Flush the stderr output immediately.
Former-commit-id: 240c09daf17f4707564e853164342940d372982e
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1ceaad21bb
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28a805b638
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@ -1044,6 +1044,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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if (watch_time):
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if (watch_time):
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timec = time.time()
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timec = time.time()
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print('%.4f: running scatter_plane_wave_rectarray' % timec, file = sys.stderr)
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print('%.4f: running scatter_plane_wave_rectarray' % timec, file = sys.stderr)
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sys.stderr.flush()
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nelem = TMatrices.shape[-1]
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nelem = TMatrices.shape[-1]
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if ((nelem != TMatrices.shape[-3]) or (2 != TMatrices.shape[-2]) or (2 != TMatrices.shape[-4])):
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if ((nelem != TMatrices.shape[-3]) or (2 != TMatrices.shape[-2]) or (2 != TMatrices.shape[-4])):
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raise ValueError('The T-matrices must be of shape (N, 2, nelem, 2, nelem) but are of shape %s' % (str(TMatrices.shape),))
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raise ValueError('The T-matrices must be of shape (N, 2, nelem, 2, nelem) but are of shape %s' % (str(TMatrices.shape),))
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@ -1072,6 +1073,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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if (watch_time):
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if (watch_time):
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timec = time.time()
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timec = time.time()
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print('%.4f: calculating the %d translation matrix elements' % (timec, 8*nelem*nelem*xN*yN), file = sys.stderr)
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print('%.4f: calculating the %d translation matrix elements' % (timec, 8*nelem*nelem*xN*yN), file = sys.stderr)
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sys.stderr.flush()
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Agrid = np.zeros((nelem, 2*xN, 2*yN, nelem),dtype=np.complex_)
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Agrid = np.zeros((nelem, 2*xN, 2*yN, nelem),dtype=np.complex_)
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Bgrid = np.zeros((nelem, 2*xN, 2*yN, nelem),dtype=np.complex_)
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Bgrid = np.zeros((nelem, 2*xN, 2*yN, nelem),dtype=np.complex_)
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for yl in range(nelem): # source
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for yl in range(nelem): # source
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@ -1089,6 +1091,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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timec = time.time()
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timec = time.time()
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print('%4f: translation matrix elements calculated (elapsed %.2f s), filling the matrix'
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print('%4f: translation matrix elements calculated (elapsed %.2f s), filling the matrix'
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% (timec, timec-timecold), file = sys.stderr)
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% (timec, timec-timecold), file = sys.stderr)
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sys.stderr.flush()
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transmat = np.zeros((xN* yN, 2, nelem, xN* yN, 2, nelem),dtype=np.complex_)
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transmat = np.zeros((xN* yN, 2, nelem, xN* yN, 2, nelem),dtype=np.complex_)
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for l in range(N):
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for l in range(N):
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xil, yil = xyind[l]
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xil, yil = xyind[l]
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@ -1106,6 +1109,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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timec = time.time()
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timec = time.time()
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print('%4f: translation matrix filled (elapsed %.2f s), building the interaction matrix'
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print('%4f: translation matrix filled (elapsed %.2f s), building the interaction matrix'
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% (timec, timec-timecold), file=sys.stderr)
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% (timec, timec-timecold), file=sys.stderr)
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sys.stderr.flush()
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# Now we solve a linear problem (1 - M T) A = M P_0 where M is the T-matrix :-)
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# Now we solve a linear problem (1 - M T) A = M P_0 where M is the T-matrix :-)
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MT = np.empty((N,2,nelem,N,2,nelem),dtype=np.complex_)
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MT = np.empty((N,2,nelem,N,2,nelem),dtype=np.complex_)
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@ -1122,6 +1126,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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timec = time.time()
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timec = time.time()
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print('%.4f: interaction matrix complete (elapsed %.2f s)' % (timec, timec-timecold),
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print('%.4f: interaction matrix complete (elapsed %.2f s)' % (timec, timec-timecold),
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file=sys.stderr)
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file=sys.stderr)
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sys.stderr.flush()
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if ((1 == k_dirs.ndim) and (1 == E_0s.ndim)):
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if ((1 == k_dirs.ndim) and (1 == E_0s.ndim)):
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k_cart = k_dirs * k_out # wave vector of the incident plane wave
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k_cart = k_dirs * k_out # wave vector of the incident plane wave
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@ -1143,10 +1148,12 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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timecold = time.time()
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timecold = time.time()
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print('%4f: solving the scattering problem for single incoming wave' % timecold,
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print('%4f: solving the scattering problem for single incoming wave' % timecold,
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file = sys.stderr)
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file = sys.stderr)
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sys.stderr.flush()
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ab = np.linalg.solve(leftmatrix, MP_0)
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ab = np.linalg.solve(leftmatrix, MP_0)
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if watch_time:
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if watch_time:
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timec = time.time()
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timec = time.time()
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print('%4f: solved (elapsed %.2f s)' % (timec, timec-timecold), file=sys.stderr)
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print('%4f: solved (elapsed %.2f s)' % (timec, timec-timecold), file=sys.stderr)
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sys.stderr.flush()
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ab.shape = (xN, yN, 2, nelem)
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ab.shape = (xN, yN, 2, nelem)
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else:
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else:
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@ -1171,6 +1178,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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file = sys.stderr)
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file = sys.stderr)
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print('%.4f: solving the scattering problem for %d incoming waves' % (timec, K),
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print('%.4f: solving the scattering problem for %d incoming waves' % (timec, K),
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file=sys.stderr)
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file=sys.stderr)
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sys.stderr.flush()
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timecold = timec
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timecold = timec
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if (return_pq_0):
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if (return_pq_0):
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@ -1194,6 +1202,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
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if watch_time:
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if watch_time:
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timec = time.time()
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timec = time.time()
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print('%.4f: done (elapsed %.2f s)' % (timec, timec-timecold),file = sys.stderr)
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print('%.4f: done (elapsed %.2f s)' % (timec, timec-timecold),file = sys.stderr)
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sys.stderr.flush()
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if not (return_pq_0 + return_pq + return_xy):
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if not (return_pq_0 + return_pq + return_xy):
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return ab
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return ab
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returnlist = [ab]
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returnlist = [ab]
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