 0; k < K; ++k) {
double v1 = data1 _p(i, j, k);
double v2 = data2 _p(i, j, k);
int hp1 = has_point1 _p(i, j, k);
int hp2 = has_point2 _p(i, j, k);
z1z2 _p3(i, j, k)[REAL] = v1 * v2;
i1z2 _p3(i, j, k)[REAL] = hp1 * v2;
i2z1 _p3(i, j, k)[REAL] = hp2 * v1;
i1i2 _p3(i, j, k)[REAL] = hp1 * hp2;
}
}
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z1z2, Z1Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, i1z2, I1Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, i2z1, I2Z1, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, i1i2, I1I2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int h = 0; h < ZS; ++h) {
fftw_complex A;
fftw_complex B;
fftw_complex C;
fftw_complex D;
fftw_complex I1_I2;
mul_conj(A, Z1Z2[h], I1I2[h]);
mul_conj(D, I1I2[h], Z1Z2[h]);
mul_conj(B, I2Z1[h], I1Z2[h]);
mul_conj(C, I1Z2[h], I2Z1[h]);
mul_conj(I1_I2, I1I2[h], I1I2[h]);
Z1Z2[h][REAL] = A[REAL] - B[REAL] - C[REAL] + D[REAL];
Z1Z2[h][IMAG] = A[IMAG] - B[IMAG] - C[IMAG] + D[IMAG];
I1I2[h][REAL] = I1_I2[REAL];
I1I2[h][IMAG] = I1_I2[IMAG];
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, Z1Z2, Z1I, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, I1I2, I1I, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int hx = 0; hx < N; ++hx) {
for (int hy = 0; hy < M; ++hy) {
for (int hz = 0; hz < K; ++hz) {
double Y = Z1I _p3(hx, hy, hz)[REAL] / ZS;
double N = I1I _p3(hx, hy, hz)[REAL] / ZS;
if (N > 0.01) {
Yout.varmap _p(hx, hy, hz) = Y / (2 * N);
} else {
Yout.varmap _p(hx, hy, hz) = 0;
}
Yout.ni _p(hx, hy, hz) = N;
}
}
}
fft_lock();
fftw_destroy_plan(p);
fftw_free(Z1I);
fftw_free(I1I);
fftw_free(z1z2);
fftw_free(Z1Z2);
fftw_free(i2z1);
fftw_free(I2Z1);
fftw_free(i1z2);
fftw_free(I1Z2);
fftw_free(i1i2);
fftw_free(I1I2);
fft_unlock();
return true;
}
WGSLIB_DECL bool fft_varmap_3d_declus(
VarOut& Yout,
const std::vector<double>& data,
const std::vector<double>& weigth,
const std::vector<int>& has_point,
int N, int M, int K)
{
omp_set_num_threads(fft_get_num_threads());
fftw_plan_with_nthreads(fft_get_num_threads());
fftw_complex *z, *Z, *ZI;
fftw_complex *z2, *Z2;
fftw_complex *ni, *NI, *INI;
fftw_complex *w, *W;
fftw_complex *z2w, *Z2W;
fftw_complex *zw, *ZW;
fftw_plan p;
int ZS = (2 * N + 1) * (2 * M + 1) * (2 * K + 1);
fft_lock();
z = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
ZI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z2 = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
ni = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
NI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
INI = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
w = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
W = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
z2w = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
Z2W = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
zw = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
ZW = (fftw_complex*)fftw_malloc(sizeof(fftw_complex)* ZS);
fft_unlock();
#pragma omp parallel for
for (int i = 0; i < ZS; ++i) {
z[i][REAL] = z[i][IMAG] = 0;
z2[i][REAL] = z2[i][IMAG] = 0;
ni[i][REAL] = ni[i][IMAG] = 0;
w[i][REAL] = w[i][IMAG] = 0;
z2w[i][REAL] = z2w[i][IMAG] = 0;
zw[i][REAL] = zw[i][IMAG] = 0;
}
#pragma omp parallel for
for (int i = 0; i < N; ++i) {
for (int j = 0; j < M; ++j) {
for (int k = 0; k < K; ++k) {
double v = data _p(i, j, k);
double w_ = weigth _p(i, j, k);
int hp = has_point _p(i, j, k);
ni _p3(i, j, k)[REAL] = hp;
if (hp) {
z _p3(i, j, k)[REAL] = v;
z2 _p3(i, j, k)[REAL] = v * v;
zw _p3(i, j, k)[REAL] = v * w_;
z2w _p3(i, j, k)[REAL] = v * v * w_;
w _p3(i, j, k)[REAL] = w_;
}
}
}
}
//LEVA z para o dominio da frequencia
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z, Z, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, w, W, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, zw, ZW, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z2w, Z2W, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, z2, Z2, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, ni, NI, FFTW_FORWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
//Realiza convolução
#pragma omp parallel for
for (int h = 0; h < ZS; ++h) {
fftw_complex Z2W_I;
fftw_complex ZW_Z;
fftw_complex W_Z2;
fftw_complex Z2_W;
fftw_complex Z_ZW;
fftw_complex I_Z2W;
fftw_complex W_I;
fftw_complex I_W;
mul_conj(Z2W_I, Z2W[h], NI[h]);
mul_conj(ZW_Z, ZW[h], Z[h]);
mul_conj(W_Z2, W[h], Z2[h]);
mul_conj(Z2_W, Z2[h], W[h]);
mul_conj(Z_ZW, Z[h], ZW[h]);
mul_conj(I_Z2W, NI[h], Z2W[h]);
mul_conj(I_W, NI[h], W[h]);
mul_conj(W_I, W[h], NI[h]);
Z[h][REAL] = Z2W_I[REAL] - 2 * ZW_Z[REAL] + W_Z2[REAL] +
Z2_W[REAL] - 2 * Z_ZW[REAL] + I_Z2W[REAL];
Z[h][IMAG] = Z2W_I[IMAG] - 2 * ZW_Z[IMAG] + W_Z2[IMAG] +
Z2_W[IMAG] - 2 * Z_ZW[IMAG] + I_Z2W[IMAG];
NI[h][REAL] = 2 * (W_I[REAL] + I_W[REAL]);
NI[h][IMAG] = 2 * (W_I[IMAG] + I_W[IMAG]);
}
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, Z, ZI, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
fft_lock();
p = fftw_plan_dft_3d(2 * N + 1, 2 * M + 1, 2 * K + 1, NI, INI, FFTW_BACKWARD, FFTW_ESTIMATE);
fft_unlock();
fftw_execute(p);
#pragma omp parallel for
for (int hx = 0; hx < N; ++hx) {
for (int hy = 0; hy < M; ++hy) {
for (int hz = 0; hz < K; ++hz) {
double Y = ZI _p3(hx, hy, hz)[REAL] / ZS;
double N = INI _p3(hx, hy, hz)[REAL] / ZS;
if (N > 0.01) {
Yout.varmap _p(hx, hy, hz) = Y / N;
}
else {
Yout.varmap _p(hx, hy, hz) = 0;
}
Yout.ni _p(hx, hy, hz) = N;
}
}
}
fft_lock();
fftw_destroy_plan(p);
fftw_free(z);
fftw_free(Z);
fftw_free(ZI);
fftw_free(z2);
fftw_free(Z2);
fftw_free(zw);
fftw_free(ZW);
fftw_free(z2w);
fftw_free(Z2W);
fftw_free(w);
fftw_free(W);
fftw_free(ni);
fftw_free(NI);
fftw_free(INI);
fft_unlock();
return true;
}
void drive_operation()
{
// Uint64 tests
CQLValue a1(Uint64(10));
CQLValue a2(Uint64(15));
CQLValue a3(Uint64(25));
CQLValue a4(Uint64(30));
CQLValue a5(Uint64(150));
PEGASUS_TEST_ASSERT(a1 != a2);
PEGASUS_TEST_ASSERT(a5 == a5);
PEGASUS_TEST_ASSERT(a1 < a2);
PEGASUS_TEST_ASSERT(a2 >= a1);
PEGASUS_TEST_ASSERT(a1 <= a2);
PEGASUS_TEST_ASSERT(a2 > a1);
// Sint64 tests
CQLValue b1(Sint64(10));
CQLValue b2(Sint64(15));
CQLValue b3(Sint64(25));
CQLValue b4(Sint64(30));
CQLValue b5(Sint64(150));
PEGASUS_TEST_ASSERT(b1 != b2);
PEGASUS_TEST_ASSERT(b5 == b5);
PEGASUS_TEST_ASSERT(b1 < b2);
PEGASUS_TEST_ASSERT(b2 >= b1);
PEGASUS_TEST_ASSERT(b1 <= b2);
PEGASUS_TEST_ASSERT(b2 > b1);
// Real64 tests
CQLValue c1(Real64(10.00));
CQLValue c2(Real64(15.00));
CQLValue c3(Real64(25.00));
CQLValue c4(Real64(30.00));
CQLValue c5(Real64(150.00));
PEGASUS_TEST_ASSERT(c1 != c2);
PEGASUS_TEST_ASSERT(c5 == c5);
PEGASUS_TEST_ASSERT(c1 < c2);
PEGASUS_TEST_ASSERT(c2 >= c1);
PEGASUS_TEST_ASSERT(c1 <= c2);
PEGASUS_TEST_ASSERT(c2 > c1);
// Misc
PEGASUS_TEST_ASSERT(a1 == b1);
PEGASUS_TEST_ASSERT(a1 == c1);
PEGASUS_TEST_ASSERT(b1 == a1);
PEGASUS_TEST_ASSERT(b1 == c1);
PEGASUS_TEST_ASSERT(c1 == a1);
PEGASUS_TEST_ASSERT(c1 == b1);
PEGASUS_TEST_ASSERT(a2 != b1);
PEGASUS_TEST_ASSERT(a2 != c1);
PEGASUS_TEST_ASSERT(b2 != a1);
PEGASUS_TEST_ASSERT(b2 != c1);
PEGASUS_TEST_ASSERT(c2 != a1);
PEGASUS_TEST_ASSERT(c2 != b1);
PEGASUS_TEST_ASSERT(a2 >= b1);
PEGASUS_TEST_ASSERT(a2 >= c1);
PEGASUS_TEST_ASSERT(b2 >= a1);
PEGASUS_TEST_ASSERT(b2 >= c1);
PEGASUS_TEST_ASSERT(c2 >= a1);
PEGASUS_TEST_ASSERT(c2 >= b1);
PEGASUS_TEST_ASSERT(a2 <= b3);
PEGASUS_TEST_ASSERT(a2 <= c3);
PEGASUS_TEST_ASSERT(b2 <= a3);
PEGASUS_TEST_ASSERT(b2 <= c3);
PEGASUS_TEST_ASSERT(c2 <= a3);
PEGASUS_TEST_ASSERT(c2 <= b3);
PEGASUS_TEST_ASSERT(a2 > b1);
PEGASUS_TEST_ASSERT(a2 > c1);
PEGASUS_TEST_ASSERT(b2 > a1);
PEGASUS_TEST_ASSERT(b2 > c1);
PEGASUS_TEST_ASSERT(c2 > a1);
PEGASUS_TEST_ASSERT(c2 > b1);
PEGASUS_TEST_ASSERT(a2 < b3);
PEGASUS_TEST_ASSERT(a2 < c3);
PEGASUS_TEST_ASSERT(b2 < a3);
PEGASUS_TEST_ASSERT(b2 < c3);
PEGASUS_TEST_ASSERT(c2 < a3);
PEGASUS_TEST_ASSERT(c2 < b3);
//Overflow testing
CQLValue real1(Real64(0.00000001));
CQLValue sint1(Sint64(-1));
CQLValue uint1(Sint64(1));
CQLValue uint2(Uint64(0));
PEGASUS_TEST_ASSERT(uint1 > sint1);
PEGASUS_TEST_ASSERT(real1 > sint1);
PEGASUS_TEST_ASSERT(uint2 > sint1);
PEGASUS_TEST_ASSERT(real1 > uint2);
CQLValue real2(Real64(25.00000000000001));
CQLValue real3(Real64(24.99999999999999));
CQLValue sint2(Sint64(25));
CQLValue uint3(Uint64(25));
PEGASUS_TEST_ASSERT(real2 > real3);
PEGASUS_TEST_ASSERT(real2 > sint2);
PEGASUS_TEST_ASSERT(real2 > uint3);
PEGASUS_TEST_ASSERT(real3 < sint2);
PEGASUS_TEST_ASSERT(real3 < uint3);
// String tests
CQLValue d1(String("HELLO"));
CQLValue d2(String("HEL"));
CQLValue d3(String("LO"));
CQLValue d4(String("AHELLO"));
CQLValue d5(String("ZHELLO"));
PEGASUS_TEST_ASSERT(d1 == d2 + d3);
PEGASUS_TEST_ASSERT(d1 != d2 + d4);
PEGASUS_TEST_ASSERT(d1 <= d5);
PEGASUS_TEST_ASSERT(d1 < d5);
PEGASUS_TEST_ASSERT(d1 >= d4);
PEGASUS_TEST_ASSERT(d1 > d4);
String str1("0x10");
String str2("10");
String str3("10B");
String str4("10.10");
CQLValue e1( str1, CQLValue::Hex);
CQLValue e2( str2, CQLValue::Decimal);
CQLValue e3( str3, CQLValue::Binary);
CQLValue e4( str4, CQLValue::Real);
CQLValue e5(Uint64(16));
CQLValue e6(Uint64(10));
CQLValue e7(Uint64(2));
CQLValue e8(Real64(10.10));
PEGASUS_TEST_ASSERT(e1 == e5);
PEGASUS_TEST_ASSERT(e2 == e6);
PEGASUS_TEST_ASSERT(e3 == e7);
PEGASUS_TEST_ASSERT(e4 == e8);
Array<Uint64> array1;
array1.append(1);
array1.append(2);
array1.append(3);
array1.append(4);
array1.append(5);
array1.append(6);
array1.append(7);
array1.append(8);
array1.append(9);
array1.append(10);
Array<Sint64> array2;
array2.append(1);
array2.append(2);
array2.append(3);
array2.append(4);
array2.append(5);
array2.append(6);
array2.append(7);
array2.append(8);
array2.append(9);
array2.append(10);
array2.append(3);
Array<Real64> array3;
array3.append(1.00);
array3.append(2.00);
array3.append(3.00);
array3.append(9.00);
array3.append(10.00);
array3.append(3.00);
array3.append(4.00);
array3.append(5.00);
array3.append(6.00);
array3.append(7.00);
array3.append(8.00);
Array<Uint64> array4;
array4.append(1);
array4.append(23);
array4.append(3);
array4.append(4);
array4.append(5);
array4.append(6);
array4.append(7);
array4.append(88);
array4.append(9);
array4.append(10);
Array<Sint64> array5;
array5.append(-1);
array5.append(2);
array5.append(3);
array5.append(4);
array5.append(5);
array5.append(-6);
array5.append(7);
array5.append(8);
array5.append(9);
array5.append(10);
array5.append(-3);
Array<Real64> array6;
array6.append(1.23);
array6.append(2.00);
array6.append(3.00);
array6.append(9.00);
array6.append(10.00);
array6.append(3.00);
array6.append(4.14);
array6.append(5.00);
array6.append(6.00);
array6.append(7.00);
array6.append(8.00);
CIMValue cv1(array1);
CIMValue cv2(array2);
CIMValue cv3(array3);
CIMValue cv4(array4);
CIMValue cv5(array5);
CIMValue cv6(array6);
CQLValue vr1(cv1);
CQLValue vr2(cv1);
CQLValue vr3(cv2);
CQLValue vr4(cv3);
CQLValue vr5(cv4);
CQLValue vr6(cv5);
CQLValue vr7(cv6);
PEGASUS_TEST_ASSERT(vr1 == vr2);
PEGASUS_TEST_ASSERT(vr1 == vr3);
PEGASUS_TEST_ASSERT(vr1 == vr4);
PEGASUS_TEST_ASSERT(vr4 == vr3);
PEGASUS_TEST_ASSERT(vr1 != vr5);
PEGASUS_TEST_ASSERT(vr3 != vr6);
PEGASUS_TEST_ASSERT(vr4 != vr7);
const CIMName _cimName(String("CIM_OperatingSystem"));
CIMInstance _i1(_cimName);
CIMProperty _p1(CIMName("Description"),CIMValue(String("Dave Rules")));
CIMProperty _p2(CIMName("EnabledState"),CIMValue(Uint16(2)));
CIMProperty _p3(CIMName("CurrentTimeZone"),CIMValue(Sint16(-600)));
CIMProperty _p4(CIMName("TimeOfLastStateChange"),
CIMValue(CIMDateTime(String("20040811105625.000000-360"))));
_i1.addProperty(_p1);
_i1.addProperty(_p2);
_i1.addProperty(_p3);
_i1.addProperty(_p4);
CIMInstance _i2(_cimName);
CIMProperty _p5(CIMName("Description"),
CIMValue(String("Dave Rules Everything")));
CIMProperty _p6(CIMName("EnabledState"),CIMValue(Uint16(2)));
CIMProperty _p7(CIMName("CurrentTimeZone"),CIMValue(Sint16(-600)));
CIMProperty _p8(CIMName("TimeOfLastStateChange"),
CIMValue(CIMDateTime(String("20040811105625.000000-360"))));
_i2.addProperty(_p5);
_i2.addProperty(_p6);
_i2.addProperty(_p7);
_i2.addProperty(_p8);
CQLValue cql1(_i1);
CQLValue cql2(_i1);
CQLValue cql3(_i2);
CQLValue cql4(_i2);
//PEGASUS_TEST_ASSERT(cql1 == cql1);
return;
}
void drive_resolve_specialChars()
{
const char* env = getenv("PEGASUS_HOME");
String repositoryDir(env);
repositoryDir.append("/repository");
//String repositoryDir("c:/pegasus-cvs/pegasus/repository");
CIMNamespaceName _ns("root/cimv2");
CIMRepository *_rep = new CIMRepository(repositoryDir);
RepositoryQueryContext _query(_ns, _rep);
RepositoryQueryContext _query1(_ns, _rep);
try {
const CQLIdentifier _Id1(String("CIM_OperatingSystem"));
_query.insertClassPath(_Id1);
const CIMName _cimName(String("CIM_OperatingSystem"));
CIMInstance _i1(_cimName);
CIMProperty _p1(CIMName("OSType"),CIMValue(Uint16(11)));
CIMProperty _p2(CIMName("Status"),CIMValue(String("Degraded")));
Array<Uint16> array16;
array16.append(Uint16(0));
array16.append(Uint16(1));
array16.append(Uint16(2));
array16.append(Uint16(3));
CIMProperty _p3(CIMName("OperationalStatus"),CIMValue(array16));
_i1.addProperty(_p1);
_i1.addProperty(_p2);
_i1.addProperty(_p3);
CQLChainedIdentifier ci1(String("CIM_OperatingSystem.OSType#OS400"));
CQLChainedIdentifier ci2(String("CIM_OperatingSystem.OSType#LINUX"));
CQLChainedIdentifier ci3(String("CIM_OperatingSystem.Status#Degraded"));
CQLChainedIdentifier ci5(String("CIM_OperatingSystem.Status#BOGUS"));
CQLChainedIdentifier ci6(
String("CIM_OperatingSystem.CIM_OperatingSystem::"
"OperationalStatus[2]"));
CQLValue a1(ci1);
CQLValue a2(ci2);
CQLValue a3(ci3);
CQLValue a5(ci5);
CQLValue a6(ci6);
a1.resolve(_i1, _query);
a2.resolve(_i1, _query);
a6.resolve(_i1, _query);
try
{
a3.resolve(_i1, _query);
PEGASUS_TEST_ASSERT(0);
}
catch(...)
{
PEGASUS_TEST_ASSERT(1);
}
try
{
a5.resolve(_i1, _query);
PEGASUS_TEST_ASSERT(0);
}
catch(...)
{
PEGASUS_TEST_ASSERT(1);
}
PEGASUS_TEST_ASSERT(a1 == CQLValue(Uint64(11)));
PEGASUS_TEST_ASSERT(a2 == CQLValue(Uint64(36)));
PEGASUS_TEST_ASSERT(a6 == CQLValue(Uint64(2)));
}
catch(Exception & e)
{
cout << e.getMessage() << endl;
PEGASUS_TEST_ASSERT(0);
}
delete _rep;
return;
}
void drive_resolve_primitive()
{
const char* env = getenv("PEGASUS_HOME");
String repositoryDir(env);
repositoryDir.append("/repository");
//String repositoryDir("c:/pegasus-cvs/pegasus/repository");
CIMNamespaceName _ns("root/cimv2");
CIMRepository *_rep = new CIMRepository(repositoryDir);
RepositoryQueryContext _query(_ns, _rep);
RepositoryQueryContext _query1(_ns, _rep);
try {
const CQLIdentifier _Id1(String("CIM_OperatingSystem"));
_query.insertClassPath(_Id1);
const CIMName _cimName(String("CIM_OperatingSystem"));
CIMInstance _i1(_cimName);
CIMProperty _p1(CIMName("Description"),CIMValue(String("Dave Rules")));
CIMProperty _p2(CIMName("EnabledState"),CIMValue(Uint16(2)));
CIMProperty _p3(CIMName("CurrentTimeZone"),CIMValue(Sint16(-600)));
CIMProperty _p4(CIMName("TimeOfLastStateChange"),
CIMValue(CIMDateTime(String("20040811105625.000000-360"))));
_i1.addProperty(_p1);
_i1.addProperty(_p2);
_i1.addProperty(_p3);
_i1.addProperty(_p4);
CQLChainedIdentifier ci1(
String("CIM_OperatingSystem.CIM_OperatingSystem::Description"));
CQLChainedIdentifier
ci2(String("CIM_OperatingSystem.CIM_OperatingSystem::EnabledState"));
CQLChainedIdentifier ci3(
String("CIM_OperatingSystem.CIM_OperatingSystem::CurrentTimeZone"));
CQLChainedIdentifier ci4(
String("CIM_OperatingSystem.CIM_OperatingSystem::TimeOfLastStateChange"));
CQLChainedIdentifier
ci5(String(
"CIM_OperatingSystem.CIM_EnabledLogicalElement::TimeOfLastStateChange"));
CQLChainedIdentifier
ci7(String("CIM_OperatingSystem"));
CQLChainedIdentifier
ci9(String(
"CIM_EnabledLogicalElement.CIM_OperatingSystem::CSCreationClassName"));
CQLChainedIdentifier
ci10(String("CIM_OperatingSystem.CIM_OperatingSystem::Bubba"));
CQLValue a1(ci1);
CQLValue a2(ci2);
CQLValue a3(ci3);
CQLValue a4(ci4);
CQLValue a5(ci5);
CQLValue a7(ci7);
CQLValue a9(ci9);
CQLValue a10(ci10);
CQLValue a11(_query.getClass(CIMName("CIM_OperatingSystem")));
a1.resolve(_i1, _query);
a2.resolve(_i1, _query);
a3.resolve(_i1, _query);
a4.resolve(_i1, _query);
a5.resolve(_i1, _query);
a7.resolve(_i1, _query);
a10.resolve(_i1, _query1);
a9.resolve(_i1, _query);
PEGASUS_TEST_ASSERT(a1 == CQLValue(String("Dave Rules")));
PEGASUS_TEST_ASSERT(a2 == CQLValue(Uint64(2)));
PEGASUS_TEST_ASSERT(a3 == CQLValue(Sint64(-600)));
PEGASUS_TEST_ASSERT(a4 == CQLValue(
CIMDateTime(String("20040811105625.000000-360"))));
PEGASUS_TEST_ASSERT(a5 == CQLValue(
CIMDateTime(String("20040811105625.000000-360"))));
//PEGASUS_TEST_ASSERT(a7 == CQLValue(_i1));
PEGASUS_TEST_ASSERT(a9.isNull());
PEGASUS_TEST_ASSERT(a10.isNull());
}
catch(Exception & e)
{
cout << e.getMessage() << endl;
PEGASUS_TEST_ASSERT(0);
}
delete _rep;
return;
}
