1558 lines
60 KiB
Cython
1558 lines
60 KiB
Cython
# Cythonized parts of QPMS here
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# -----------------------------
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import numpy as np
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import cmath
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from qpms_cdefs cimport *
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cimport cython
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from cython.parallel cimport parallel, prange
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import enum
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import warnings
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# Here will be enum and dtype definitions; maybe move these to a separate file
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class VSWFType(enum.IntEnum):
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ELECTRIC = QPMS_VSWF_ELECTRIC
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MAGNETIC = QPMS_VSWF_MAGNETIC
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LONGITUDINAL = QPMS_VSWF_LONGITUDINAL
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M = QPMS_VSWF_MAGNETIC
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N = QPMS_VSWF_ELECTRIC
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L = QPMS_VSWF_LONGITUDINAL
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class VSWFNorm(enum.IntEnum):
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#XU = QPMS_NORMALISATION_XU
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#XU_CS = QPMS_NORMALISATION_XU_CS
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NONE = QPMS_NORMALISATION_NONE
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NONE_CS = QPMS_NORMALISATION_NONE_CS
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POWER = QPMS_NORMALISATION_POWER
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POWER_CS = QPMS_NORMALISATION_POWER_CS
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SPHARM = QPMS_NORMALISATION_SPHARM
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SPHARM_CS = QPMS_NORMALISATION_SPHARM_CS
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UNDEF = QPMS_NORMALISATION_UNDEF
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KRISTENSSON = QPMS_NORMALISATION_KRISTENSSON
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KRISTENSSON_CS = QPMS_NORMALISATION_KRISTENSSON_CS
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TAYLOR = QPMS_NORMALISATION_TAYLOR
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TAYLOR_CS = QPMS_NORMALISATION_TAYLOR_CS
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import math # for copysign in crep methods
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#import re # TODO for crep methods?
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#cimport openmp
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#openmp.omp_set_dynamic(1)
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## Auxillary function for retrieving the "meshgrid-like" indices; inc. nmax
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@cython.boundscheck(False)
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def get_mn_y(int nmax):
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"""
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Auxillary function for retreiving the 'meshgrid-like' indices from the flat indexing;
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inc. nmax.
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('y to mn' conversion)
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Parameters
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----------
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nmax : int
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The maximum order to which the VSWFs / Legendre functions etc. will be evaluated.
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Returns
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-------
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output : (m, n)
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Tuple of two arrays of type np.array(shape=(nmax*nmax + 2*nmax), dtype=np.int),
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where [(m[y],n[y]) for y in range(nmax*nmax + 2*nma)] covers all possible
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integer pairs n >= 1, -n <= m <= n.
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"""
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cdef Py_ssize_t nelems = nmax * nmax + 2 * nmax
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cdef np.ndarray[np.int_t,ndim=1] m_arr = np.empty([nelems], dtype=np.int)
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cdef np.ndarray[np.int_t,ndim=1] n_arr = np.empty([nelems], dtype=np.int)
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cdef Py_ssize_t i = 0
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cdef np.int_t n, m
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for n in range(1,nmax+1):
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for m in range(-n,n+1):
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m_arr[i] = m
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n_arr[i] = n
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i = i + 1
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return (m_arr, n_arr)
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def get_nelem(unsigned int lMax):
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return lMax * (lMax + 2)
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def get_y_mn_unsigned(int nmax):
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"""
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Auxillary function for mapping 'unsigned m', n indices to the flat y-indexing.
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For use with functions as scipy.special.lpmn, which have to be evaluated separately
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for positive and negative m.
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Parameters
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----------
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nmax : int
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The maximum order to which the VSWFs / Legendre functions etc. will be evaluated.
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output : (ymn_plus, ymn_minus)
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Tuple of two arrays of shape (nmax+1,nmax+1), containing the flat y-indices corresponding
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to the respective (m,n) and (-m,n). The elements for which |m| > n are set to -1.
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(Therefore, the caller must not use those elements equal to -1.)
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"""
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cdef np.ndarray[np.intp_t, ndim=2] ymn_plus = np.full((nmax+1,nmax+1),-1, dtype=np.intp)
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cdef np.ndarray[np.intp_t, ndim=2] ymn_minus = np.full((nmax+1,nmax+1),-1, dtype=np.intp)
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cdef Py_ssize_t i = 0
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cdef np.int_t n, m
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for n in range(1,nmax+1):
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for m in range(-n,0):
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ymn_minus[-m,n] = i
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i = i + 1
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for m in range(0,n+1):
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ymn_plus[m,n] = i
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i = i + 1
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return(ymn_plus, ymn_minus)
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cdef int q_max(int m, int n, int mu, int nu):
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return min(n,nu,(n+nu-abs(m+mu)//2))
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"""
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Now we generate our own universal functions to be used with numpy.
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Good way to see how this is done is to look at scipy/scipy/special/generate_ufuncs.py
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and scipy/scipy/special/generate_ufuncs.py
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In simple words, it works like this:
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- Let's have a single element function. This can be function which returns or a "subroutine".
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- Then we need a loop function; this is a wrapper that gets bunch of pointers from numpy and
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has to properly call the single element function.
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- From those two, we build a python object using PyUFunc_FromFuncAndData.
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* If the ufunc is supposed to work on different kinds of input/output types,
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then a pair of single-element and loop functions is o be provided for
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each combination of types. However, the single-element function can be reused if
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the corresponding loop functions do the proper casting.
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"""
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## as in scipy/special/_ufuncs_cxx.pyx
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##-------------------------------------
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#cdef extern from "numpy/ufuncobject.h":
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# int PyUFunc_getfperr() nogil
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#
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#cdef public int wrap_PyUFunc_getfperr() nogil:
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# """
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# Call PyUFunc_getfperr in a context where PyUFunc_API array is initialized;
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#
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# """
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# return PyUFunc_getfperr()
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#
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#cimport sf_error
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#-------------------------------------
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cdef void loop_D_iiiidddii_As_D_lllldddbl(char **args, np.npy_intp *dims, np.npy_intp *steps, void *data) nogil:
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cdef np.npy_intp i, n = dims[0]
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cdef void *func = (<void**>data)#[0]
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#cdef char *func_name= <char*>(<void**>data)[1] # i am not using this, nor have I saved func_name to data
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cdef char *ip0 = args[0]
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cdef char *ip1 = args[1]
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cdef char *ip2 = args[2]
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cdef char *ip3 = args[3]
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cdef char *ip4 = args[4]
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cdef char *ip5 = args[5]
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cdef char *ip6 = args[6]
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cdef char *ip7 = args[7]
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cdef char *ip8 = args[8]
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cdef char *op0 = args[9]
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cdef cdouble ov0
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for i in range(n): # iterating over dimensions
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ov0 = (<double complex(*)(int, int, int, int, double, double, double, int, int) nogil>func)(
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<int>(<np.npy_long*>ip0)[0],
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<int>(<np.npy_long*>ip1)[0],
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<int>(<np.npy_long*>ip2)[0],
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<int>(<np.npy_long*>ip3)[0],
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<double>(<np.npy_double*>ip4)[0],
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<double>(<np.npy_double*>ip5)[0],
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<double>(<np.npy_double*>ip6)[0],
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<int>(<np.npy_bool*>ip7)[0],
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<int>(<np.npy_long*>ip8)[0],
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)
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(<cdouble *>op0)[0] = <cdouble>ov0
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ip0 += steps[0]
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ip1 += steps[1]
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ip2 += steps[2]
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ip3 += steps[3]
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ip4 += steps[4]
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ip5 += steps[5]
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ip6 += steps[6]
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ip7 += steps[7]
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ip8 += steps[8]
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op0 += steps[9]
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# FIXME ERROR HANDLING!!! requires correct import and different data passed (see scipy's generated ufuncs)
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# sf_error.check_fpe(func_name)
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# Module initialisation
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# ---------------------
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np.import_array() # not sure whether this is really needed
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np.import_ufunc()
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# Arrays passed to PyUFunc_FromFuncAndData()
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# ------------------------------------------
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# BTW, aren't there anonymous arrays in cython?
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cdef np.PyUFuncGenericFunction trans_X_taylor_loop_func[1]
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cdef void *trans_A_taylor_elementwise_funcs[1]
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cdef void *trans_B_taylor_elementwise_funcs[1]
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trans_X_taylor_loop_func[0] = loop_D_iiiidddii_As_D_lllldddbl
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# types to be used for all of the single-type translation
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# coefficient retrieval ufuncs called like
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# coeff = func(m, n, mu, nu, r, theta, phi, r_ge_d, J)
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# currently supported signatures: (D_lllldddbl)
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cdef char ufunc__get_either_trans_coeff_types[10]
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ufunc__get_either_trans_coeff_types[0] = np.NPY_LONG
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ufunc__get_either_trans_coeff_types[1] = np.NPY_LONG
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ufunc__get_either_trans_coeff_types[2] = np.NPY_LONG
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ufunc__get_either_trans_coeff_types[3] = np.NPY_LONG
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ufunc__get_either_trans_coeff_types[4] = np.NPY_DOUBLE
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ufunc__get_either_trans_coeff_types[5] = np.NPY_DOUBLE
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ufunc__get_either_trans_coeff_types[6] = np.NPY_DOUBLE
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ufunc__get_either_trans_coeff_types[7] = np.NPY_BOOL
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ufunc__get_either_trans_coeff_types[8] = np.NPY_LONG
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ufunc__get_either_trans_coeff_types[9] = np.NPY_CDOUBLE
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# types to be used for all of the both-type translation
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# coefficient retrieval ufuncs called like
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# errval = func(m, n, mu, nu, r, theta, phi, r_ge_d, J, &A, &B)
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# currently supported signatures: (lllldddbl_DD)
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cdef char ufunc__get_both_coeff_types[11]
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ufunc__get_both_coeff_types[0] = np.NPY_LONG
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ufunc__get_both_coeff_types[1] = np.NPY_LONG
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ufunc__get_both_coeff_types[2] = np.NPY_LONG
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ufunc__get_both_coeff_types[3] = np.NPY_LONG
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ufunc__get_both_coeff_types[4] = np.NPY_DOUBLE
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ufunc__get_both_coeff_types[5] = np.NPY_DOUBLE
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ufunc__get_both_coeff_types[6] = np.NPY_DOUBLE
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ufunc__get_both_coeff_types[7] = np.NPY_BOOL
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ufunc__get_both_coeff_types[8] = np.NPY_LONG
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ufunc__get_both_coeff_types[9] = np.NPY_CDOUBLE
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ufunc__get_both_coeff_types[10] = np.NPY_CDOUBLE
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trans_A_taylor_elementwise_funcs[0] = <void*> qpms_trans_single_A_Taylor_ext
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trans_B_taylor_elementwise_funcs[0] = <void*> qpms_trans_single_B_Taylor_ext
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trans_A_Taylor = np.PyUFunc_FromFuncAndData(
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trans_X_taylor_loop_func, # func
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trans_A_taylor_elementwise_funcs, #data
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ufunc__get_either_trans_coeff_types, # types
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1, # ntypes: number of supported input types
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9, # nin: number of input args
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1, # nout: number of output args
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0, # identity element, unused
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"trans_A_Taylor", # name
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"""
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TODO computes the E-E or M-M translation coefficient in Taylor's normalisation
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""", # doc
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0 # unused, for backward compatibility of numpy c api
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)
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trans_B_Taylor = np.PyUFunc_FromFuncAndData(
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trans_X_taylor_loop_func,
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trans_B_taylor_elementwise_funcs,
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ufunc__get_either_trans_coeff_types,
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1, # number of supported input types
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9, # number of input args
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1, # number of output args
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0, # identity element, unused
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"trans_B_Taylor",
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"""
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TODO computes the E-E or M-M translation coefficient in Taylor's normalisation
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""",
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0 # unused
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)
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# ---------------------------------------------
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# Wrapper for the qpms_trans_calculator "class"
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# ---------------------------------------------
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ctypedef struct trans_calculator_get_X_data_t:
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qpms_trans_calculator* c
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void* cmethod
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cdef void trans_calculator_loop_D_Ciiiidddii_As_D_lllldddbl(char **args, np.npy_intp *dims, np.npy_intp *steps, void *data) nogil:
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cdef np.npy_intp i, n = dims[0]
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cdef void *func = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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#cdef cdouble (*func)(qpms_trans_calculator*, int, int, int, int, double, double, double, int, int) nogil = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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cdef qpms_trans_calculator* c = (<trans_calculator_get_X_data_t*>data)[0].c
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#cdef char *func_name= <char*>(<void**>data)[1] # i am not using this, nor have I saved func_name to data
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cdef char *ip0 = args[0]
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cdef char *ip1 = args[1]
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cdef char *ip2 = args[2]
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cdef char *ip3 = args[3]
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cdef char *ip4 = args[4]
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cdef char *ip5 = args[5]
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cdef char *ip6 = args[6]
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cdef char *ip7 = args[7]
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cdef char *ip8 = args[8]
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cdef char *op0 = args[9]
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cdef cdouble ov0
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for i in range(n): # iterating over dimensions
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#ov0 = func(
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ov0 = (<double complex(*)(qpms_trans_calculator*, int, int, int, int, double, double, double, int, int) nogil>func)(
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c,
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<int>(<np.npy_long*>ip0)[0],
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<int>(<np.npy_long*>ip1)[0],
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<int>(<np.npy_long*>ip2)[0],
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<int>(<np.npy_long*>ip3)[0],
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<double>(<np.npy_double*>ip4)[0],
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<double>(<np.npy_double*>ip5)[0],
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<double>(<np.npy_double*>ip6)[0],
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<int>(<np.npy_bool*>ip7)[0],
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<int>(<np.npy_long*>ip8)[0],
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)
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(<cdouble *>op0)[0] = <cdouble>ov0
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ip0 += steps[0]
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ip1 += steps[1]
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ip2 += steps[2]
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ip3 += steps[3]
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ip4 += steps[4]
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ip5 += steps[5]
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ip6 += steps[6]
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ip7 += steps[7]
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ip8 += steps[8]
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op0 += steps[9]
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# FIXME ERROR HANDLING!!! requires correct import and different data passed (see scipy's generated ufuncs)
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# sf_error.check_fpe(func_name)
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cdef void trans_calculator_loop_E_C_DD_iiiidddii_As_lllldddbl_DD(char **args, np.npy_intp *dims, np.npy_intp *steps, void *data) nogil:
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# E stands for error value (int), C for qpms_trans_calculator*
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cdef np.npy_intp i, n = dims[0]
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cdef void *func = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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#cdef complex double (*func)(qpms_trans_calculator*, double complex *, double complex *, int, int, int, int, double, double, double, int, int) nogil = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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cdef qpms_trans_calculator* c = (<trans_calculator_get_X_data_t*>data)[0].c
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#cdef char *func_name= <char*>(<void**>data)[1] # i am not using this, nor have I saved func_name to data
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cdef char *ip0 = args[0]
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cdef char *ip1 = args[1]
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cdef char *ip2 = args[2]
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cdef char *ip3 = args[3]
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cdef char *ip4 = args[4]
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cdef char *ip5 = args[5]
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cdef char *ip6 = args[6]
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cdef char *ip7 = args[7]
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cdef char *ip8 = args[8]
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cdef char *op0 = args[9]
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cdef char *op1 = args[10]
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cdef cdouble ov0
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cdef int errval
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for i in range(n): # iterating over dimensions
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#errval = func(
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errval = (<int(*)(qpms_trans_calculator*, double complex *, double complex *, int, int, int, int, double, double, double, int, int) nogil>func)(
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c,
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<cdouble *> op0,
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<cdouble *> op1,
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<int>(<np.npy_long*>ip0)[0],
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<int>(<np.npy_long*>ip1)[0],
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<int>(<np.npy_long*>ip2)[0],
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<int>(<np.npy_long*>ip3)[0],
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<double>(<np.npy_double*>ip4)[0],
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<double>(<np.npy_double*>ip5)[0],
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<double>(<np.npy_double*>ip6)[0],
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<int>(<np.npy_bool*>ip7)[0],
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<int>(<np.npy_long*>ip8)[0],
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)
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ip0 += steps[0]
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ip1 += steps[1]
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ip2 += steps[2]
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ip3 += steps[3]
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ip4 += steps[4]
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ip5 += steps[5]
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ip6 += steps[6]
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ip7 += steps[7]
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ip8 += steps[8]
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op0 += steps[9]
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op1 += steps[10]
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# TODO if (errval != 0): ...
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# FIXME ERROR HANDLING!!! requires correct import and different data passed (see scipy's generated ufuncs)
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# sf_error.check_fpe(func_name)
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@cython.boundscheck(False)
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@cython.wraparound(False)
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cdef void trans_calculator_parallel_loop_E_C_DD_iiiidddii_As_lllldddbl_DD(char **args, np.npy_intp *dims, np.npy_intp *steps, void *data) nogil:
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# E stands for error value (int), C for qpms_trans_calculator*
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cdef np.npy_intp i, n = dims[0]
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cdef void *func = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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#cdef complex double (*func)(qpms_trans_calculator*, double complex *, double complex *, int, int, int, int, double, double, double, int, int) nogil = (<trans_calculator_get_X_data_t*>data)[0].cmethod
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cdef qpms_trans_calculator* c = (<trans_calculator_get_X_data_t*>data)[0].c
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#cdef char *func_name= <char*>(<void**>data)[1] # i am not using this, nor have I saved func_name to data
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cdef char *ip0
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cdef char *ip1
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cdef char *ip2
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cdef char *ip3
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cdef char *ip4
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cdef char *ip5
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cdef char *ip6
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cdef char *ip7
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cdef char *ip8
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cdef char *op0
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cdef char *op1
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cdef int errval
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for i in prange(n): # iterating over dimensions
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ip0 = args[0] + i * steps[0]
|
|
ip1 = args[1] + i * steps[1]
|
|
ip2 = args[2] + i * steps[2]
|
|
ip3 = args[3] + i * steps[3]
|
|
ip4 = args[4] + i * steps[4]
|
|
ip5 = args[5] + i * steps[5]
|
|
ip6 = args[6] + i * steps[6]
|
|
ip7 = args[7] + i * steps[7]
|
|
ip8 = args[8] + i * steps[8]
|
|
op0 = args[9] + i * steps[9]
|
|
op1 = args[10] + i * steps[10]
|
|
#errval = func(
|
|
errval = (<int(*)(qpms_trans_calculator*, double complex *, double complex *, int, int, int, int, double, double, double, int, int) nogil>func)(
|
|
c,
|
|
<cdouble *> op0,
|
|
<cdouble *> op1,
|
|
<int>(<np.npy_long*>ip0)[0],
|
|
<int>(<np.npy_long*>ip1)[0],
|
|
<int>(<np.npy_long*>ip2)[0],
|
|
<int>(<np.npy_long*>ip3)[0],
|
|
<double>(<np.npy_double*>ip4)[0],
|
|
<double>(<np.npy_double*>ip5)[0],
|
|
<double>(<np.npy_double*>ip6)[0],
|
|
<int>(<np.npy_bool*>ip7)[0],
|
|
<int>(<np.npy_long*>ip8)[0],
|
|
)
|
|
# TODO if (errval != 0): ...
|
|
# FIXME ERROR HANDLING!!! requires correct import and different data passed (see scipy's generated ufuncs)
|
|
# sf_error.check_fpe(func_name)
|
|
|
|
|
|
cdef np.PyUFuncGenericFunction trans_calculator_get_X_loop_funcs[1]
|
|
trans_calculator_get_X_loop_funcs[0] = trans_calculator_loop_D_Ciiiidddii_As_D_lllldddbl
|
|
|
|
cdef np.PyUFuncGenericFunction trans_calculator_get_AB_loop_funcs[1]
|
|
#trans_calculator_get_AB_loop_funcs[0] = trans_calculator_parallel_loop_E_C_DD_iiiidddii_As_lllldddbl_DD
|
|
trans_calculator_get_AB_loop_funcs[0] = trans_calculator_loop_E_C_DD_iiiidddii_As_lllldddbl_DD
|
|
cdef void *trans_calculator_get_AB_elementwise_funcs[1]
|
|
trans_calculator_get_AB_elementwise_funcs[0] = <void *>qpms_trans_calculator_get_AB_p_ext
|
|
|
|
'''
|
|
cdef extern from "numpy/ndarrayobject.h":
|
|
struct PyArrayInterface:
|
|
int itemsize
|
|
np.npy_uintp *shape
|
|
np.npy_uintp *strides
|
|
void *data
|
|
'''
|
|
|
|
|
|
from libc.stdlib cimport malloc, free, calloc, abort
|
|
|
|
|
|
|
|
cdef class trans_calculator:
|
|
cdef qpms_trans_calculator* c
|
|
cdef trans_calculator_get_X_data_t get_A_data[1]
|
|
cdef trans_calculator_get_X_data_t* get_A_data_p[1]
|
|
|
|
cdef trans_calculator_get_X_data_t get_B_data[1]
|
|
cdef trans_calculator_get_X_data_t* get_B_data_p[1]
|
|
|
|
cdef trans_calculator_get_X_data_t get_AB_data[1]
|
|
cdef trans_calculator_get_X_data_t* get_AB_data_p[1]
|
|
cdef public: # TODO CHECK FOR CORRECT REFERENCE COUNTING AND LEAKS
|
|
# have to be cdef public in order that __init__ can set these attributes
|
|
object get_A, get_B, get_AB
|
|
|
|
def __cinit__(self, int lMax, int normalization = 1):
|
|
if (lMax <= 0):
|
|
raise ValueError('lMax has to be greater than 0.')
|
|
self.c = qpms_trans_calculator_init(lMax, normalization)
|
|
if self.c is NULL:
|
|
raise MemoryError
|
|
|
|
def __init__(self, int lMax, int normalization = 1):
|
|
if self.c is NULL:
|
|
raise MemoryError()
|
|
self.get_A_data[0].c = self.c
|
|
self.get_A_data[0].cmethod = <void *>qpms_trans_calculator_get_A_ext
|
|
self.get_A_data_p[0] = &(self.get_A_data[0])
|
|
self.get_A = <object>np.PyUFunc_FromFuncAndData(# TODO CHECK FOR CORRECT REFERENCE COUNTING AND LEAKS
|
|
trans_calculator_get_X_loop_funcs, # func
|
|
<void **>self.get_A_data_p, #data
|
|
ufunc__get_either_trans_coeff_types, #types
|
|
1, # ntypes: number of supported input types
|
|
9, # nin: number of input args
|
|
1, # nout: number of output args
|
|
0, # identity element, unused
|
|
"get_A", #name
|
|
"""
|
|
TODO doc
|
|
""", # doc
|
|
0 # unused
|
|
)
|
|
self.get_B_data[0].c = self.c
|
|
self.get_B_data[0].cmethod = <void *>qpms_trans_calculator_get_B_ext
|
|
self.get_B_data_p[0] = &(self.get_B_data[0])
|
|
self.get_B = <object>np.PyUFunc_FromFuncAndData(# TODO CHECK FOR CORRECT REFERENCE COUNTING AND LEAKS
|
|
trans_calculator_get_X_loop_funcs, # func
|
|
<void **>self.get_B_data_p, #data
|
|
ufunc__get_either_trans_coeff_types, #types
|
|
1, # ntypes: number of supported input types
|
|
9, # nin: number of input args
|
|
1, # nout: number of output args
|
|
0, # identity element, unused
|
|
"get_B", #name
|
|
"""
|
|
TODO doc
|
|
""", # doc
|
|
0 # unused
|
|
)
|
|
self.get_AB_data[0].c = self.c
|
|
self.get_AB_data[0].cmethod = <void *>qpms_trans_calculator_get_AB_p_ext
|
|
self.get_AB_data_p[0] = &(self.get_AB_data[0])
|
|
self.get_AB = <object>np.PyUFunc_FromFuncAndData(# TODO CHECK FOR CORRECT REFERENCE COUNTING AND LEAKS
|
|
trans_calculator_get_AB_loop_funcs, # func
|
|
<void **>self.get_AB_data_p, #data
|
|
ufunc__get_both_coeff_types, #types
|
|
1, # ntypes: number of supported input types
|
|
9, # nin: number of input args
|
|
2, # nout: number of output args
|
|
0, # identity element, unused
|
|
"get_AB", #name
|
|
"""
|
|
TODO doc
|
|
""", # doc
|
|
0 # unused
|
|
)
|
|
def __dealloc__(self):
|
|
if self.c is not NULL:
|
|
qpms_trans_calculator_free(self.c)
|
|
# TODO Reference counts to get_A, get_B, get_AB?
|
|
|
|
def lMax(self):
|
|
return self.c[0].lMax
|
|
|
|
def nelem(self):
|
|
return self.c[0].nelem
|
|
|
|
def get_AB_arrays(self, r, theta, phi, r_ge_d, int J,
|
|
destaxis=None, srcaxis=None, expand=True):
|
|
"""
|
|
Returns arrays of translation coefficients, inserting two new nelem-sized axes
|
|
(corresponding to the destination and source axes of the translation matrix,
|
|
respectively).
|
|
|
|
By default (expand==True), it inserts the new axes. or it can be provided with
|
|
the resulting shape (with the corresponding axes dimensions equal to one).
|
|
The provided axes positions are for the resulting array.
|
|
|
|
If none axis positions are provided, destaxis and srcaxis will be the second-to-last
|
|
and last, respectively.
|
|
"""
|
|
# TODO CHECK (and try to cast) INPUT ARRAY TYPES (now is done)
|
|
# BIG FIXME: make skalars valid arguments, now r, theta, phi, r_ge_d have to be ndarrays
|
|
cdef:
|
|
int daxis, saxis, smallaxis, bigaxis, resnd, i, j, d, ax, errval
|
|
np.npy_intp sstride, dstride, longi
|
|
int *local_indices
|
|
char *r_p
|
|
char *theta_p
|
|
char *phi_p
|
|
char *r_ge_d_p
|
|
char *a_p
|
|
char *b_p
|
|
# Process the array shapes
|
|
baseshape = np.broadcast(r,theta,phi,r_ge_d).shape # nope, does not work as needed
|
|
'''
|
|
cdef int r_orignd = r.ndim if hasattr(r, "ndim") else 0
|
|
cdef int theta_orignd = theta.ndim if hasattr(theta, "ndim") else 0
|
|
cdef int phi_orignd = phi.ndim if hasattr(phi, "ndim") else 0
|
|
cdef int r_ge_d_orignd = r_ge_d.ndim if hasattr(r_ge_d, "__len__") else 0
|
|
cdef int basend = max(r_orignd, theta_orignd, phi_orignd, r_ge_d_orignd)
|
|
baseshape = list()
|
|
for d in range(basend):
|
|
baseshape.append(max(
|
|
r.shape[d+r_orignd-basend] if d+r_orignd-basend >= 0 else 1,
|
|
theta.shape[d+theta_orignd-basend] if d+theta_orignd-basend >= 0 else 1,
|
|
phi.shape[d+phi_orignd-basend] if d+phi_orignd-basend >= 0 else 1,
|
|
r_ge_d.shape[d+r_ge_d_orignd-basend] if d+r_ge_d_orignd-basend >= 0 else 1,
|
|
))
|
|
baseshape = tuple(baseshape)
|
|
'''
|
|
if not expand:
|
|
resnd = len(baseshape)
|
|
if resnd < 2:
|
|
raise ValueError('Translation matrix arrays must have at least 2 dimensions!')
|
|
daxis = (resnd-2) if destaxis is None else destaxis
|
|
saxis = (resnd-1) if srcaxis is None else srcaxis
|
|
if daxis < 0:
|
|
daxis = resnd + daxis
|
|
if saxis < 0:
|
|
saxis = resnd + saxis
|
|
if daxis < 0 or saxis < 0 or daxis >= resnd or saxis >= resnd or daxis == saxis:
|
|
raise ValueError('invalid axes provided (destaxis = %d, srcaxis = %d, # of axes: %d'
|
|
% (daxis, saxis, resnd))
|
|
if baseshape[daxis] != 1 or baseshape[saxis] != 1:
|
|
raise ValueError('dimension mismatch (input argument dimensions have to be 1 both at'
|
|
'destaxis (==%d) and srcaxis (==%d) but are %d and %d' %
|
|
(daxis, saxis, baseshape[daxis], baseshape[saxis]))
|
|
resultshape = list(baseshape)
|
|
else:
|
|
resnd = len(baseshape)+2
|
|
daxis = (resnd-2) if destaxis is None else destaxis
|
|
saxis = (resnd-1) if srcaxis is None else srcaxis
|
|
if daxis < 0:
|
|
daxis = resnd + daxis
|
|
if saxis < 0:
|
|
saxis = resnd + saxis
|
|
if daxis < 0 or saxis < 0 or daxis >= resnd or saxis >= resnd or daxis == saxis:
|
|
raise ValueError('invalid axes provided') # TODO better error formulation
|
|
resultshape = list(baseshape)
|
|
if daxis > saxis:
|
|
smallaxis = saxis
|
|
bigaxis = daxis
|
|
else:
|
|
smallaxis = daxis
|
|
bigaxis = saxis
|
|
resultshape.insert(smallaxis,1)
|
|
resultshape.insert(bigaxis,1)
|
|
r = np.expand_dims(np.expand_dims(r.astype(np.float_, copy=False), smallaxis), bigaxis)
|
|
theta = np.expand_dims(np.expand_dims(theta.astype(np.float_, copy=False), smallaxis), bigaxis)
|
|
phi = np.expand_dims(np.expand_dims(phi.astype(np.float_, copy=False), smallaxis), bigaxis)
|
|
r_ge_d = np.expand_dims(np.expand_dims(r_ge_d.astype(np.bool_, copy=False), smallaxis), bigaxis)
|
|
|
|
resultshape[daxis] = self.c[0].nelem
|
|
resultshape[saxis] = self.c[0].nelem
|
|
cdef np.ndarray r_c = np.broadcast_to(r,resultshape)
|
|
cdef np.ndarray theta_c = np.broadcast_to(theta,resultshape)
|
|
cdef np.ndarray phi_c = np.broadcast_to(phi,resultshape)
|
|
cdef np.ndarray r_ge_d_c = np.broadcast_to(r_ge_d, resultshape)
|
|
cdef np.ndarray a = np.empty(resultshape, dtype=complex)
|
|
cdef np.ndarray b = np.empty(resultshape, dtype=complex)
|
|
dstride = a.strides[daxis]
|
|
sstride = a.strides[saxis]
|
|
with nogil:
|
|
errval = qpms_cython_trans_calculator_get_AB_arrays_loop(
|
|
self.c, J, resnd,
|
|
daxis, saxis,
|
|
a.data, a.shape, a.strides,
|
|
b.data, b.shape, b.strides,
|
|
r_c.data, r_c.shape, r_c.strides,
|
|
theta_c.data, theta_c.shape, theta_c.strides,
|
|
phi_c.data, phi_c.shape, phi_c.strides,
|
|
r_ge_d_c.data, r_ge_d_c.shape, r_ge_d_c.strides
|
|
)
|
|
return a, b
|
|
|
|
# TODO make possible to access the attributes (to show normalization etc)
|
|
|
|
|
|
def complex_crep(complex c, parentheses = False, shortI = True, has_Imaginary = False):
|
|
'''
|
|
Return a C-code compatible string representation of a (python) complex number.
|
|
'''
|
|
return ( ('(' if parentheses else '')
|
|
+ repr(c.real)
|
|
+ ('+' if math.copysign(1, c.imag) >= 0 else '')
|
|
+ repr(c.imag)
|
|
+ ('*I' if shortI else '*_Imaginary_I' if has_Imaginary else '*_Complex_I')
|
|
+ (')' if parentheses else '')
|
|
)
|
|
|
|
cdef class BaseSpec:
|
|
'''Cython wrapper over qpms_vswf_set_spec_t.
|
|
|
|
It should be kept immutable. The memory is managed by numpy/cython, not directly by the C functions, therefore
|
|
whenever used in other wrapper classes that need the pointer
|
|
to qpms_vswf_set_spec_t, remember to set a (private, probably immutable) reference to qpms.basespec to ensure
|
|
correct reference counting and garbage collection.
|
|
'''
|
|
cdef qpms_vswf_set_spec_t s
|
|
cdef np.ndarray __ilist
|
|
#cdef const qpms_uvswfi_t[:] __ilist
|
|
|
|
def __cinit__(self, *args, **kwargs):
|
|
cdef const qpms_uvswfi_t[:] ilist_memview
|
|
if len(args) == 0:
|
|
if 'lMax' in kwargs.keys(): # if only lMax is specified, create the 'usual' definition in ('E','M') order
|
|
lMax = kwargs['lMax']
|
|
my, ny = get_mn_y(lMax)
|
|
nelem = len(my)
|
|
tlist = nelem * (QPMS_VSWF_ELECTRIC,) + nelem * (QPMS_VSWF_MAGNETIC,)
|
|
mlist = 2*list(my)
|
|
llist = 2*list(ny)
|
|
ilist = tlm2uvswfi(tlist,llist,mlist)
|
|
else:
|
|
raise ValueError
|
|
else: # len(args) > 0:
|
|
ilist = args[0]
|
|
#self.__ilist = np.array(args[0], dtype=qpms_uvswfi_t, order='C', copy=True) # FIXME define the dtypes at qpms_cdef.pxd level
|
|
self.__ilist = np.array(ilist, dtype=np.ulonglong, order='C', copy=True)
|
|
self.__ilist.setflags(write=False)
|
|
ilist_memview = self.__ilist
|
|
self.s.ilist = &ilist_memview[0]
|
|
self.s.n = len(self.__ilist)
|
|
self.s.capacity = 0 # is this the best way?
|
|
if 'norm' in kwargs.keys():
|
|
self.s.norm = kwargs['norm']
|
|
else:
|
|
self.s.norm = QPMS_NORMALISATION_POWER_CS
|
|
# set the other metadata
|
|
cdef qpms_l_t l
|
|
self.s.lMax_L = -1
|
|
cdef qpms_m_t m
|
|
cdef qpms_vswf_type_t t
|
|
for i in range(self.s.n):
|
|
if(qpms_uvswfi2tmn(ilist_memview[i], &t, &m, &l) != QPMS_SUCCESS):
|
|
raise ValueError("Invalid uvswf index")
|
|
if (t == QPMS_VSWF_ELECTRIC):
|
|
self.s.lMax_N = max(self.s.lMax_N, l)
|
|
elif (t == QPMS_VSWF_MAGNETIC):
|
|
self.s.lMax_M = max(self.s.lMax_M, l)
|
|
elif (t == QPMS_VSWF_LONGITUDINAL):
|
|
self.s.lMax_L = max(self.s.lMax_L, l)
|
|
else:
|
|
raise ValueError # If this happens, it's probably a bug, as it should have failed already at qpms_uvswfi2tmn
|
|
self.s.lMax = max(self.s.lMax, l)
|
|
|
|
def tlm(self):
|
|
cdef const qpms_uvswfi_t[:] ilist_memview = <qpms_uvswfi_t[:self.s.n]> self.s.ilist
|
|
#cdef qpms_vswf_type_t[:] t = np.empty(shape=(self.s.n,), dtype=qpms_vswf_type_t) # does not work, workaround:
|
|
cdef size_t i
|
|
cdef np.ndarray ta = np.empty(shape=(self.s.n,), dtype=np.intc)
|
|
cdef int[:] t = ta
|
|
#cdef qpms_l_t[:] l = np.empty(shape=(self.s.n,), dtype=qpms_l_t) # FIXME explicit dtype again
|
|
cdef np.ndarray la = np.empty(shape=(self.s.n,), dtype=np.intc)
|
|
cdef qpms_l_t[:] l = la
|
|
#cdef qpms_m_t[:] m = np.empty(shape=(self.s.n,), dtype=qpms_m_t) # FIXME explicit dtype again
|
|
cdef np.ndarray ma = np.empty(shape=(self.s.n,), dtype=np.intc)
|
|
cdef qpms_m_t[:] m = ma
|
|
for i in range(self.s.n):
|
|
qpms_uvswfi2tmn(self.s.ilist[i], <qpms_vswf_type_t*>&t[i], &m[i], &l[i])
|
|
return (ta, la, ma)
|
|
|
|
def m(self): # ugly
|
|
return self.tlm()[2]
|
|
|
|
def t(self): # ugly
|
|
return self.tlm()[0]
|
|
|
|
def l(self): # ugly
|
|
return self.tlm()[1]
|
|
|
|
def __len__(self):
|
|
return self.s.n
|
|
|
|
def __getitem__(self, key):
|
|
# TODO raise correct errors (TypeError on bad type of key, IndexError on exceeding index)
|
|
return self.__ilist[key]
|
|
|
|
property ilist:
|
|
def __get__(self):
|
|
return self.__ilist
|
|
|
|
cdef qpms_vswf_set_spec_t *rawpointer(BaseSpec self):
|
|
'''Pointer to the qpms_vswf_set_spec_t structure.
|
|
Don't forget to reference the BaseSpec object itself when storing the pointer anywhere!!!
|
|
'''
|
|
return &(self.s)
|
|
|
|
property rawpointer:
|
|
def __get__(self):
|
|
return <uintptr_t> &(self.s)
|
|
|
|
# Quaternions from wigner.h
|
|
# (mainly for testing; use moble's quaternions in python)
|
|
|
|
cdef class CQuat:
|
|
'''
|
|
Wrapper of the qpms_quat_t object, with the functionality
|
|
to evaluate Wigner D-matrix elements.
|
|
'''
|
|
cdef readonly qpms_quat_t q
|
|
|
|
def __cinit__(self, double w, double x, double y, double z):
|
|
cdef qpms_quat4d_t p
|
|
p.c1 = w
|
|
p.ci = x
|
|
p.cj = y
|
|
p.ck = z
|
|
self.q = qpms_quat_2c_from_4d(p)
|
|
|
|
def copy(self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = self.q
|
|
return res
|
|
|
|
def __repr__(self): # TODO make this look like a quaternion with i,j,k
|
|
return repr(self.r)
|
|
|
|
def __add__(CQuat self, CQuat other):
|
|
# TODO add real numbers
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_add(self.q, other.q)
|
|
return res
|
|
|
|
def __mul__(self, other):
|
|
res = CQuat(0,0,0,0)
|
|
if isinstance(self, CQuat):
|
|
if isinstance(other, CQuat):
|
|
res.q = qpms_quat_mult(self.q, other.q)
|
|
elif isinstance(other, (int, float)):
|
|
res.q = qpms_quat_rscale(other, self.q)
|
|
else: return NotImplemented
|
|
elif isinstance(self, (int, float)):
|
|
if isinstance(other, CQuat):
|
|
res.q = qpms_quat_rscale(self, other.q)
|
|
else: return NotImplemented
|
|
return res
|
|
|
|
def __neg__(CQuat self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_rscale(-1, self.q)
|
|
return res
|
|
|
|
def __sub__(CQuat self, CQuat other):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_add(self.q, qpms_quat_rscale(-1,other.q))
|
|
return res
|
|
|
|
def __abs__(self):
|
|
return qpms_quat_norm(self.q)
|
|
|
|
def norm(self):
|
|
return qpms_quat_norm(self.q)
|
|
|
|
def imnorm(self):
|
|
return qpms_quat_imnorm(self.q)
|
|
|
|
def exp(self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_exp(self.q)
|
|
return res
|
|
|
|
def log(self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_exp(self.q)
|
|
return res
|
|
|
|
def __pow__(CQuat self, double other, _):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_pow(self.q, other)
|
|
return res
|
|
|
|
def normalise(self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = qpms_quat_normalise(self.q)
|
|
return res
|
|
|
|
def isclose(CQuat self, CQuat other, rtol=1e-5, atol=1e-8):
|
|
'''
|
|
Checks whether two quaternions are "almost equal".
|
|
'''
|
|
return abs(self - other) <= (atol + rtol * abs(other))
|
|
|
|
property c:
|
|
'''
|
|
Quaternion representation as two complex numbers
|
|
'''
|
|
def __get__(self):
|
|
return (self.q.a, self.q.b)
|
|
def __set__(self, RaRb):
|
|
self.q.a = RaRb[0]
|
|
self.q.b = RaRb[1]
|
|
|
|
property r:
|
|
'''
|
|
Quaternion representation as four real numbers
|
|
'''
|
|
def __get__(self):
|
|
cdef qpms_quat4d_t p
|
|
p = qpms_quat_4d_from_2c(self.q)
|
|
return (p.c1, p.ci, p.cj, p.ck)
|
|
def __set__(self, wxyz):
|
|
cdef qpms_quat4d_t p
|
|
p.c1 = wxyz[0]
|
|
p.ci = wxyz[1]
|
|
p.cj = wxyz[2]
|
|
p.ck = wxyz[3]
|
|
self.q = qpms_quat_2c_from_4d(p)
|
|
|
|
def crepr(self):
|
|
'''
|
|
Returns a string that can be used in C code to initialise a qpms_irot3_t
|
|
'''
|
|
return '{' + complex_crep(self.q.a) + ', ' + complex_crep(self.q.b) + '}'
|
|
|
|
def wignerDelem(self, qpms_l_t l, qpms_m_t mp, qpms_m_t m):
|
|
'''
|
|
Returns an element of a bosonic Wigner matrix.
|
|
'''
|
|
# don't crash on bad l, m here
|
|
if (abs(m) > l or abs(mp) > l):
|
|
return 0
|
|
return qpms_wignerD_elem(self.q, l, mp, m)
|
|
|
|
cdef class IRot3:
|
|
'''
|
|
Wrapper over the C type qpms_irot3_t.
|
|
'''
|
|
cdef readonly qpms_irot3_t qd
|
|
|
|
def __cinit__(self, *args):
|
|
'''
|
|
TODO doc
|
|
'''
|
|
# TODO implement a constructor with
|
|
# - tuple as argument ...?
|
|
if (len(args) == 0): # no args, return identity
|
|
self.qd.rot.a = 1
|
|
self.qd.rot.b = 0
|
|
self.qd.det = 1
|
|
elif (len(args) == 2 and isinstance(args[0], CQuat) and isinstance(args[1], (int, float))):
|
|
# The original __cinit__(self, CQuat q, short det) constructor
|
|
q = args[0]
|
|
det = args[1]
|
|
if (det != 1 and det != -1):
|
|
raise ValueError("Improper rotation determinant has to be 1 or -1")
|
|
self.qd.rot = q.normalise().q
|
|
self.qd.det = det
|
|
elif (len(args) == 1 and isinstance(args[0], IRot3)):
|
|
# Copy
|
|
self.qd = args[0].qd
|
|
elif (len(args) == 1 and isinstance(args[0], CQuat)):
|
|
# proper rotation from a quaternion
|
|
q = args[0]
|
|
det = 1
|
|
self.qd.rot = q.normalise().q
|
|
self.qd.det = det
|
|
else:
|
|
raise ValueError('Unsupported constructor arguments')
|
|
|
|
def copy(self):
|
|
res = IRot3(CQuat(1,0,0,0),1)
|
|
res.qd = self.qd
|
|
return res
|
|
|
|
property rot:
|
|
'''
|
|
The proper rotation part of the IRot3 type.
|
|
'''
|
|
def __get__(self):
|
|
res = CQuat(0,0,0,0)
|
|
res.q = self.qd.rot
|
|
return res
|
|
def __set__(self, CQuat r):
|
|
# TODO check for non-zeroness and throw an exception if norm is zero
|
|
self.qd.rot = r.normalise().q
|
|
|
|
property det:
|
|
'''
|
|
The determinant of the improper rotation.
|
|
'''
|
|
def __get__(self):
|
|
return self.qd.det
|
|
def __set__(self, d):
|
|
d = int(d)
|
|
if (d != 1 and d != -1):
|
|
raise ValueError("Improper rotation determinant has to be 1 or -1")
|
|
self.qd.det = d
|
|
|
|
def __repr__(self): # TODO make this look like a quaternion with i,j,k
|
|
return '(' + repr(self.rot) + ', ' + repr(self.det) + ')'
|
|
|
|
def crepr(self):
|
|
'''
|
|
Returns a string that can be used in C code to initialise a qpms_irot3_t
|
|
'''
|
|
return '{' + self.rot.crepr() + ', ' + repr(self.det) + '}'
|
|
|
|
def __mul__(IRot3 self, IRot3 other):
|
|
res = IRot3(CQuat(1,0,0,0), 1)
|
|
res.qd = qpms_irot3_mult(self.qd, other.qd)
|
|
return res
|
|
|
|
def __pow__(IRot3 self, n, _):
|
|
cdef int nint
|
|
if (n % 1 == 0):
|
|
nint = n
|
|
else:
|
|
raise ValueError("The exponent of an IRot3 has to have an integer value.")
|
|
res = IRot3(CQuat(1,0,0,0), 1)
|
|
res.qd = qpms_irot3_pow(self.qd, n)
|
|
return res
|
|
|
|
def isclose(IRot3 self, IRot3 other, rtol=1e-5, atol=1e-8):
|
|
'''
|
|
Checks whether two (improper) rotations are "almost equal".
|
|
Returns always False if the determinants are different.
|
|
'''
|
|
if self.det != other.det:
|
|
return False
|
|
return (self.rot.isclose(other.rot, rtol=rtol, atol=atol)
|
|
# unit quaternions are a double cover of SO(3), i.e.
|
|
# minus the same quaternion represents the same rotation
|
|
or self.rot.isclose(-(other.rot), rtol=rtol, atol=atol)
|
|
)
|
|
|
|
# Several 'named constructors' for convenience
|
|
@staticmethod
|
|
def inversion():
|
|
'''
|
|
Returns an IRot3 object representing the 3D spatial inversion.
|
|
'''
|
|
r = IRot3()
|
|
r.det = -1
|
|
return r
|
|
|
|
@staticmethod
|
|
def zflip():
|
|
'''
|
|
Returns an IRot3 object representing the 3D xy-plane mirror symmetry (z axis sign flip).
|
|
'''
|
|
r = IRot3()
|
|
r.rot = CQuat(0,0,0,1) # π-rotation around z-axis
|
|
r.det = -1 # inversion
|
|
return r
|
|
|
|
@staticmethod
|
|
def yflip():
|
|
'''
|
|
Returns an IRot3 object representing the 3D xz-plane mirror symmetry (y axis sign flip).
|
|
'''
|
|
r = IRot3()
|
|
r.rot = CQuat(0,0,1,0) # π-rotation around y-axis
|
|
r.det = -1 # inversion
|
|
return r
|
|
|
|
@staticmethod
|
|
def xflip():
|
|
'''
|
|
Returns an IRot3 object representing the 3D yz-plane mirror symmetry (x axis sign flip).
|
|
'''
|
|
r = IRot3()
|
|
r.rot = CQuat(0,1,0,0) # π-rotation around x-axis
|
|
r.det = -1 # inversion
|
|
return r
|
|
|
|
@staticmethod
|
|
def zrotN(int n):
|
|
'''
|
|
Returns an IRot3 object representing a \f$ C_n $\f rotation (around the z-axis).
|
|
'''
|
|
r = IRot3()
|
|
r.rot = CQuat(math.cos(math.pi/n),0,0,math.sin(math.pi/n))
|
|
return r
|
|
|
|
@staticmethod
|
|
def identity():
|
|
'''
|
|
An alias for the constructor without arguments; returns identity.
|
|
'''
|
|
return IRot3()
|
|
|
|
def as_uvswf_matrix(IRot3 self, BaseSpec bspec):
|
|
'''
|
|
Returns the uvswf representation of the current transform as a numpy array
|
|
'''
|
|
cdef ssize_t sz = len(bspec)
|
|
cdef np.ndarray m = np.empty((sz, sz), dtype=complex, order='C') # FIXME explicit dtype
|
|
cdef cdouble[:, ::1] view = m
|
|
qpms_irot3_uvswfi_dense(&view[0,0], bspec.rawpointer(), self.qd)
|
|
return m
|
|
|
|
cdef class TMatrixInterpolator:
|
|
'''
|
|
Wrapper over the qpms_tmatrix_interpolator_t structure.
|
|
'''
|
|
#cdef readonly np.ndarray m # Numpy array holding the matrix data
|
|
cdef readonly BaseSpec spec # Here we hold the base spec for the correct reference counting; TODO check if it gets copied
|
|
cdef qpms_tmatrix_t *tmatrices_array
|
|
cdef cdouble *tmdata
|
|
cdef double *freqs
|
|
cdef double *freqs_su
|
|
cdef size_t nfreqs
|
|
cdef qpms_tmatrix_interpolator_t *interp
|
|
|
|
def __cinit__(self, filename, BaseSpec bspec, *args, **kwargs):
|
|
'''Creates a T-matrix interpolator object from a scuff-tmatrix output'''
|
|
self.spec = bspec
|
|
cdef char * cpath = make_c_string(filename)
|
|
if QPMS_SUCCESS != qpms_load_scuff_tmatrix(cpath, self.spec.rawpointer(),
|
|
&(self.nfreqs), &(self.freqs), &(self.freqs_su),
|
|
&(self.tmatrices_array), &(self.tmdata)):
|
|
raise IOError("Could not read T-matrix from %s" % filename)
|
|
if 'symmetrise' in kwargs:
|
|
sym = kwargs['symmetrise']
|
|
if isinstance(sym, FinitePointGroup):
|
|
if QPMS_SUCCESS != qpms_symmetrise_tmdata_finite_group(
|
|
self.tmdata, self.nfreqs, self.spec.rawpointer(),
|
|
(<FinitePointGroup?>sym).rawpointer()):
|
|
raise Exception("This should not happen.")
|
|
atol = kwargs['atol'] if 'atol' in kwargs else 1e-16
|
|
qpms_czero_roundoff_clean(self.tmdata, self.nfreqs * len(bspec)**2, atol)
|
|
else:
|
|
warnings.warn('symmetrise argument type not supported; ignoring.')
|
|
self.interp = qpms_tmatrix_interpolator_create(self.nfreqs,
|
|
self.freqs, self.tmatrices_array, gsl_interp_cspline)
|
|
if not self.interp: raise Exception("Unexpected NULL at interpolator creation.")
|
|
def __call__(self, double freq):
|
|
'''Returns a TMatrix instance, corresponding to a given frequency.'''
|
|
if freq < self.freqs[0] or freq > self.freqs[self.nfreqs-1]:# FIXME here I assume that the input is already sorted
|
|
raise ValueError("input frequency %g is outside the interpolator domain (%g, %g)"
|
|
% (freq, self.freqs[0], self.freqs[self.nfreqs-1]))
|
|
# This is a bit stupid, I should rethink the CTMatrix constuctors
|
|
cdef qpms_tmatrix_t *t = qpms_tmatrix_interpolator_eval(self.interp, freq)
|
|
cdef CTMatrix res = CTMatrix(self.spec, <cdouble[:len(self.spec),:len(self.spec)]>(t[0].m))
|
|
qpms_tmatrix_free(t)
|
|
return res
|
|
def __dealloc__(self):
|
|
qpms_tmatrix_interpolator_free(self.interp)
|
|
free(self.tmatrices_array)
|
|
free(self.tmdata)
|
|
free(self.freqs_su)
|
|
free(self.freqs)
|
|
property freq_interval:
|
|
def __get__(self):
|
|
return [self.freqs[0], self.freqs[self.nfreqs-1]]
|
|
|
|
cdef class CTMatrix: # N.B. there is another type called TMatrix in tmatrices.py!
|
|
'''
|
|
Wrapper over the C qpms_tmatrix_t stucture.
|
|
'''
|
|
cdef readonly np.ndarray m # Numpy array holding the matrix data
|
|
cdef readonly BaseSpec spec # Here we hold the base spec for the correct reference counting; TODO check if it gets copied
|
|
cdef qpms_tmatrix_t t
|
|
|
|
def __cinit__(CTMatrix self, BaseSpec spec, matrix):
|
|
self.spec = spec
|
|
self.t.spec = self.spec.rawpointer();
|
|
# The following will raise an exception if shape is wrong
|
|
self.m = np.array(matrix, dtype=complex, copy=True, order='C').reshape((len(spec), len(spec)))
|
|
#self.m.setflags(write=False) # checkme
|
|
cdef cdouble[:,:] m_memview = self.m
|
|
self.t.m = &(m_memview[0,0])
|
|
self.t.owns_m = False # Memory in self.t.m is "owned" by self.m, not by self.t...
|
|
|
|
cdef qpms_tmatrix_t *rawpointer(CTMatrix self):
|
|
'''Pointer to the qpms_tmatrix_t structure.
|
|
Don't forget to reference the BaseSpec object itself when storing the pointer anywhere!!!
|
|
'''
|
|
return &(self.t)
|
|
property rawpointer:
|
|
def __get__(self):
|
|
return <uintptr_t> &(self.t)
|
|
|
|
# Transparent access to the T-matrix elements.
|
|
def __getitem__(self, key):
|
|
return self.m[key]
|
|
def __setitem__(self, key, value):
|
|
self.m[key] = value
|
|
|
|
def as_ndarray(CTMatrix self):
|
|
''' Returns a copy of the T-matrix as a numpy array.'''
|
|
# Maybe not totally needed after all, as np.array(T[...]) should be equivalent and not longer
|
|
return np.array(self.m, copy=True)
|
|
|
|
cdef char *make_c_string(pythonstring):
|
|
'''
|
|
Copies contents of a python string into a char[]
|
|
(allocating the memory with malloc())
|
|
'''
|
|
bytestring = pythonstring.encode('UTF-8')
|
|
cdef Py_ssize_t n = len(bytestring)
|
|
cdef Py_ssize_t i
|
|
cdef char *s
|
|
s = <char *>malloc(n+1)
|
|
if not s:
|
|
raise MemoryError
|
|
#s[:n] = bytestring # This segfaults; why?
|
|
for i in range(n): s[i] = bytestring[i]
|
|
s[n] = <char>0
|
|
return s
|
|
|
|
def string_c2py(const char* cstring):
|
|
return cstring.decode('UTF-8')
|
|
|
|
cdef class FinitePointGroup:
|
|
'''
|
|
Wrapper over the qpms_finite_group_t structure.
|
|
|
|
TODO more functionality to make it better usable in Python
|
|
(group element class at least)
|
|
'''
|
|
cdef readonly bint owns_data
|
|
cdef qpms_finite_group_t *G
|
|
|
|
def __cinit__(self, info):
|
|
'''Constructs a FinitePointGroup from PointGroupInfo'''
|
|
# TODO maybe I might use a try..finally statement to avoid leaks
|
|
# First, generate all basic data from info
|
|
permlist = info.deterministic_elemlist()
|
|
cdef int order = len(permlist)
|
|
permindices = {perm: i for i, perm in enumerate(permlist)} # 'invert' permlist
|
|
identity = info.permgroup.identity
|
|
# We use calloc to avoid calling free to unitialized pointers
|
|
self.G = <qpms_finite_group_t *>calloc(1,sizeof(qpms_finite_group_t))
|
|
if not self.G: raise MemoryError
|
|
self.G[0].name = make_c_string(info.name)
|
|
self.G[0].order = order
|
|
self.G[0].idi = permindices[identity]
|
|
self.G[0].mt = <qpms_gmi_t *>malloc(sizeof(qpms_gmi_t) * order * order)
|
|
if not self.G[0].mt: raise MemoryError
|
|
for i in range(order):
|
|
for j in range(order):
|
|
self.G[0].mt[i*order + j] = permindices[permlist[i] * permlist[j]]
|
|
self.G[0].invi = <qpms_gmi_t *>malloc(sizeof(qpms_gmi_t) * order)
|
|
if not self.G[0].invi: raise MemoryError
|
|
for i in range(order):
|
|
self.G[0].invi[i] = permindices[permlist[i]**-1]
|
|
self.G[0].ngens = len(info.permgroupgens)
|
|
self.G[0].gens = <qpms_gmi_t *>malloc(sizeof(qpms_gmi_t) * self.G[0].ngens)
|
|
if not self.G[0].gens: raise MemoryError
|
|
for i in range(self.G[0].ngens):
|
|
self.G[0].gens[i] = permindices[info.permgroupgens[i]]
|
|
self.G[0].permrep = <char **>calloc(order, sizeof(char *))
|
|
if not self.G[0].permrep: raise MemoryError
|
|
for i in range(order):
|
|
self.G[0].permrep[i] = make_c_string(str(permlist[i]))
|
|
if not self.G[0].permrep[i]: raise MemoryError
|
|
self.G[0].permrep_nelem = info.permgroup.degree
|
|
if info.rep3d is not None:
|
|
self.G[0].rep3d = <qpms_irot3_t *>malloc(order * sizeof(qpms_irot3_t))
|
|
for i in range(order):
|
|
self.G[0].rep3d[i] = info.rep3d[permlist[i]].qd
|
|
self.G[0].nirreps = len(info.irreps)
|
|
self.G[0].irreps = <qpms_finite_group_irrep_t *>calloc(self.G[0].nirreps, sizeof(qpms_finite_group_irrep_t))
|
|
if not self.G[0].irreps: raise MemoryError
|
|
cdef int dim
|
|
for iri, irname in enumerate(sorted(info.irreps.keys())):
|
|
irrep = info.irreps[irname]
|
|
is1d = isinstance(irrep[identity], (int, float, complex))
|
|
dim = 1 if is1d else irrep[identity].shape[0]
|
|
self.G[0].irreps[iri].dim = dim
|
|
self.G[0].irreps[iri].name = <char *>make_c_string(irname)
|
|
if not self.G[0].irreps[iri].name: raise MemoryError
|
|
self.G[0].irreps[iri].m = <cdouble *>malloc(dim*dim*sizeof(cdouble)*order)
|
|
if not self.G[0].irreps[iri].m: raise MemoryError
|
|
if is1d:
|
|
for i in range(order):
|
|
self.G[0].irreps[iri].m[i] = irrep[permlist[i]]
|
|
else:
|
|
for i in range(order):
|
|
for row in range(dim):
|
|
for col in range(dim):
|
|
self.G[0].irreps[iri].m[i*dim*dim + row*dim + col] = irrep[permlist[i]][row,col]
|
|
self.G[0].elemlabels = <char **> 0 # Elem labels not yet implemented
|
|
self.owns_data = True
|
|
|
|
def __dealloc__(self):
|
|
cdef qpms_gmi_t order
|
|
if self.owns_data:
|
|
if self.G:
|
|
order = self.G[0].order
|
|
free(self.G[0].name)
|
|
free(self.G[0].mt)
|
|
free(self.G[0].invi)
|
|
free(self.G[0].gens)
|
|
if self.G[0].permrep:
|
|
for i in range(order): free(self.G[0].permrep[i])
|
|
free(self.G[0].permrep)
|
|
if self.G[0].elemlabels: # this is not even contructed right now
|
|
for i in range(order): free(self.G[0].elemlabels[i])
|
|
if self.G[0].irreps:
|
|
for iri in range(self.G[0].nirreps):
|
|
free(self.G[0].irreps[iri].name)
|
|
free(self.G[0].irreps[iri].m)
|
|
free(self.G[0].irreps)
|
|
free(self.G)
|
|
self.G = <qpms_finite_group_t *>0
|
|
self.owns_data = False
|
|
|
|
cdef qpms_finite_group_t *rawpointer(self):
|
|
return self.G
|
|
|
|
cdef class FinitePointGroupElement:
|
|
'''TODO'''
|
|
cdef readonly FinitePointGroup G
|
|
cdef readonly qpms_gmi_t gmi
|
|
def __cinit__(self, FinitePointGroup G, qpms_gmi_t gmi):
|
|
self.G = G
|
|
self.gmi = gmi
|
|
|
|
cdef class Particle:
|
|
'''
|
|
Wrapper over the qpms_particle_t structure.
|
|
'''
|
|
cdef qpms_particle_t p
|
|
cdef readonly CTMatrix t # We hold the reference to the T-matrix to ensure correct reference counting
|
|
|
|
def __cinit__(Particle self, pos, CTMatrix t):
|
|
if(len(pos)>=2 and len(pos) < 4):
|
|
self.p.pos.x = pos[0]
|
|
self.p.pos.y = pos[1]
|
|
self.p.pos.z = pos[2] if len(pos)==3 else 0
|
|
else:
|
|
raise ValueError("Position argument has to contain 3 or 2 cartesian coordinates")
|
|
self.t = t
|
|
self.p.tmatrix = self.t.rawpointer()
|
|
|
|
cdef qpms_particle_t *rawpointer(Particle self):
|
|
'''Pointer to the qpms_particle_p structure.
|
|
'''
|
|
return &(self.p)
|
|
property rawpointer:
|
|
def __get__(self):
|
|
return <uintptr_t> &(self.p)
|
|
|
|
cdef qpms_particle_t cval(Particle self):
|
|
'''Provides a copy for assigning in cython code'''
|
|
return self.p
|
|
|
|
property x:
|
|
def __get__(self):
|
|
return self.p.pos.x
|
|
def __set__(self,x):
|
|
self.p.pos.x = x
|
|
property y:
|
|
def __get__(self):
|
|
return self.p.pos.y
|
|
def __set__(self,y):
|
|
self.p.pos.y = y
|
|
property z:
|
|
def __get__(self):
|
|
return self.p.pos.z
|
|
def __set__(self,z):
|
|
self.p.pos.z = z
|
|
property pos:
|
|
def __get__(self):
|
|
return (self.p.pos.x, self.p.pos.y, self.p.pos.z)
|
|
def __set__(self, pos):
|
|
if(len(pos)>=2 and len(pos) < 4):
|
|
self.p.pos.x = pos[0]
|
|
self.p.pos.y = pos[1]
|
|
self.p.pos.z = pos[2] if len(pos)==3 else 0
|
|
else:
|
|
raise ValueError("Position argument has to contain 3 or 2 cartesian coordinates")
|
|
|
|
cdef class ScatteringSystem:
|
|
'''
|
|
Wrapper over the C qpms_scatsys_t structure.
|
|
'''
|
|
cdef list basespecs # Here we keep the references to occuring basespecs
|
|
#cdef list Tmatrices # Here we keep the references to occuring T-matrices
|
|
cdef qpms_scatsys_t *s
|
|
|
|
def __cinit__(self, particles, FinitePointGroup sym):
|
|
'''TODO doc.
|
|
Takes the particles (which have to be a sequence of instances of Particle),
|
|
fills them together with their t-matrices to the "proto-qpms_scatsys_t"
|
|
orig and calls qpms_scatsys_apply_symmetry
|
|
(and then cleans orig)
|
|
'''
|
|
cdef qpms_scatsys_t orig # This should be automatically init'd to 0 (CHECKME)
|
|
cdef qpms_ss_pi_t p_count = len(particles)
|
|
cdef qpms_ss_tmi_t tm_count = 0
|
|
tmindices = dict()
|
|
tmobjs = list()
|
|
self.basespecs=list()
|
|
for p in particles: # find and enumerate unique t-matrices
|
|
if id(p.t) not in tmindices:
|
|
tmindices[id(p.t)] = tm_count
|
|
tmobjs.append(p.t)
|
|
tm_count += 1
|
|
orig.tm_count = tm_count
|
|
orig.p_count = p_count
|
|
for tm in tmobjs: # create references to BaseSpec objects
|
|
self.basespecs.append(tm.spec)
|
|
try:
|
|
orig.tm = <qpms_tmatrix_t **>malloc(orig.tm_count * sizeof(orig.tm[0]))
|
|
if not orig.tm: raise MemoryError
|
|
orig.p = <qpms_particle_tid_t *>malloc(orig.p_count * sizeof(orig.p[0]))
|
|
if not orig.p: raise MemoryError
|
|
for tmi in range(tm_count):
|
|
orig.tm[tmi] = (<CTMatrix?>(tmobjs[tmi])).rawpointer()
|
|
for pi in range(p_count):
|
|
orig.p[pi].pos = (<Particle?>(particles[pi])).cval().pos
|
|
orig.p[pi].tmatrix_id = tmindices[id(particles[pi].t)]
|
|
self.s = qpms_scatsys_apply_symmetry(&orig, sym.rawpointer())
|
|
finally:
|
|
free(orig.tm)
|
|
free(orig.p)
|
|
|
|
def __dealloc__(self):
|
|
qpms_scatsys_free(self.s)
|
|
|
|
def particles_tmi(self):
|
|
r = list()
|
|
cdef qpms_ss_pi_t pi
|
|
for pi in range(self.s[0].p_count):
|
|
r.append(self.s[0].p[pi])
|
|
return r
|
|
|
|
property fecv_size:
|
|
def __get__(self): return self.s[0].fecv_size
|
|
property saecv_sizes:
|
|
def __get__(self):
|
|
return [self.s[0].saecv_sizes[i]
|
|
for i in range(self.s[0].sym[0].nirreps)]
|
|
property irrep_names:
|
|
def __get__(self):
|
|
return [string_c2py(self.s[0].sym[0].irreps[iri].name)
|
|
if (self.s[0].sym[0].irreps[iri].name) else None
|
|
for iri in range(self.s[0].sym[0].nirreps)]
|
|
property nirreps:
|
|
def __get__(self): return self.s[0].sym[0].nirreps
|
|
|
|
def pack_vector(self, vect, iri):
|
|
if len(vect) != self.fecv_size:
|
|
raise ValueError("Length of a full vector has to be %d, not %d"
|
|
% (self.fecv_size, len(vect)))
|
|
vect = np.array(vect, dtype=complex, copy=False, order='C')
|
|
cdef cdouble[::1] vect_view = vect;
|
|
cdef np.ndarray[np.complex_t, ndim=1] target_np = np.empty(
|
|
(self.saecv_sizes[iri],), dtype=complex, order='C')
|
|
cdef cdouble[::1] target_view = target_np
|
|
qpms_scatsys_irrep_pack_vector(&target_view[0], &vect_view[0], self.s, iri)
|
|
return target_np
|
|
def unpack_vector(self, packed, iri):
|
|
if len(packed) != self.saecv_sizes[iri]:
|
|
raise ValueError("Length of %d. irrep-packed vector has to be %d, not %d"
|
|
% (iri, self.saecv_sizes, len(packed)))
|
|
packed = np.array(packed, dtype=complex, copy=False, order='C')
|
|
cdef cdouble[::1] packed_view = packed
|
|
cdef np.ndarray[np.complex_t, ndim=1] target_np = np.empty(
|
|
(self.fecv_size,), dtype=complex)
|
|
cdef cdouble[::1] target_view = target_np
|
|
qpms_scatsys_irrep_unpack_vector(&target_view[0], &packed_view[0],
|
|
self.s, iri, 0)
|
|
return target_np
|
|
def pack_matrix(self, fullmatrix, iri):
|
|
cdef size_t flen = self.s[0].fecv_size
|
|
cdef size_t rlen = self.saecv_sizes[iri]
|
|
fullmatrix = np.array(fullmatrix, dtype=complex, copy=False, order='C')
|
|
if fullmatrix.shape != (flen, flen):
|
|
raise ValueError("Full matrix shape should be (%d,%d), is %s."
|
|
% (flen, flen, repr(fullmatrix.shape)))
|
|
cdef cdouble[:,::1] fullmatrix_view = fullmatrix
|
|
cdef np.ndarray[np.complex_t, ndim=2] target_np = np.empty(
|
|
(rlen, rlen), dtype=complex, order='C')
|
|
cdef cdouble[:,::1] target_view = target_np
|
|
qpms_scatsys_irrep_pack_matrix(&target_view[0][0], &fullmatrix_view[0][0],
|
|
self.s, iri)
|
|
return target_np
|
|
def unpack_matrix(self, packedmatrix, iri):
|
|
cdef size_t flen = self.s[0].fecv_size
|
|
cdef size_t rlen = self.saecv_sizes[iri]
|
|
packedmatrix = np.array(packedmatrix, dtype=complex, copy=False, order='C')
|
|
if packedmatrix.shape != (rlen, rlen):
|
|
raise ValueError("Packed matrix shape should be (%d,%d), is %s."
|
|
% (rlen, rlen, repr(packedmatrix.shape)))
|
|
cdef cdouble[:,::1] packedmatrix_view = packedmatrix
|
|
cdef np.ndarray[np.complex_t, ndim=2] target_np = np.empty(
|
|
(flen, flen), dtype=complex, order='C')
|
|
cdef cdouble[:,::1] target_view = target_np
|
|
qpms_scatsys_irrep_unpack_matrix(&target_view[0][0], &packedmatrix_view[0][0],
|
|
self.s, iri, 0)
|
|
return target_np
|
|
|
|
def modeproblem_matrix_full(self, double k):
|
|
cdef size_t flen = self.s[0].fecv_size
|
|
cdef np.ndarray[np.complex_t, ndim=2] target = np.empty(
|
|
(flen,flen),dtype=complex, order='C')
|
|
cdef cdouble[:,::1] target_view = target
|
|
qpms_scatsys_build_modeproblem_matrix_full(&target_view[0][0], self.s, k)
|
|
return target
|
|
|
|
def modeproblem_matrix_packed(self, double k, qpms_iri_t iri):
|
|
cdef size_t rlen = self.saecv_sizes[iri]
|
|
cdef np.ndarray[np.complex_t, ndim=2] target = np.empty(
|
|
(rlen,rlen),dtype=complex, order='C')
|
|
cdef cdouble[:,::1] target_view = target
|
|
qpms_scatsys_build_modeproblem_matrix_irrep_packed(&target_view[0][0], self.s, iri, k)
|
|
return target
|
|
|
|
def translation_matrix_full(self, double k):
|
|
cdef size_t flen = self.s[0].fecv_size
|
|
cdef np.ndarray[np.complex_t, ndim=2] target = np.empty(
|
|
(flen,flen),dtype=complex, order='C')
|
|
cdef cdouble[:,::1] target_view = target
|
|
qpms_scatsys_build_translation_matrix_full(&target_view[0][0], self.s, k)
|
|
return target
|
|
|
|
def fullvec_psizes(self):
|
|
cdef np.ndarray[int32_t, ndim=1] ar = np.empty((self.s[0].p_count,), dtype=np.int32)
|
|
cdef int32_t[::1] ar_view = ar
|
|
for pi in range(self.s[0].p_count):
|
|
ar_view[pi] = self.s[0].tm[self.s[0].p[pi].tmatrix_id].spec[0].n
|
|
return ar
|
|
|
|
def fullvec_poffsets(self):
|
|
cdef np.ndarray[intptr_t, ndim=1] ar = np.empty((self.s[0].p_count,), dtype=np.intp)
|
|
cdef intptr_t[::1] ar_view = ar
|
|
cdef intptr_t offset = 0
|
|
for pi in range(self.s[0].p_count):
|
|
ar_view[pi] = offset
|
|
offset += self.s[0].tm[self.s[0].p[pi].tmatrix_id].spec[0].n
|
|
return ar
|
|
|
|
def positions(self):
|
|
cdef np.ndarray[np.double_t, ndim=2] ar = np.empty((self.s[0].p_count, 3), dtype=float)
|
|
cdef np.double_t[:,::1] ar_view = ar
|
|
for pi in range(self.s[0].p_count):
|
|
ar_view[pi,0] = self.s[0].p[pi].pos.x
|
|
ar_view[pi,1] = self.s[0].p[pi].pos.y
|
|
ar_view[pi,2] = self.s[0].p[pi].pos.z
|
|
return ar
|
|
|
|
def tlm2uvswfi(t, l, m):
|
|
''' TODO doc
|
|
And TODO this should rather be an ufunc.
|
|
'''
|
|
# Very low-priority TODO: add some types / cythonize
|
|
if isinstance(t, int) and isinstance(l, int) and isinstance(m, int):
|
|
return qpms_tmn2uvswfi(t, m, l)
|
|
elif len(t) == len(l) and len(t) == len(m):
|
|
u = list()
|
|
for i in range(len(t)):
|
|
if not (t[i] % 1 == 0 and l[i] % 1 == 0 and m[i] % 1 == 0): # maybe not the best check possible, though
|
|
raise ValueError # TODO error message
|
|
u.append(qpms_tmn2uvswfi(t[i],m[i],l[i]))
|
|
return u
|
|
else:
|
|
print(len(t), len(l), len(m))
|
|
raise ValueError("Lengths of the t,l,m arrays must be equal, but they are %d, %d, %d."
|
|
% (len(t), len(l), len(m)))
|
|
|
|
|
|
def uvswfi2tlm(u):
|
|
''' TODO doc
|
|
and TODO this should rather be an ufunc.
|
|
'''
|
|
cdef qpms_vswf_type_t t
|
|
cdef qpms_l_t l
|
|
cdef qpms_m_t m
|
|
cdef size_t i
|
|
if isinstance(u, (int, np.ulonglong)):
|
|
if (qpms_uvswfi2tmn(u, &t, &m, &l) != QPMS_SUCCESS):
|
|
raise ValueError("Invalid uvswf index")
|
|
return (t, l, m)
|
|
else:
|
|
ta = list()
|
|
la = list()
|
|
ma = list()
|
|
for i in range(len(u)):
|
|
if (qpms_uvswfi2tmn(u[i], &t, &m, &l) != QPMS_SUCCESS):
|
|
raise ValueError("Invalid uvswf index")
|
|
ta.append(t)
|
|
la.append(l)
|
|
ma.append(m)
|
|
return (ta, la, ma)
|
|
|
|
|
|
|