edgartools/venv/lib/python3.10/site-packages/rapidfuzz/distance/Indel_py.py

# SPDX-License-Identifier: MIT
# Copyright (C) 2022 Max Bachmann
from __future__ import annotations

from rapidfuzz._common_py import conv_sequences
from rapidfuzz._utils import is_none, setupPandas
from rapidfuzz.distance.LCSseq_py import (
    _block_similarity as lcs_seq_block_similarity,
    editops as lcs_seq_editops,
    opcodes as lcs_seq_opcodes,
    similarity as lcs_seq_similarity,
)


def distance(
    s1,
    s2,
    *,
    processor=None,
    score_cutoff=None,
):
    """
    Calculates the minimum number of insertions and deletions
    required to change one sequence into the other. This is equivalent to the
    Levenshtein distance with a substitution weight of 2.

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.
    score_cutoff : int, optional
        Maximum distance between s1 and s2, that is
        considered as a result. If the distance is bigger than score_cutoff,
        score_cutoff + 1 is returned instead. Default is None, which deactivates
        this behaviour.

    Returns
    -------
    distance : int
        distance between s1 and s2

    Examples
    --------
    Find the Indel distance between two strings:

    >>> from rapidfuzz.distance import Indel
    >>> Indel.distance("lewenstein", "levenshtein")
    3

    Setting a maximum distance allows the implementation to select
    a more efficient implementation:

    >>> Indel.distance("lewenstein", "levenshtein", score_cutoff=1)
    2

    """
    if processor is not None:
        s1 = processor(s1)
        s2 = processor(s2)

    s1, s2 = conv_sequences(s1, s2)
    maximum = len(s1) + len(s2)
    lcs_sim = lcs_seq_similarity(s1, s2)
    dist = maximum - 2 * lcs_sim
    return dist if (score_cutoff is None or dist <= score_cutoff) else score_cutoff + 1


def _block_distance(
    block,
    s1,
    s2,
    score_cutoff=None,
):
    maximum = len(s1) + len(s2)
    lcs_sim = lcs_seq_block_similarity(block, s1, s2)
    dist = maximum - 2 * lcs_sim
    return dist if (score_cutoff is None or dist <= score_cutoff) else score_cutoff + 1


def similarity(
    s1,
    s2,
    *,
    processor=None,
    score_cutoff=None,
):
    """
    Calculates the Indel similarity in the range [max, 0].

    This is calculated as ``(len1 + len2) - distance``.

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.
    score_cutoff : int, optional
        Maximum distance between s1 and s2, that is
        considered as a result. If the similarity is smaller than score_cutoff,
        0 is returned instead. Default is None, which deactivates
        this behaviour.

    Returns
    -------
    similarity : int
        similarity between s1 and s2
    """
    if processor is not None:
        s1 = processor(s1)
        s2 = processor(s2)

    s1, s2 = conv_sequences(s1, s2)
    maximum = len(s1) + len(s2)
    dist = distance(s1, s2)
    sim = maximum - dist
    return sim if (score_cutoff is None or sim >= score_cutoff) else 0


def normalized_distance(
    s1,
    s2,
    *,
    processor=None,
    score_cutoff=None,
):
    """
    Calculates a normalized levenshtein similarity in the range [1, 0].

    This is calculated as ``distance / (len1 + len2)``.

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.
    score_cutoff : float, optional
        Optional argument for a score threshold as a float between 0 and 1.0.
        For norm_dist > score_cutoff 1.0 is returned instead. Default is 1.0,
        which deactivates this behaviour.

    Returns
    -------
    norm_dist : float
        normalized distance between s1 and s2 as a float between 0 and 1.0
    """
    setupPandas()
    if is_none(s1) or is_none(s2):
        return 1.0

    if processor is not None:
        s1 = processor(s1)
        s2 = processor(s2)

    s1, s2 = conv_sequences(s1, s2)
    maximum = len(s1) + len(s2)
    dist = distance(s1, s2)
    norm_dist = dist / maximum if maximum else 0
    return norm_dist if (score_cutoff is None or norm_dist <= score_cutoff) else 1


def _block_normalized_distance(
    block,
    s1,
    s2,
    score_cutoff=None,
):
    maximum = len(s1) + len(s2)
    dist = _block_distance(block, s1, s2)
    norm_dist = dist / maximum if maximum else 0
    return norm_dist if (score_cutoff is None or norm_dist <= score_cutoff) else 1


def normalized_similarity(
    s1,
    s2,
    *,
    processor=None,
    score_cutoff=None,
):
    """
    Calculates a normalized indel similarity in the range [0, 1].

    This is calculated as ``1 - normalized_distance``

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.
    score_cutoff : float, optional
        Optional argument for a score threshold as a float between 0 and 1.0.
        For norm_sim < score_cutoff 0 is returned instead. Default is 0,
        which deactivates this behaviour.

    Returns
    -------
    norm_sim : float
        normalized similarity between s1 and s2 as a float between 0 and 1.0

    Examples
    --------
    Find the normalized Indel similarity between two strings:

    >>> from rapidfuzz.distance import Indel
    >>> Indel.normalized_similarity("lewenstein", "levenshtein")
    0.85714285714285

    Setting a score_cutoff allows the implementation to select
    a more efficient implementation:

    >>> Indel.normalized_similarity("lewenstein", "levenshtein", score_cutoff=0.9)
    0.0

    When a different processor is used s1 and s2 do not have to be strings

    >>> Indel.normalized_similarity(["lewenstein"], ["levenshtein"], processor=lambda s: s[0])
    0.8571428571428572
    """
    setupPandas()
    if is_none(s1) or is_none(s2):
        return 0.0

    if processor is not None:
        s1 = processor(s1)
        s2 = processor(s2)

    s1, s2 = conv_sequences(s1, s2)
    norm_dist = normalized_distance(s1, s2)
    norm_sim = 1.0 - norm_dist
    return norm_sim if (score_cutoff is None or norm_sim >= score_cutoff) else 0


def _block_normalized_similarity(
    block,
    s1,
    s2,
    score_cutoff=None,
):
    norm_dist = _block_normalized_distance(block, s1, s2)
    norm_sim = 1.0 - norm_dist
    return norm_sim if (score_cutoff is None or norm_sim >= score_cutoff) else 0


def editops(
    s1,
    s2,
    *,
    processor=None,
):
    """
    Return Editops describing how to turn s1 into s2.

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.

    Returns
    -------
    editops : Editops
        edit operations required to turn s1 into s2

    Notes
    -----
    The alignment is calculated using an algorithm of Heikki Hyyrö, which is
    described [6]_. It has a time complexity and memory usage of ``O([N/64] * M)``.

    References
    ----------
    .. [6] Hyyrö, Heikki. "A Note on Bit-Parallel Alignment Computation."
           Stringology (2004).

    Examples
    --------
    >>> from rapidfuzz.distance import Indel
    >>> for tag, src_pos, dest_pos in Indel.editops("qabxcd", "abycdf"):
    ...    print(("%7s s1[%d] s2[%d]" % (tag, src_pos, dest_pos)))
     delete s1[0] s2[0]
     delete s1[3] s2[2]
     insert s1[4] s2[2]
     insert s1[6] s2[5]
    """
    return lcs_seq_editops(s1, s2, processor=processor)


def opcodes(
    s1,
    s2,
    *,
    processor=None,
):
    """
    Return Opcodes describing how to turn s1 into s2.

    Parameters
    ----------
    s1 : Sequence[Hashable]
        First string to compare.
    s2 : Sequence[Hashable]
        Second string to compare.
    processor: callable, optional
        Optional callable that is used to preprocess the strings before
        comparing them. Default is None, which deactivates this behaviour.

    Returns
    -------
    opcodes : Opcodes
        edit operations required to turn s1 into s2

    Notes
    -----
    The alignment is calculated using an algorithm of Heikki Hyyrö, which is
    described [7]_. It has a time complexity and memory usage of ``O([N/64] * M)``.

    References
    ----------
    .. [7] Hyyrö, Heikki. "A Note on Bit-Parallel Alignment Computation."
           Stringology (2004).

    Examples
    --------
    >>> from rapidfuzz.distance import Indel

    >>> a = "qabxcd"
    >>> b = "abycdf"
    >>> for tag, i1, i2, j1, j2 in Indel.opcodes(a, b):
    ...    print(("%7s a[%d:%d] (%s) b[%d:%d] (%s)" %
    ...           (tag, i1, i2, a[i1:i2], j1, j2, b[j1:j2])))
     delete a[0:1] (q) b[0:0] ()
      equal a[1:3] (ab) b[0:2] (ab)
     delete a[3:4] (x) b[2:2] ()
     insert a[4:4] () b[2:3] (y)
      equal a[4:6] (cd) b[3:5] (cd)
     insert a[6:6] () b[5:6] (f)
    """
    return lcs_seq_opcodes(s1, s2, processor=processor)