/usr/lib/python3/dist-packages/pint/util.py is in python3-pint 0.6-1ubuntu1.
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"""
pint.util
~~~~~~~~~
Miscellaneous functions for pint.
:copyright: 2013 by Pint Authors, see AUTHORS for more details.
:license: BSD, see LICENSE for more details.
"""
from __future__ import division, unicode_literals, print_function, absolute_import
import re
import operator
from numbers import Number
from fractions import Fraction
import logging
from token import STRING, NAME, OP
from tokenize import untokenize
from .compat import string_types, tokenizer, lru_cache, NullHandler, maketrans
logger = logging.getLogger(__name__)
logger.addHandler(NullHandler())
def matrix_to_string(matrix, row_headers=None, col_headers=None, fmtfun=lambda x: str(int(x))):
"""Takes a 2D matrix (as nested list) and returns a string.
"""
ret = []
if col_headers:
ret.append(('\t' if row_headers else '') + '\t'.join(col_headers))
if row_headers:
ret += [rh + '\t' + '\t'.join(fmtfun(f) for f in row)
for rh, row in zip(row_headers, matrix)]
else:
ret += ['\t'.join(fmtfun(f) for f in row)
for row in matrix]
return '\n'.join(ret)
def transpose(matrix):
"""Takes a 2D matrix (as nested list) and returns the transposed version.
"""
return [list(val) for val in zip(*matrix)]
def column_echelon_form(matrix, ntype=Fraction, transpose_result=False):
"""Calculates the column echelon form using Gaussian elimination.
:param matrix: a 2D matrix as nested list.
:param ntype: the numerical type to use in the calculation.
:param transpose_result: indicates if the returned matrix should be transposed.
:return: column echelon form, transformed identity matrix, swapped rows
"""
lead = 0
M = transpose(matrix)
_transpose = transpose if transpose_result else lambda x: x
rows, cols = len(M), len(M[0])
new_M = []
for row in M:
r = []
for x in row:
if isinstance(x, float):
x = ntype.from_float(x)
else:
x = ntype(x)
r.append(x)
new_M.append(r)
M = new_M
# M = [[ntype(x) for x in row] for row in M]
I = [[ntype(1) if n == nc else ntype(0) for nc in range(rows)] for n in range(rows)]
swapped = []
for r in range(rows):
if lead >= cols:
return _transpose(M), _transpose(I), swapped
i = r
while M[i][lead] == 0:
i += 1
if i != rows:
continue
i = r
lead += 1
if cols == lead:
return _transpose(M), _transpose(I), swapped
M[i], M[r] = M[r], M[i]
I[i], I[r] = I[r], I[i]
swapped.append(i)
lv = M[r][lead]
M[r] = [mrx / lv for mrx in M[r]]
I[r] = [mrx / lv for mrx in I[r]]
for i in range(rows):
if i == r:
continue
lv = M[i][lead]
M[i] = [iv - lv*rv for rv, iv in zip(M[r], M[i])]
I[i] = [iv - lv*rv for rv, iv in zip(I[r], I[i])]
lead += 1
return _transpose(M), _transpose(I), swapped
def pi_theorem(quantities, registry=None):
"""Builds dimensionless quantities using the Buckingham π theorem
:param quantities: mapping between variable name and units
:type quantities: dict
:return: a list of dimensionless quantities expressed as dicts
"""
# Preprocess input and build the dimensionality Matrix
quant = []
dimensions = set()
if registry is None:
getdim = lambda x: x
else:
getdim = registry.get_dimensionality
for name, value in quantities.items():
if isinstance(value, string_types):
value = ParserHelper.from_string(value)
if isinstance(value, dict):
dims = getdim(value)
elif not hasattr(value, 'dimensionality'):
dims = getdim(value)
else:
dims = value.dimensionality
if not registry and any(not key.startswith('[') for key in dims):
logger.warning('A non dimension was found and a registry was not provided. '
'Assuming that it is a dimension name: {0}.'.format(dims))
quant.append((name, dims))
dimensions = dimensions.union(dims.keys())
dimensions = list(dimensions)
# Calculate dimensionless quantities
M = [[dimensionality[dimension] for name, dimensionality in quant]
for dimension in dimensions]
M, identity, pivot = column_echelon_form(M, transpose_result=False)
# Collect results
# Make all numbers integers and minimize the number of negative exponents.
# Remove zeros
results = []
for rowm, rowi in zip(M, identity):
if any(el != 0 for el in rowm):
continue
max_den = max(f.denominator for f in rowi)
neg = -1 if sum(f < 0 for f in rowi) > sum(f > 0 for f in rowi) else 1
results.append(dict((q[0], neg * f.numerator * max_den / f.denominator)
for q, f in zip(quant, rowi) if f.numerator != 0))
return results
def solve_dependencies(dependencies):
"""Solve a dependency graph.
:param dependencies: dependency dictionary. For each key, the value is
an iterable indicating its dependencies.
:return: list of sets, each containing keys of independents tasks dependent
only of the previous tasks in the list.
"""
d = dict((key, set(dependencies[key])) for key in dependencies)
r = []
while d:
# values not in keys (items without dep)
t = set(i for v in d.values() for i in v) - set(d.keys())
# and keys without value (items without dep)
t.update(k for k, v in d.items() if not v)
# can be done right away
r.append(t)
# and cleaned up
d = dict(((k, v - t) for k, v in d.items() if v))
return r
def find_shortest_path(graph, start, end, path=None):
path = (path or []) + [start]
if start == end:
return path
if not start in graph:
return None
shortest = None
for node in graph[start]:
if node not in path:
newpath = find_shortest_path(graph, node, end, path)
if newpath:
if not shortest or len(newpath) < len(shortest):
shortest = newpath
return shortest
def find_connected_nodes(graph, start, visited=None):
if not start in graph:
return None
visited = (visited or set())
visited.add(start)
for node in graph[start]:
if node not in visited:
find_connected_nodes(graph, node, visited)
return visited
class ParserHelper(dict):
"""The ParserHelper stores in place the product of variables and
their respective exponent and implements the corresponding operations.
"""
__slots__ = ('scale', )
def __init__(self, scale=1, *args, **kwargs):
self.scale = scale
dict.__init__(self, *args, **kwargs)
@classmethod
def from_word(cls, input_word):
"""Creates a ParserHelper object with a single variable with exponent one.
Equivalent to: ParserHelper({'word': 1})
"""
ret = cls()
ret.add(input_word, 1)
return ret
@classmethod
def from_string(cls, input_string):
return cls._from_string(input_string).copy()
@classmethod
@lru_cache()
def _from_string(cls, input_string):
"""Parse linear expression mathematical units and return a quantity object.
"""
if not input_string:
return cls()
input_string = string_preprocessor(input_string)
if '[' in input_string:
input_string = input_string.replace('[', '__obra__').replace(']', '__cbra__')
reps = True
else:
reps = False
gen = tokenizer(input_string)
result = []
for toknum, tokval, _, _, _ in gen:
if toknum == NAME:
if not tokval:
continue
result.extend([
(NAME, 'L_'),
(OP, '('),
(STRING, '"' + tokval + '"'),
(OP, ')')
])
else:
result.append((toknum, tokval))
ret = eval(untokenize(result),
{'__builtins__': None},
{'L_': cls.from_word})
if isinstance(ret, Number):
return ParserHelper(ret)
if not reps:
return ret
return ParserHelper(ret.scale,
dict((key.replace('__obra__', '[').replace('__cbra__', ']'), value)
for key, value in ret.items()))
def copy(self):
return ParserHelper(scale=self.scale, **self)
def __missing__(self, key):
return 0.0
def __eq__(self, other):
if isinstance(other, self.__class__):
return self.scale == other.scale and super(ParserHelper, self).__eq__(other)
elif isinstance(other, dict):
return self.scale == 1 and super(ParserHelper, self).__eq__(other)
elif isinstance(other, string_types):
return self == ParserHelper.from_string(other)
elif isinstance(other, Number):
return self.scale == other and not len(self)
else:
return False
def __ne__(self, other):
return not self.__eq__(other)
def add(self, key, value):
newval = self.__getitem__(key) + value
if newval:
self.__setitem__(key, newval)
else:
del self[key]
def operate(self, items, op=operator.iadd, cleanup=True):
for key, value in items:
self[key] = op(self[key], value)
if cleanup:
keys = [key for key, value in self.items() if value == 0]
for key in keys:
del self[key]
def __str__(self):
tmp = '{%s}' % ', '.join(["'{0}': {1}".format(key, value) for key, value in sorted(self.items())])
return '{0} {1}'.format(self.scale, tmp)
def __repr__(self):
tmp = '{%s}' % ', '.join(["'{0}': {1}".format(key, value) for key, value in sorted(self.items())])
return '<ParserHelper({0}, {1})>'.format(self.scale, tmp)
def __mul__(self, other):
if isinstance(other, string_types):
self.add(other, 1)
elif isinstance(other, Number):
self.scale *= other
elif isinstance(other, self.__class__):
self.scale *= other.scale
self.operate(other.items())
else:
self.operate(other.items())
return self
__imul__ = __mul__
__rmul__ = __mul__
def __pow__(self, other):
self.scale **= other
for key in self.keys():
self[key] *= other
return self
__ipow__ = __pow__
def __truediv__(self, other):
if isinstance(other, string_types):
self.add(other, -1)
elif isinstance(other, Number):
self.scale /= other
elif isinstance(other, self.__class__):
self.scale /= other.scale
self.operate(other.items(), operator.sub)
else:
self.operate(other.items(), operator.sub)
return self
__itruediv__ = __truediv__
__floordiv__ = __truediv__
def __rtruediv__(self, other):
self.__pow__(-1)
if isinstance(other, string_types):
self.add(other, 1)
elif isinstance(other, Number):
self.scale *= other
elif isinstance(other, self.__class__):
self.scale *= other.scale
self.operate(other.items(), operator.add)
else:
self.operate(other.items(), operator.add)
return self
#: List of regex substitution pairs.
_subs_re = [(r"([\w\.\-\+\*\\\^])\s+", r"\1 "), # merge multiple spaces
(r"({0}) squared", r"\1**2"), # Handle square and cube
(r"({0}) cubed", r"\1**3"),
(r"cubic ({0})", r"\1**3"),
(r"square ({0})", r"\1**2"),
(r"sq ({0})", r"\1**2"),
(r"\b([0-9]+\.?[0-9]*)(?=[e|E][a-zA-Z]|[a-df-zA-DF-Z])", r"\1*"), # Handle numberLetter for multiplication
(r"([\w\.\-])\s+(?=\w)", r"\1*"), # Handle space for multiplication
]
#: Compiles the regex and replace {0} by a regex that matches an identifier.
_subs_re = [(re.compile(a.format(r"[_a-zA-Z][_a-zA-Z0-9]*")), b) for a, b in _subs_re]
_pretty_table = maketrans('⁰¹²³⁴⁵⁶⁷⁸⁹·⁻', '0123456789*-')
_pretty_exp_re = re.compile(r"⁻?[⁰¹²³⁴⁵⁶⁷⁸⁹]+(?:\.[⁰¹²³⁴⁵⁶⁷⁸⁹]*)?")
def string_preprocessor(input_string):
input_string = input_string.replace(",", "")
input_string = input_string.replace(" per ", "/")
for a, b in _subs_re:
input_string = a.sub(b, input_string)
# Replace pretty format characters
for pretty_exp in _pretty_exp_re.findall(input_string):
exp = '**' + pretty_exp.translate(_pretty_table)
input_string = input_string.replace(pretty_exp, exp)
input_string = input_string.translate(_pretty_table)
# Handle caret exponentiation
input_string = input_string.replace("^", "**")
return input_string
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