Intelegentny_Pszczelarz/.venv/Lib/site-packages/opt_einsum/parser.py

#!/usr/bin/env python
# coding: utf-8
"""
A functionally equivalent parser of the numpy.einsum input parser
"""

import itertools
from collections import OrderedDict

import numpy as np

__all__ = [
    "is_valid_einsum_char", "has_valid_einsum_chars_only", "get_symbol", "gen_unused_symbols",
    "convert_to_valid_einsum_chars", "alpha_canonicalize", "find_output_str", "find_output_shape",
    "possibly_convert_to_numpy", "parse_einsum_input"
]

_einsum_symbols_base = 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ'


def is_valid_einsum_char(x):
    """Check if the character ``x`` is valid for numpy einsum.

    Examples
    --------
    >>> is_valid_einsum_char("a")
    True

    >>> is_valid_einsum_char("Ǵ")
    False
    """
    return (x in _einsum_symbols_base) or (x in ',->.')


def has_valid_einsum_chars_only(einsum_str):
    """Check if ``einsum_str`` contains only valid characters for numpy einsum.

    Examples
    --------
    >>> has_valid_einsum_chars_only("abAZ")
    True

    >>> has_valid_einsum_chars_only("Över")
    False
    """
    return all(map(is_valid_einsum_char, einsum_str))


def get_symbol(i):
    """Get the symbol corresponding to int ``i`` - runs through the usual 52
    letters before resorting to unicode characters, starting at ``chr(192)``.

    Examples
    --------
    >>> get_symbol(2)
    'c'

    >>> get_symbol(200)
    'Ŕ'

    >>> get_symbol(20000)
    '京'
    """
    if i < 52:
        return _einsum_symbols_base[i]
    return chr(i + 140)


def gen_unused_symbols(used, n):
    """Generate ``n`` symbols that are not already in ``used``.

    Examples
    --------
    >>> list(oe.parser.gen_unused_symbols("abd", 2))
    ['c', 'e']
    """
    i = cnt = 0
    while cnt < n:
        s = get_symbol(i)
        i += 1
        if s in used:
            continue
        yield s
        cnt += 1


def convert_to_valid_einsum_chars(einsum_str):
    """Convert the str ``einsum_str`` to contain only the alphabetic characters
    valid for numpy einsum. If there are too many symbols, let the backend
    throw an error.

    Examples
    --------
    >>> oe.parser.convert_to_valid_einsum_chars("Ĥěļļö")
    'cbdda'
    """
    symbols = sorted(set(einsum_str) - set(',->'))
    replacer = {x: get_symbol(i) for i, x in enumerate(symbols)}
    return "".join(replacer.get(x, x) for x in einsum_str)


def alpha_canonicalize(equation):
    """Alpha convert an equation in an order-independent canonical way.

    Examples
    --------
    >>> oe.parser.alpha_canonicalize("dcba")
    'abcd'

    >>> oe.parser.alpha_canonicalize("Ĥěļļö")
    'abccd'
    """
    rename = OrderedDict()
    for name in equation:
        if name in '.,->':
            continue
        if name not in rename:
            rename[name] = get_symbol(len(rename))
    return ''.join(rename.get(x, x) for x in equation)


def find_output_str(subscripts):
    """
    Find the output string for the inputs ``subscripts`` under canonical einstein summation rules. That is, repeated indices are summed over by default.

    Examples
    --------
    >>> oe.parser.find_output_str("ab,bc")
    'ac'

    >>> oe.parser.find_output_str("a,b")
    'ab'

    >>> oe.parser.find_output_str("a,a,b,b")
    ''
    """
    tmp_subscripts = subscripts.replace(",", "")
    return "".join(s for s in sorted(set(tmp_subscripts)) if tmp_subscripts.count(s) == 1)


def find_output_shape(inputs, shapes, output):
    """Find the output shape for given inputs, shapes and output string, taking
    into account broadcasting.

    Examples
    --------
    >>> oe.parser.find_output_shape(["ab", "bc"], [(2, 3), (3, 4)], "ac")
    (2, 4)

    # Broadcasting is accounted for
    >>> oe.parser.find_output_shape(["a", "a"], [(4, ), (1, )], "a")
    (4,)
    """
    return tuple(
        max(shape[loc] for shape, loc in zip(shapes, [x.find(c) for x in inputs]) if loc >= 0) for c in output)


def possibly_convert_to_numpy(x):
    """Convert things without a 'shape' to ndarrays, but leave everything else.

    Examples
    --------
    >>> oe.parser.possibly_convert_to_numpy(5)
    array(5)

    >>> oe.parser.possibly_convert_to_numpy([5, 3])
    array([5, 3])

    >>> oe.parser.possibly_convert_to_numpy(np.array([5, 3]))
    array([5, 3])

    # Any class with a shape is passed through
    >>> class Shape:
    ...     def __init__(self, shape):
    ...         self.shape = shape
    ...

    >>> myshape = Shape((5, 5))
    >>> oe.parser.possibly_convert_to_numpy(myshape)
    <__main__.Shape object at 0x10f850710>
    """

    if not hasattr(x, 'shape'):
        return np.asanyarray(x)
    else:
        return x


def convert_subscripts(old_sub, symbol_map):
    """Convert user custom subscripts list to subscript string according to `symbol_map`.

    Examples
    --------
    >>>  oe.parser.convert_subscripts(['abc', 'def'], {'abc':'a', 'def':'b'})
    'ab'
    >>> oe.parser.convert_subscripts([Ellipsis, object], {object:'a'})
    '...a'
    """
    new_sub = ""
    for s in old_sub:
        if s is Ellipsis:
            new_sub += "..."
        else:
            # no need to try/except here because symbol_map has already been checked
            new_sub += symbol_map[s]
    return new_sub


def convert_interleaved_input(operands):
    """Convert 'interleaved' input to standard einsum input.
    """
    tmp_operands = list(operands)
    operand_list = []
    subscript_list = []
    for p in range(len(operands) // 2):
        operand_list.append(tmp_operands.pop(0))
        subscript_list.append(tmp_operands.pop(0))

    output_list = tmp_operands[-1] if len(tmp_operands) else None
    operands = [possibly_convert_to_numpy(x) for x in operand_list]

    # build a map from user symbols to single-character symbols based on `get_symbol`
    # The map retains the intrinsic order of user symbols
    try:
        # collect all user symbols
        symbol_set = set(itertools.chain.from_iterable(subscript_list))

        # remove Ellipsis because it can not be compared with other objects
        symbol_set.discard(Ellipsis)

        # build the map based on sorted user symbols, retaining the order we lost in the `set`
        symbol_map = {symbol: get_symbol(idx) for idx, symbol in enumerate(sorted(symbol_set))}

    except TypeError:  # unhashable or uncomparable object
        raise TypeError("For this input type lists must contain either Ellipsis "
                        "or hashable and comparable object (e.g. int, str).")

    subscripts = ','.join(convert_subscripts(sub, symbol_map) for sub in subscript_list)
    if output_list is not None:
        subscripts += "->"
        subscripts += convert_subscripts(output_list, symbol_map)

    return subscripts, operands


def parse_einsum_input(operands):
    """
    A reproduction of einsum c side einsum parsing in python.

    Returns
    -------
    input_strings : str
        Parsed input strings
    output_string : str
        Parsed output string
    operands : list of array_like
        The operands to use in the numpy contraction

    Examples
    --------
    The operand list is simplified to reduce printing:

    >>> a = np.random.rand(4, 4)
    >>> b = np.random.rand(4, 4, 4)
    >>> parse_einsum_input(('...a,...a->...', a, b))
    ('za,xza', 'xz', [a, b])

    >>> parse_einsum_input((a, [Ellipsis, 0], b, [Ellipsis, 0]))
    ('za,xza', 'xz', [a, b])
    """

    if len(operands) == 0:
        raise ValueError("No input operands")

    if isinstance(operands[0], str):
        subscripts = operands[0].replace(" ", "")
        operands = [possibly_convert_to_numpy(x) for x in operands[1:]]

    else:
        subscripts, operands = convert_interleaved_input(operands)

    # Check for proper "->"
    if ("-" in subscripts) or (">" in subscripts):
        invalid = (subscripts.count("-") > 1) or (subscripts.count(">") > 1)
        if invalid or (subscripts.count("->") != 1):
            raise ValueError("Subscripts can only contain one '->'.")

    # Parse ellipses
    if "." in subscripts:
        used = subscripts.replace(".", "").replace(",", "").replace("->", "")
        ellipse_inds = "".join(gen_unused_symbols(used, max(len(x.shape) for x in operands)))
        longest = 0

        # Do we have an output to account for?
        if "->" in subscripts:
            input_tmp, output_sub = subscripts.split("->")
            split_subscripts = input_tmp.split(",")
            out_sub = True
        else:
            split_subscripts = subscripts.split(',')
            out_sub = False

        for num, sub in enumerate(split_subscripts):
            if "." in sub:
                if (sub.count(".") != 3) or (sub.count("...") != 1):
                    raise ValueError("Invalid Ellipses.")

                # Take into account numerical values
                if operands[num].shape == ():
                    ellipse_count = 0
                else:
                    ellipse_count = max(len(operands[num].shape), 1) - (len(sub) - 3)

                if ellipse_count > longest:
                    longest = ellipse_count

                if ellipse_count < 0:
                    raise ValueError("Ellipses lengths do not match.")
                elif ellipse_count == 0:
                    split_subscripts[num] = sub.replace('...', '')
                else:
                    split_subscripts[num] = sub.replace('...', ellipse_inds[-ellipse_count:])

        subscripts = ",".join(split_subscripts)

        # Figure out output ellipses
        if longest == 0:
            out_ellipse = ""
        else:
            out_ellipse = ellipse_inds[-longest:]

        if out_sub:
            subscripts += "->" + output_sub.replace("...", out_ellipse)
        else:
            # Special care for outputless ellipses
            output_subscript = find_output_str(subscripts)
            normal_inds = ''.join(sorted(set(output_subscript) - set(out_ellipse)))

            subscripts += "->" + out_ellipse + normal_inds

    # Build output string if does not exist
    if "->" in subscripts:
        input_subscripts, output_subscript = subscripts.split("->")
    else:
        input_subscripts, output_subscript = subscripts, find_output_str(subscripts)

    # Make sure output subscripts are in the input
    for char in output_subscript:
        if char not in input_subscripts:
            raise ValueError("Output character '{}' did not appear in the input".format(char))

    # Make sure number operands is equivalent to the number of terms
    if len(input_subscripts.split(',')) != len(operands):
        raise ValueError("Number of einsum subscripts must be equal to the " "number of operands.")

    return input_subscripts, output_subscript, operands
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`#!/usr/bin/env python`
			`# coding: utf-8`
			`"""`
			`A functionally equivalent parser of the numpy.einsum input parser`
			`"""`

			`import itertools`
			`from collections import OrderedDict`

			`import numpy as np`

			`__all__ = [`
			`"is_valid_einsum_char", "has_valid_einsum_chars_only", "get_symbol", "gen_unused_symbols",`
			`"convert_to_valid_einsum_chars", "alpha_canonicalize", "find_output_str", "find_output_shape",`
			`"possibly_convert_to_numpy", "parse_einsum_input"`
			`]`

			`_einsum_symbols_base = 'abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ'`


			`def is_valid_einsum_char(x):`
			"""Check if the character ``x`` is valid for numpy einsum.

			`Examples`
			`--------`
			`>>> is_valid_einsum_char("a")`
			`True`

			`>>> is_valid_einsum_char("Ǵ")`
			`False`
			`"""`
			`return (x in _einsum_symbols_base) or (x in ',->.')`


			`def has_valid_einsum_chars_only(einsum_str):`
			"""Check if ``einsum_str`` contains only valid characters for numpy einsum.

			`Examples`
			`--------`
			`>>> has_valid_einsum_chars_only("abAZ")`
			`True`

			`>>> has_valid_einsum_chars_only("Över")`
			`False`
			`"""`
			`return all(map(is_valid_einsum_char, einsum_str))`


			`def get_symbol(i):`
			"""Get the symbol corresponding to int ``i`` - runs through the usual 52
			letters before resorting to unicode characters, starting at ``chr(192)``.

			`Examples`
			`--------`
			`>>> get_symbol(2)`
			`'c'`

			`>>> get_symbol(200)`
			`'Ŕ'`

			`>>> get_symbol(20000)`
			`'京'`
			`"""`
			`if i < 52:`
			`return _einsum_symbols_base[i]`
			`return chr(i + 140)`


			`def gen_unused_symbols(used, n):`
			"""Generate ``n`` symbols that are not already in ``used``.

			`Examples`
			`--------`
			`>>> list(oe.parser.gen_unused_symbols("abd", 2))`
			`['c', 'e']`
			`"""`
			`i = cnt = 0`
			`while cnt < n:`
			`s = get_symbol(i)`
			`i += 1`
			`if s in used:`
			`continue`
			`yield s`
			`cnt += 1`


			`def convert_to_valid_einsum_chars(einsum_str):`
			"""Convert the str ``einsum_str`` to contain only the alphabetic characters
			`valid for numpy einsum. If there are too many symbols, let the backend`
			`throw an error.`

			`Examples`
			`--------`
			`>>> oe.parser.convert_to_valid_einsum_chars("Ĥěļļö")`
			`'cbdda'`
			`"""`
			`symbols = sorted(set(einsum_str) - set(',->'))`
			`replacer = {x: get_symbol(i) for i, x in enumerate(symbols)}`
			`return "".join(replacer.get(x, x) for x in einsum_str)`


			`def alpha_canonicalize(equation):`
			`"""Alpha convert an equation in an order-independent canonical way.`

			`Examples`
			`--------`
			`>>> oe.parser.alpha_canonicalize("dcba")`
			`'abcd'`

			`>>> oe.parser.alpha_canonicalize("Ĥěļļö")`
			`'abccd'`
			`"""`
			`rename = OrderedDict()`
			`for name in equation:`
			`if name in '.,->':`
			`continue`
			`if name not in rename:`
			`rename[name] = get_symbol(len(rename))`
			`return ''.join(rename.get(x, x) for x in equation)`


			`def find_output_str(subscripts):`
			`"""`
			Find the output string for the inputs ``subscripts`` under canonical einstein summation rules. That is, repeated indices are summed over by default.

			`Examples`
			`--------`
			`>>> oe.parser.find_output_str("ab,bc")`
			`'ac'`

			`>>> oe.parser.find_output_str("a,b")`
			`'ab'`

			`>>> oe.parser.find_output_str("a,a,b,b")`
			`''`
			`"""`
			`tmp_subscripts = subscripts.replace(",", "")`
			`return "".join(s for s in sorted(set(tmp_subscripts)) if tmp_subscripts.count(s) == 1)`


			`def find_output_shape(inputs, shapes, output):`
			`"""Find the output shape for given inputs, shapes and output string, taking`
			`into account broadcasting.`

			`Examples`
			`--------`
			`>>> oe.parser.find_output_shape(["ab", "bc"], [(2, 3), (3, 4)], "ac")`
			`(2, 4)`

			`# Broadcasting is accounted for`
			`>>> oe.parser.find_output_shape(["a", "a"], [(4, ), (1, )], "a")`
			`(4,)`
			`"""`
			`return tuple(`
			`max(shape[loc] for shape, loc in zip(shapes, [x.find(c) for x in inputs]) if loc >= 0) for c in output)`


			`def possibly_convert_to_numpy(x):`
			`"""Convert things without a 'shape' to ndarrays, but leave everything else.`

			`Examples`
			`--------`
			`>>> oe.parser.possibly_convert_to_numpy(5)`
			`array(5)`

			`>>> oe.parser.possibly_convert_to_numpy([5, 3])`
			`array([5, 3])`

			`>>> oe.parser.possibly_convert_to_numpy(np.array([5, 3]))`
			`array([5, 3])`

			`# Any class with a shape is passed through`
			`>>> class Shape:`
			`... def __init__(self, shape):`
			`... self.shape = shape`
			`...`

			`>>> myshape = Shape((5, 5))`
			`>>> oe.parser.possibly_convert_to_numpy(myshape)`
			`<__main__.Shape object at 0x10f850710>`
			`"""`

			`if not hasattr(x, 'shape'):`
			`return np.asanyarray(x)`
			`else:`
			`return x`


			`def convert_subscripts(old_sub, symbol_map):`
			"""Convert user custom subscripts list to subscript string according to `symbol_map`.

			`Examples`
			`--------`
			`>>> oe.parser.convert_subscripts(['abc', 'def'], {'abc':'a', 'def':'b'})`
			`'ab'`
			`>>> oe.parser.convert_subscripts([Ellipsis, object], {object:'a'})`
			`'...a'`
			`"""`
			`new_sub = ""`
			`for s in old_sub:`
			`if s is Ellipsis:`
			`new_sub += "..."`
			`else:`
			`# no need to try/except here because symbol_map has already been checked`
			`new_sub += symbol_map[s]`
			`return new_sub`


			`def convert_interleaved_input(operands):`
			`"""Convert 'interleaved' input to standard einsum input.`
			`"""`
			`tmp_operands = list(operands)`
			`operand_list = []`
			`subscript_list = []`
			`for p in range(len(operands) // 2):`
			`operand_list.append(tmp_operands.pop(0))`
			`subscript_list.append(tmp_operands.pop(0))`

			`output_list = tmp_operands[-1] if len(tmp_operands) else None`
			`operands = [possibly_convert_to_numpy(x) for x in operand_list]`

			# build a map from user symbols to single-character symbols based on `get_symbol`
			`# The map retains the intrinsic order of user symbols`
			`try:`
			`# collect all user symbols`
			`symbol_set = set(itertools.chain.from_iterable(subscript_list))`

			`# remove Ellipsis because it can not be compared with other objects`
			`symbol_set.discard(Ellipsis)`

			# build the map based on sorted user symbols, retaining the order we lost in the `set`
			`symbol_map = {symbol: get_symbol(idx) for idx, symbol in enumerate(sorted(symbol_set))}`

			`except TypeError: # unhashable or uncomparable object`
			`raise TypeError("For this input type lists must contain either Ellipsis "`
			`"or hashable and comparable object (e.g. int, str).")`

			`subscripts = ','.join(convert_subscripts(sub, symbol_map) for sub in subscript_list)`
			`if output_list is not None:`
			`subscripts += "->"`
			`subscripts += convert_subscripts(output_list, symbol_map)`

			`return subscripts, operands`


			`def parse_einsum_input(operands):`
			`"""`
			`A reproduction of einsum c side einsum parsing in python.`

			`Returns`
			`-------`
			`input_strings : str`
			`Parsed input strings`
			`output_string : str`
			`Parsed output string`
			`operands : list of array_like`
			`The operands to use in the numpy contraction`

			`Examples`
			`--------`
			`The operand list is simplified to reduce printing:`

			`>>> a = np.random.rand(4, 4)`
			`>>> b = np.random.rand(4, 4, 4)`
			`>>> parse_einsum_input(('...a,...a->...', a, b))`
			`('za,xza', 'xz', [a, b])`

			`>>> parse_einsum_input((a, [Ellipsis, 0], b, [Ellipsis, 0]))`
			`('za,xza', 'xz', [a, b])`
			`"""`

			`if len(operands) == 0:`
			`raise ValueError("No input operands")`

			`if isinstance(operands[0], str):`
			`subscripts = operands[0].replace(" ", "")`
			`operands = [possibly_convert_to_numpy(x) for x in operands[1:]]`

			`else:`
			`subscripts, operands = convert_interleaved_input(operands)`

			`# Check for proper "->"`
			`if ("-" in subscripts) or (">" in subscripts):`
			`invalid = (subscripts.count("-") > 1) or (subscripts.count(">") > 1)`
			`if invalid or (subscripts.count("->") != 1):`
			`raise ValueError("Subscripts can only contain one '->'.")`

			`# Parse ellipses`
			`if "." in subscripts:`
			`used = subscripts.replace(".", "").replace(",", "").replace("->", "")`
			`ellipse_inds = "".join(gen_unused_symbols(used, max(len(x.shape) for x in operands)))`
			`longest = 0`

			`# Do we have an output to account for?`
			`if "->" in subscripts:`
			`input_tmp, output_sub = subscripts.split("->")`
			`split_subscripts = input_tmp.split(",")`
			`out_sub = True`
			`else:`
			`split_subscripts = subscripts.split(',')`
			`out_sub = False`

			`for num, sub in enumerate(split_subscripts):`
			`if "." in sub:`
			`if (sub.count(".") != 3) or (sub.count("...") != 1):`
			`raise ValueError("Invalid Ellipses.")`

			`# Take into account numerical values`
			`if operands[num].shape == ():`
			`ellipse_count = 0`
			`else:`
			`ellipse_count = max(len(operands[num].shape), 1) - (len(sub) - 3)`

			`if ellipse_count > longest:`
			`longest = ellipse_count`

			`if ellipse_count < 0:`
			`raise ValueError("Ellipses lengths do not match.")`
			`elif ellipse_count == 0:`
			`split_subscripts[num] = sub.replace('...', '')`
			`else:`
			`split_subscripts[num] = sub.replace('...', ellipse_inds[-ellipse_count:])`

			`subscripts = ",".join(split_subscripts)`

			`# Figure out output ellipses`
			`if longest == 0:`
			`out_ellipse = ""`
			`else:`
			`out_ellipse = ellipse_inds[-longest:]`

			`if out_sub:`
			`subscripts += "->" + output_sub.replace("...", out_ellipse)`
			`else:`
			`# Special care for outputless ellipses`
			`output_subscript = find_output_str(subscripts)`
			`normal_inds = ''.join(sorted(set(output_subscript) - set(out_ellipse)))`

			`subscripts += "->" + out_ellipse + normal_inds`

			`# Build output string if does not exist`
			`if "->" in subscripts:`
			`input_subscripts, output_subscript = subscripts.split("->")`
			`else:`
			`input_subscripts, output_subscript = subscripts, find_output_str(subscripts)`

			`# Make sure output subscripts are in the input`
			`for char in output_subscript:`
			`if char not in input_subscripts:`
			`raise ValueError("Output character '{}' did not appear in the input".format(char))`

			`# Make sure number operands is equivalent to the number of terms`
			`if len(input_subscripts.split(',')) != len(operands):`
			`raise ValueError("Number of einsum subscripts must be equal to the " "number of operands.")`

			`return input_subscripts, output_subscript, operands`