import operator from cpython.object cimport ( Py_EQ, Py_GE, Py_GT, Py_LE, Py_LT, Py_NE, PyObject_RichCompareBool, ) import cython from cython import Py_ssize_t import numpy as np from numpy cimport ( import_array, ndarray, uint8_t, ) import_array() from pandas._libs.missing cimport checknull from pandas._libs.util cimport is_nan @cython.wraparound(False) @cython.boundscheck(False) def scalar_compare(object[:] values, object val, object op) -> ndarray: """ Compare each element of `values` array with the scalar `val`, with the comparison operation described by `op`. Parameters ---------- values : ndarray[object] val : object op : {operator.eq, operator.ne, operator.le, operator.lt, operator.ge, operator.gt} Returns ------- result : ndarray[bool] """ cdef: Py_ssize_t i, n = len(values) ndarray[uint8_t, cast=True] result bint isnull_val int flag object x if op is operator.lt: flag = Py_LT elif op is operator.le: flag = Py_LE elif op is operator.gt: flag = Py_GT elif op is operator.ge: flag = Py_GE elif op is operator.eq: flag = Py_EQ elif op is operator.ne: flag = Py_NE else: raise ValueError('Unrecognized operator') result = np.empty(n, dtype=bool).view(np.uint8) isnull_val = checknull(val) if flag == Py_NE: for i in range(n): x = values[i] if checknull(x): result[i] = True elif isnull_val: result[i] = True else: try: result[i] = PyObject_RichCompareBool(x, val, flag) except TypeError: result[i] = True elif flag == Py_EQ: for i in range(n): x = values[i] if checknull(x): result[i] = False elif isnull_val: result[i] = False else: try: result[i] = PyObject_RichCompareBool(x, val, flag) except TypeError: result[i] = False else: for i in range(n): x = values[i] if checknull(x): result[i] = False elif isnull_val: result[i] = False else: result[i] = PyObject_RichCompareBool(x, val, flag) return result.view(bool) @cython.wraparound(False) @cython.boundscheck(False) def vec_compare(ndarray[object] left, ndarray[object] right, object op) -> ndarray: """ Compare the elements of `left` with the elements of `right` pointwise, with the comparison operation described by `op`. Parameters ---------- left : ndarray[object] right : ndarray[object] op : {operator.eq, operator.ne, operator.le, operator.lt, operator.ge, operator.gt} Returns ------- result : ndarray[bool] """ cdef: Py_ssize_t i, n = len(left) ndarray[uint8_t, cast=True] result int flag if n != len(right): raise ValueError(f'Arrays were different lengths: {n} vs {len(right)}') if op is operator.lt: flag = Py_LT elif op is operator.le: flag = Py_LE elif op is operator.gt: flag = Py_GT elif op is operator.ge: flag = Py_GE elif op is operator.eq: flag = Py_EQ elif op is operator.ne: flag = Py_NE else: raise ValueError('Unrecognized operator') result = np.empty(n, dtype=bool).view(np.uint8) if flag == Py_NE: for i in range(n): x = left[i] y = right[i] if checknull(x) or checknull(y): result[i] = True else: result[i] = PyObject_RichCompareBool(x, y, flag) else: for i in range(n): x = left[i] y = right[i] if checknull(x) or checknull(y): result[i] = False else: result[i] = PyObject_RichCompareBool(x, y, flag) return result.view(bool) @cython.wraparound(False) @cython.boundscheck(False) def scalar_binop(object[:] values, object val, object op) -> ndarray: """ Apply the given binary operator `op` between each element of the array `values` and the scalar `val`. Parameters ---------- values : ndarray[object] val : object op : binary operator Returns ------- result : ndarray[object] """ cdef: Py_ssize_t i, n = len(values) object[:] result object x result = np.empty(n, dtype=object) if val is None or is_nan(val): result[:] = val return result.base # `.base` to access underlying np.ndarray for i in range(n): x = values[i] if x is None or is_nan(x): result[i] = x else: result[i] = op(x, val) return maybe_convert_bool(result.base)[0] @cython.wraparound(False) @cython.boundscheck(False) def vec_binop(object[:] left, object[:] right, object op) -> ndarray: """ Apply the given binary operator `op` pointwise to the elements of arrays `left` and `right`. Parameters ---------- left : ndarray[object] right : ndarray[object] op : binary operator Returns ------- result : ndarray[object] """ cdef: Py_ssize_t i, n = len(left) object[:] result if n != len(right): raise ValueError(f'Arrays were different lengths: {n} vs {len(right)}') result = np.empty(n, dtype=object) for i in range(n): x = left[i] y = right[i] try: result[i] = op(x, y) except TypeError: if x is None or is_nan(x): result[i] = x elif y is None or is_nan(y): result[i] = y else: raise return maybe_convert_bool(result.base)[0] # `.base` to access np.ndarray def maybe_convert_bool(ndarray[object] arr, true_values=None, false_values=None, convert_to_masked_nullable=False ) -> tuple[np.ndarray, np.ndarray | None]: cdef: Py_ssize_t i, n ndarray[uint8_t] result ndarray[uint8_t] mask object val set true_vals, false_vals bint has_na = False n = len(arr) result = np.empty(n, dtype=np.uint8) mask = np.zeros(n, dtype=np.uint8) # the defaults true_vals = {'True', 'TRUE', 'true'} false_vals = {'False', 'FALSE', 'false'} if true_values is not None: true_vals = true_vals | set(true_values) if false_values is not None: false_vals = false_vals | set(false_values) for i in range(n): val = arr[i] if isinstance(val, bool): if val is True: result[i] = 1 else: result[i] = 0 elif val in true_vals: result[i] = 1 elif val in false_vals: result[i] = 0 elif is_nan(val): mask[i] = 1 result[i] = 0 # Value here doesn't matter, will be replaced w/ nan has_na = True else: return (arr, None) if has_na: if convert_to_masked_nullable: return (result.view(np.bool_), mask.view(np.bool_)) else: arr = result.view(np.bool_).astype(object) np.putmask(arr, mask, np.nan) return (arr, None) else: return (result.view(np.bool_), None)