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data_structure.py
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data_structure.py
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# ##### BEGIN GPL LICENSE BLOCK #####
#
# This program is free software; you can redistribute it and/or
# modify it under the terms of the GNU General Public License
# as published by the Free Software Foundation; either version 2
# of the License, or (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program; if not, write to the Free Software Foundation,
# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
#
# ##### END GPL LICENSE BLOCK #####
from contextlib import contextmanager
from collections import defaultdict
from functools import wraps
from math import radians, ceil
import itertools
import copy
from itertools import zip_longest, chain, cycle, islice
import bpy
from mathutils import Vector, Matrix
from numpy import (
array as np_array,
newaxis as np_newaxis,
ndarray,
ones as np_ones,
arange as np_arange,
repeat as np_repeat,
concatenate as np_concatenate,
tile as np_tile,
float64,
int32, int64)
from sverchok.utils.sv_logging import sv_logger
import numpy as np
RELOAD_EVENT = False
cache_viewer_baker = {}
sentinel = object()
#####################################################
################### cache magic #####################
#####################################################
#handle for object in node and neuro node
temp_handle = {}
def handle_delete(handle):
if handle in temp_handle:
del temp_handle[handle]
def handle_read(handle):
if not (handle in temp_handle):
return (False, [])
return (True, temp_handle[handle]['prop'])
def handle_write(handle, prop):
handle_delete(handle)
temp_handle[handle] = {"prop" : prop}
def handle_check(handle, prop):
if handle in handle_check and \
prop == handle_check[handle]['prop']:
return True
return False
#####################################################
################ list matching magic ################
#####################################################
def repeat_last(lst):
"""
creates an infinite iterator the first each element in lst
and then keep repeating the last element,
use with terminating input
"""
last = [lst[-1]] if len(lst) else [] # len(lst) in case of numpy arrays
yield from chain(lst, cycle(last))
def fixed_iter(data, iter_number, fill_value=0):
"""
Creates iterator for given data which will be yielded iter_number times
If data is shorter then iter_number last element will be cycled
If data is empty [fill_value] list will be used instead
"""
last_index = -1
for i, item in zip(range(iter_number), data):
yield item
last_index = i
fill_value = item
if last_index + 1 < iter_number:
for i, item in zip(range(iter_number - (last_index + 1)), cycle([fill_value])):
yield item
def flat_iter(data):
"""[1, [2, 3, [4]], 5] -> 1, 2, 3, 4, 5 """
if isinstance(data, str):
yield data
return
try:
for v in data:
yield from flat_iter(v)
except TypeError:
yield data
def match_long_repeat(lsts):
"""return matched list, using the last value to fill lists as needed
longest list matching [[1,2,3,4,5], [10,11]] -> [[1,2,3,4,5], [10,11,11,11,11]]
lists passed into this function are not modified, it produces non-deep copies and extends those.
"""
max_l = 0
tmp = []
for l in lsts:
if not hasattr(l, '__len__'):
raise TypeError(f"Cannot perform data matching: input of type {type(l)} is not a list or tuple, but an atomic object")
max_l = max(max_l, len(l))
for l in lsts:
if len(l) == max_l:
tmp.append(l)
else:
tmp.append(repeat_last(l))
return list(map(list, zip(*zip(*tmp))))
def zip_long_repeat(*lists):
objects = match_long_repeat(lists)
return zip(*objects)
def match_long_cycle(lsts):
"""return matched list, cycling the shorter lists
longest list matching, cycle [[1,2,3,4,5] ,[10,11]] -> [[1,2,3,4,5] ,[10,11,10,11,10]]
"""
max_l = 0
tmp = []
for l in lsts:
max_l = max(max_l, len(l))
for l in lsts:
if len(l) == max_l:
tmp.append(l)
else:
tmp.append(itertools.cycle(l))
return list(map(list, zip(*zip(*tmp))))
# when you intent to use length of first list to control WHILE loop duration
# and you do not want to change the length of the first list, but you want the second list
# length to by not less than the length of the first
def second_as_first_cycle(F, S):
if len(F) > len(S):
return list(map(list, zip(*zip(*[F, itertools.cycle(S)]))))[1]
else:
return S
def match_cross(lsts):
""" return cross matched lists
[[1,2], [5,6,7]] -> [[1,1,1,2,2,2], [5,6,7,5,6,7]]
"""
return list(map(list, zip(*itertools.product(*lsts))))
def match_cross2(lsts):
""" return cross matched lists
[[1,2], [5,6,7]] ->[[1, 2, 1, 2, 1, 2], [5, 5, 6, 6, 7, 7]]
"""
return list(reversed(list(map(list, zip(*itertools.product(*reversed(lsts)))))))
# Shortest list decides output length [[1,2,3,4,5], [10,11]] -> [[1,2], [10, 11]]
def match_short(lsts):
"""return lists of equal length using the Shortest list to decides length
Shortest list decides output length [[1,2,3,4,5], [10,11]] -> [[1,2], [10, 11]]
"""
return list(map(list, zip(*zip(*lsts))))
def fullList(l, count):
"""extends list l so len is at least count if needed with the
last element of l"""
n = len(l)
if n == count:
return
d = count - n
if d > 0:
l.extend([l[-1] for a in range(d)])
return
def fullList_np(l, count):
"""extends list l so len is at least count if needed with the
last element of l"""
n = len(l)
if n == count:
return
d = count - n
if d > 0:
try:
l.extend([l[-1] for a in range(d)])
except:
l = numpy_full_list(l, n)
else:
l = l[:count]
def fullList_deep_copy(l, count):
"""the same that full list function but
it have correct work with objects such as lists."""
d = count - len(l)
if d > 0:
l.extend([copy.deepcopy(l[-1]) for _ in range(d)])
return
def cycle_for_length(lst, count):
result = []
n = len(lst)
for i in range(count):
result.append(lst[i % n])
return result
def repeat_last_for_length(lst, count, deepcopy=False):
"""
Repeat last item of the list enough times
for result's length to be equal to `count`.
repeat_last_for_length(None, n) = None
repeat_last_for_length([], n) = []
repeat_last_for_length([1,2], 4) = [1, 2, 2, 2]
"""
if not lst:
return lst
if len(lst) >= count:
return lst[:count]
n = len(lst)
x = lst[-1]
result = lst[:]
if deepcopy:
for i in range(count - n):
result.append(copy.deepcopy(x))
else:
for i in range(count - n):
result.append(x)
return result
def cycle_for_length(lst, count):
return list(islice(cycle(lst), count))
def sv_zip(*iterables):
"""zip('ABCD', 'xy') --> Ax By
like standard zip but list instead of tuple
"""
iterators = [iter(it) for it in iterables]
sentinel = object() # use internal sentinel
while iterators:
result = []
for it in iterators:
elem = next(it, sentinel)
if elem is sentinel:
return
result.append(elem)
yield result
list_match_modes = [
("SHORT", "Short", "Match shortest List", 1),
("CYCLE", "Cycle", "Match longest List by cycling", 2),
("REPEAT", "Repeat Last", "Match longest List by repeating last item", 3),
("XREF", "X-Ref", "Cross reference (fast cycle of long)", 4),
("XREF2", "X-Ref 2", "Cross reference (fast cycle of short)", 5),
]
list_match_func = {
"SHORT": match_short,
"CYCLE": match_long_cycle,
"REPEAT": match_long_repeat,
"XREF": match_cross,
"XREF2": match_cross2
}
numpy_list_match_modes = list_match_modes[:3]
# numpy_list_match_modes = [
# ("SHORT", "Match Short", "Match shortest List", 1),
# ("CYCLE", "Cycle", "Match longest List by cycling", 2),
# ("REPEAT", "Repeat Last", "Match longest List by repeating last item", 3),
# ]
def numpy_full_list(array, desired_length):
'''retuns array with desired length by repeating last item'''
if not isinstance(array, ndarray):
array = np_array(array)
length_diff = desired_length - array.shape[0]
if length_diff > 0:
new_part = np_repeat(array[np_newaxis, -1], length_diff, axis=0)
return np_concatenate((array, new_part))[:desired_length]
return array[:desired_length]
def numpy_full_list_cycle(array, desired_length):
'''retuns array with desired length by cycling'''
length_diff = desired_length - array.shape[0]
if length_diff > 0:
if length_diff < array.shape[0]:
return np_concatenate((array, array[:length_diff]))
new_part = np_repeat(array, ceil(length_diff / array.shape[0]), axis=0)
if len(array.shape) > 1:
shape = (ceil(length_diff / array.shape[0]), 1)
else:
shape = ceil(length_diff / array.shape[0])
new_part = np_tile(array, shape)
return np_concatenate((array, new_part[:length_diff]))
return array[:desired_length]
numpy_full_list_func = {
"SHORT": lambda x,l: x[:l],
"CYCLE": numpy_full_list_cycle,
"REPEAT": numpy_full_list,
}
def numpy_match_long_repeat(list_of_arrays):
'''match numpy arrays length by repeating last one'''
out = []
maxl = 0
for array in list_of_arrays:
maxl = max(maxl, array.shape[0])
for array in list_of_arrays:
length_diff = maxl - array.shape[0]
if length_diff > 0:
new_part = np_repeat(array[np_newaxis, -1], length_diff, axis=0)
array = np_concatenate((array, new_part))
out.append(array)
return out
def numpy_match_long_cycle(list_of_arrays):
'''match numpy arrays length by cycling over the array'''
out = []
maxl = 0
for array in list_of_arrays:
maxl = max(maxl, array.shape[0])
for array in list_of_arrays:
length_diff = maxl - array.shape[0]
if length_diff > 0:
if length_diff < array.shape[0]:
array = np_concatenate((array, array[:length_diff]))
else:
new_part = np_repeat(array, ceil(length_diff / array.shape[0]), axis=0)
if len(array.shape) > 1:
shape = (ceil(length_diff / array.shape[0]), 1)
else:
shape = ceil(length_diff / array.shape[0])
new_part = np_tile(array, shape)
array = np_concatenate((array, new_part[:length_diff]))
out.append(array)
return out
def numpy_match_short(list_of_arrays):
'''match numpy arrays length by cutting the longer arrays'''
out = []
minl = list_of_arrays[0].shape[0]
for array in list_of_arrays:
minl = min(minl, array.shape[0])
for array in list_of_arrays:
length_diff = array.shape[0] - minl
if length_diff > 0:
array = array[:minl]
out.append(array)
return out
numpy_list_match_func = {
"SHORT": numpy_match_short,
"CYCLE": numpy_match_long_cycle,
"REPEAT": numpy_match_long_repeat,
}
def make_repeaters(lists):
chain = itertools.chain
repeat = itertools.repeat
out =[]
for l in lists:
out.append(chain(l, repeat(l[-1])))
return out
def make_cyclers(lists):
cycle = itertools.cycle
out =[]
for l in lists:
out.append(cycle(l))
return out
iter_list_match_func = {
"SHORT": lambda x: x,
"CYCLE": make_cyclers,
"REPEAT": make_repeaters,
}
#####################################################
################# list levels magic #################
#####################################################
# working with nesting levels
# define data floor
# NOTE, these function cannot possibly work in all scenarios, use with care
def dataCorrect(data, nominal_dept=2):
"""data from nesting to standard: TO container( objects( lists( floats, ), ), )
"""
dept = levelsOflist(data)
output = []
if not dept: # for empty lists
return []
if dept < 2:
return data #[dept, data]
else:
output = data_standard(data, dept, nominal_dept)
return output
def dataCorrect_np(data, nominal_dept=2):
"""data from nesting to standard: TO container( objects( lists( floats, ), ), )
"""
dept = levels_of_list_or_np(data)
output = []
if not dept: # for empty lists
return []
if dept < 2:
return data #[dept, data]
else:
output = data_standard(data, dept, nominal_dept)
return output
def dataSpoil(data, dept):
"""from standard data to initial levels: to nested lists
container( objects( lists( nested_lists( floats, ), ), ), ) это невозможно!
"""
__doc__ = 'preparing and making spoil'
def Spoil(dat, dep):
__doc__ = 'making spoil'
out = []
if dep:
for d in dat:
out.append([Spoil(d, dep-1)])
else:
out = dat
return out
lol = levelsOflist(data)
if dept > lol:
out = Spoil(data, dept-lol)
else:
out = data
return out
def data_standard(data, dept, nominal_dept):
"""data from nesting to standard: TO container( objects( lists( floats, ), ), )"""
deptl = dept - 1
output = []
for object in data:
if deptl >= nominal_dept:
output.extend(data_standard(object, deptl, nominal_dept))
else:
output.append(data)
return output
return output
def levelsOflist(lst):
"""calc list nesting only in countainment level integer"""
level = 1
for n in lst:
if n and isinstance(n, (list, tuple)):
level += levelsOflist(n)
return level
return 0
def levels_of_list_or_np(lst):
"""calc list nesting only in countainment level integer"""
level = 1
for n in lst:
if isinstance(n, (list, tuple)):
level += levels_of_list_or_np(n)
elif isinstance(n, (ndarray)):
level += len(n.shape)
return level
return 0
NUMERIC_DATA_TYPES = (float, int, float64, int32, int64)
SIMPLE_DATA_TYPES = (float, int, float64, int32, int64, str, Matrix)
def get_data_nesting_level(data, data_types=SIMPLE_DATA_TYPES, search_first_data=False):
"""
data: number, or list of numbers, or list of lists, etc.
data_types: list or tuple of types.
Detect nesting level of actual data.
"Actual" data is detected by belonging to one of data_types.
This method searches only for first instance of "actual data",
so it does not support cases when different elements of source
list have different nesting.
Returns integer.
Raises an exception if at some point it encounters element
which is not a tuple, list, or one of data_types.
get_data_nesting_level(1) == 0
get_data_nesting_level([]) == 1
get_data_nesting_level([1]) == 1
get_data_nesting_level([[(1,2,3)]]) == 3
"""
def helper(data, recursion_depth):
""" Needed only for better error reporting. """
if isinstance(data, data_types):
return (0, 0)
elif isinstance(data, (list, tuple, ndarray)):
if len(data) == 0:
return (1, -1)
else:
if search_first_data==False:
res = helper(data[0], recursion_depth+1)
else:
for I, data_I in enumerate(data):
res = helper(data_I, recursion_depth+1)
if res[1]==0:
return (res[0]+1, res[1] )
#return helper(data[0], recursion_depth+1) + 1
return (res[0]+ 1, res[1] )
elif data is None:
raise TypeError("get_data_nesting_level: encountered None at nesting level {}".format(recursion_depth))
else:
#unknown class. Return 0 level
return (0, -1)
res = helper(data, 0)
return res[0]
def ensure_nesting_level(data, target_level, data_types=SIMPLE_DATA_TYPES, input_name=None):
"""
data: number, or list of numbers, or list of lists, etc.
target_level: data nesting level required for further processing.
data_types: list or tuple of types.
input_name: name of input socket data was taken from. Optional. If specified,
used for error reporting.
Wraps data in so many [] as required to achieve target nesting level.
Raises an exception, if data already has too high nesting level.
ensure_nesting_level(17, 0) == 17
ensure_nesting_level(17, 1) == [17]
ensure_nesting_level([17], 1) == [17]
ensure_nesting_level([17], 2) == [[17]]
ensure_nesting_level([(1,2,3)], 3) == [[(1,2,3)]]
ensure_nesting_level([[[17]]], 1) => exception
"""
current_level = get_data_nesting_level(data, data_types)
if current_level > target_level:
if input_name is None:
raise TypeError("ensure_nesting_level: input data already has nesting level of {}. Required level was {}.".format(current_level, target_level))
else:
raise TypeError("Input data in socket {} already has nesting level of {}. Required level was {}.".format(input_name, current_level, target_level))
result = data
for i in range(target_level - current_level):
result = [result]
return result
def ensure_min_nesting(data, target_level, data_types=SIMPLE_DATA_TYPES, input_name=None):
"""
data: number, or list of numbers, or list of lists, etc.
target_level: minimum data nesting level required for further processing.
data_types: list or tuple of types.
input_name: name of input socket data was taken from. Optional. If specified,
used for error reporting.
Wraps data in so many [] as required to achieve target nesting level.
If data already has too high nesting level the same data will be returned
ensure_min_nesting(17, 0) == 17
ensure_min_nesting(17, 1) == [17]
ensure_min_nesting([17], 1) == [17]
ensure_min_nesting([17], 2) == [[17]]
ensure_min_nesting([(1,2,3)], 3) == [[(1,2,3)]]
ensure_min_nesting([[[17]]], 1) => [[[17]]]
"""
current_level = get_data_nesting_level(data, data_types)
if current_level >= target_level:
return data
result = data
for i in range(target_level - current_level):
result = [result]
return result
def flatten_data(data, target_level=1, data_types=SIMPLE_DATA_TYPES):
"""
Reduce nesting level of `data` to `target_level`, by concatenating nested sub-lists.
Raises an exception if nesting level is already less than `target_level`.
Refer to data_structure_tests.py for examples.
"""
current_level = get_data_nesting_level(data, data_types)
if current_level < target_level:
raise TypeError(f"Can't flatten data to level {target_level}: data already have level {current_level}")
elif current_level == target_level:
return data
else:
result = []
for item in data:
result.extend(flatten_data(item, target_level=target_level, data_types=data_types))
return result
def graft_data(data, item_level=1, wrap_level=1, data_types=SIMPLE_DATA_TYPES):
"""
For each nested item of the list, which has it's own nesting level of `target_level`,
wrap that item into a pair of [].
For example, with item_level==0, this means wrap each number in the nested list
(however deep this number is nested) into pair of [].
Refer to data_structure_tests.py for examples.
"""
def wrap(item):
for i in range(wrap_level):
item = [item]
return item
def helper(data):
current_level = get_data_nesting_level(data, data_types)
if current_level == item_level:
return wrap(data)
else:
result = [helper(item) for item in data]
return result
return helper(data)
def wrap_data(data, wrap_level=1):
for i in range(wrap_level):
data = [data]
return data
def unwrap_data(data, unwrap_level=1, socket=None):
socket_msg = "" if socket is None else f" in socket {socket.label or socket.name}"
def unwrap(lst, level):
if not isinstance(lst, (list, tuple, ndarray)):
raise Exception(f"Cannot unwrap data: Data at level {level} is an atomic object, not a list {socket_msg}")
n = len(lst)
if n == 0:
raise Exception(f"Cannot unwrap data: Data at level {level} is an empty list {socket_msg}")
elif n > 1:
raise Exception(f"Cannot unwrap data: Data at level {level} contains {n} objects instead of one {socket_msg}")
else:
return lst[0]
for level in range(unwrap_level):
data = unwrap(data, level)
return data
class SvListLevelAdjustment(object):
def __init__(self, flatten=False, wrap=False):
self.flatten = flatten
self.wrap = wrap
def __repr__(self):
return f"<Flatten={self.flatten}, Wrap={self.wrap}>"
def list_levels_adjust(data, instructions, data_types=SIMPLE_DATA_TYPES):
data_level = get_data_nesting_level(data, data_types + (ndarray,))
if len(instructions) < data_level+1:
raise Exception(f"Number of instructions ({len(instructions)}) is less than data nesting level {data_level} + 1")
def process(data, instruction, level):
result = data
if level + 1 < data_level and instruction.flatten:
result = sum(result, [])
if instruction.wrap:
result = [result]
#print(f"II: {level}/{data_level}, {instruction}, {data} => {result}")
return result
def helper(data, instructions, level):
if level == data_level:
items = process(data, instructions[0], level)
else:
sub_items = [helper(item, instructions[1:], level+1) for item in data]
items = process(sub_items, instructions[0], level)
#print(f"?? {level}/{data_level}, {data} => {sub_items} => {items}")
return items
return helper(data, instructions, 0)
def map_at_level(function, data, item_level=0, data_types=SIMPLE_DATA_TYPES):
"""
Given a nested list of object, apply `function` to each sub-list of items.
Nesting structure of the result will be simpler than such of the input:
most nested levels (`item_level` of them) will be eliminated.
Refer to data_structure_tests.py for examples.
"""
current_level = get_data_nesting_level(data, data_types)
if current_level == item_level:
return function(data)
else:
return [map_at_level(function, item, item_level, data_types) for item in data]
def transpose_list(lst):
"""
Transpose a list of lists.
transpose_list([[1,2], [3,4]]) == [[1,3], [2, 4]]
"""
return list(map(list, zip(*lst)))
# from python 3.5 docs https://docs.python.org/3.5/library/itertools.html recipes
def split_by_count(iterable, n, fillvalue=None):
"Collect data into fixed-length chunks or blocks"
# grouper('ABCDEFG', 3, 'x') --> ABC DEF Gxx"
args = [iter(iterable)] * n
return list(map(list, zip_longest(*args, fillvalue=fillvalue)))
def describe_data_shape_by_level(data, include_numpy_nesting=True):
"""
Describe shape of data in human-readable form.
Returns tuple:
* data nesting level
* list of descriptions of data shapes at each nesting level
"""
def helper(data):
if not isinstance(data, (list, tuple)):
if isinstance(data, ndarray):
if include_numpy_nesting:
nesting = len(data.shape)
else:
nesting = 0
return nesting, [type(data).__name__ + " of " + str(data.dtype) + " with shape " + str(data.shape)]
return 0, [type(data).__name__]
else:
result = [f"{type(data).__name__} [{len(data)}]"]
if len(data) > 0:
child = data[0]
child_nesting, child_result = helper(child)
result = result + child_result
else:
child_nesting = 0
return (child_nesting + 1), result
nesting, result = helper(data)
return nesting, result
def describe_data_shape(data):
"""
Describe shape of data in human-readable form.
Returns string.
Can be used for debugging or for displaying information to user.
Note: this method inspects only first element of each list/tuple,
expecting they are all homogeneous (that is usually true in Sverchok).
describe_data_shape(None) == 'Level 0: NoneType'
describe_data_shape(1) == 'Level 0: int'
describe_data_shape([]) == 'Level 1: list [0]'
describe_data_shape([1]) == 'Level 1: list [1] of int'
describe_data_shape([[(1,2,3)]]) == 'Level 3: list [1] of list [1] of tuple [3] of int'
"""
nesting, descriptions = describe_data_shape_by_level(data)
result = " of ".join(descriptions)
return "Level {}: {}".format(nesting, result)
def describe_data_structure(data, data_types=SIMPLE_DATA_TYPES):
if isinstance(data, data_types):
return "*"
elif isinstance(data, (list, tuple)):
if isinstance(data[0], data_types):
return str(len(data)) + "*"
else:
rs = []
for item in data:
r = describe_data_structure(item, data_types)
rs.append(str(r))
rs = str(len(data)) + "[" + ", ".join(rs) + "]"
return rs
else:
raise TypeError(f"Unexpected data type: {type(data)}")
def calc_mask(subset_data, set_data, level=0, negate=False, ignore_order=True):
"""
Calculate mask: for each item in set_data, return True if it is present in subset_data.
The function can work at any specified level.
subset_data: subset, for example [1]
set_data: set, for example [1, 2, 3]
level: 0 to check immediate members of set and subset; 1 to work with lists of lists and so on.
negate: if True, then result will be negated (True if item of set is not present in subset).
ignore_order: when comparing lists, ignore items order.
Raises an exception if nesting level of input sets is less than specified level parameter.
calc_mask([1], [1,2,3]) == [True, False, False])
calc_mask([1], [1,2,3], negate=True) == [False, True, True]
"""
if level == 0:
if not isinstance(subset_data, (tuple, list)):
raise Exception("Specified level is too high for given Subset")
if not isinstance(set_data, (tuple, list)):
raise Exception("Specified level is too high for given Set")
if ignore_order and get_data_nesting_level(subset_data) > 1:
if negate:
return [set(item) not in map(set, subset_data) for item in set_data]
else:
return [set(item) in map(set, subset_data) for item in set_data]
else:
if negate:
return [item not in subset_data for item in set_data]
else:
return [item in subset_data for item in set_data]
else:
sub_objects = match_long_repeat([subset_data, set_data])
return [calc_mask(subset_item, set_item, level - 1, negate, ignore_order) for subset_item, set_item in zip(*sub_objects)]
def apply_mask(mask, lst):
good, bad = [], []
for m, item in zip(mask, lst):
if m:
good.append(item)
else:
bad.append(item)
return good, bad
def invert_index_list(indexes, length):
'''
Inverts indexes list
indexes: List[Int] of Ndarray flat numpy array
length: Int. Length of the base list
'''
mask = np_ones(length, dtype='bool')
mask[indexes] = False
inverted_indexes = np_arange(length)[mask]
return inverted_indexes
def rotate_list(l, y=1):
"""
"Rotate" list by shifting it's items towards the end and putting last items to the beginning.
For example,
rotate_list([1, 2, 3]) = [2, 3, 1]
rotate_list([1, 2, 3], y=2) = [3, 1, 2]
"""
if len(l) == 0:
return l
if y == 0:
return l
y = y % len(l)
return list(l[y:]) + list(l[:y])
def partition(p, lst):
good, bad = [], []
for item in lst:
if p(item):
good.append(item)
else:
bad.append(item)
return good, bad
def map_recursive(fn, data, data_types=SIMPLE_DATA_TYPES):
"""
Given a nested list of items, apply `fn` to each of these items.
Nesting structure of the result will be the same as in the input.
"""
def helper(data, level):
if isinstance(data, data_types):
return fn(data)
elif isinstance(data, (list, tuple)):
return [helper(item, level+1) for item in data]
else:
raise TypeError(f"Encountered unknown data of type {type(data)} at nesting level #{level}")
return helper(data, 0)
def map_unzip_recursirve(fn, data, data_types=SIMPLE_DATA_TYPES):
"""
Given a nested list of items, apply `fn` to each of these items.
This method expects that `fn` will return a tuple (or list) of results.
After applying `fn` to each of items of data, "unzip" the result, so that
each item of result of `fn` would be in a separate nested list.
Nesting structure of each of items of the result of this method will be
the same as nesting structure of input data.
Refer to data_structure_tests.py for examples.
"""
def helper(data, level):
if isinstance(data, data_types):
return fn(data)
elif isinstance(data, (list, tuple)):
results = [helper(item, level+1) for item in data]
return transpose_list(results)
else:
raise TypeError(f"Encountered unknown data of type {type(data)} at nesting level #{level}")
return helper(data, 0)
def unzip_dict_recursive(data, item_type=dict, to_dict=None):
"""
Given a nested list of dictionaries, return a dictionary of nested lists.
Nesting structure of each of values of resulting dictionary will be similar to
nesting structure of input data, only at the deepest level, instead of dictionaries
you will have their values.
inputs:
* data: nested list of dictionaries.
* item_type: allows to use arbitrary class instead of standard python's dict.
* to_dict: a function which translates data item into python's dict (or
another class with the same interface). Identity by default.
output: dictionary of nested lists.
Refer to data_structure_tests.py for examples.
"""
if to_dict is None:
to_dict = lambda d: d
def helper(data):
current_level = get_data_nesting_level(data, data_types=(item_type,))
if current_level == 0:
return to_dict(data)
elif current_level == 1:
result = defaultdict(list)
for dct in data:
dct = to_dict(dct)
for key, value in dct.items():
result[key].append(value)
return result
else:
result = defaultdict(list)
for item in data:
sub_result = helper(item)
for key, value in sub_result.items():
result[key].append(value)
return result
return helper(data)
def is_ultimately(data, data_types):
"""
Check if data is a nested list / tuple / array
which ultimately consists of items of data_types.
"""
if isinstance(data, (list, tuple, ndarray)):
return is_ultimately(data[0], data_types)
return isinstance(data, data_types)
#####################################################
################### matrix magic ####################
#####################################################
# tools that makes easier to convert data
# from string to matrixes, vertices,
# lists, other and vice versa
def Matrix_listing(prop):
"""Convert Matrix() into Sverchok data"""
mat_out = []
for matrix in prop:
unit = []
for m in matrix:
# [Matrix0, Matrix1, ... ]
unit.append(m[:])
mat_out.append((unit))
return mat_out
def Matrix_generate(prop):
"""Generate Matrix() data from Sverchok data"""
mat_out = []
for matrix in prop:
unit = Matrix()
for k, m in enumerate(matrix):
# [Matrix0, Matrix1, ... ]
unit[k] = Vector(m)
mat_out.append(unit)
return mat_out
def Matrix_location(prop, to_list=False):
"""return a list of locations representing the translation of the matrices"""