Metadata-Version: 2.4
Name: cardy
Version: 0.4.2
Summary: Card sorting utilities to compute edit distances, d-neighbourhoods, d-cliques, orthogonality and more
Author-email: James Ansley <james@ansley.dev>
License-Expression: Apache-2.0
Project-URL: repository, https://codeberg.org/jamesansley/cardy
Requires-Python: >=3.12
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: munkres~=1.1.4
Dynamic: license-file

# Cardy

[![Repository](https://img.shields.io/badge/jamesansley%2Fcardy-102335?logo=codeberg&labelColor=07121A)](https://codeberg.org/jamesansley/cardy)
[![License](https://img.shields.io/badge/Apache--2.0-002d00?label=license)](https://codeberg.org/jamesansley/cardy/src/branch/main/LICENSE)
[![PyPi](https://img.shields.io/pypi/v/cardy?label=PyPi&labelColor=%23ffd343&color=%230073b7)](https://pypi.org/project/cardy/)

Low-level card sorting utilities to compare card sorts — including calculating
edit distances, d-neighbourhoods, d-cliques, and orthogonality of card sorts.

It is recommended to read
[Deibel et al. (2005)](https://doi.org/10.1111/j.1468-0394.2005.00304.x)[^1]
and [Fossum & Haller (2005)](https://doi.org/10.1111/j.1468-0394.2005.00305.x)[^2]
to familiarize yourself with the metrics covered in this library. In fact, that
entire special issue of Expert Systems is excellent reading for anyone
interested in analysing card sorting data.

## Installation

```bash
pip install cardy
```

For the JavaScript version of this library,
see [Cardy on JSR](https://jsr.io/@ansley/cardy).

## Usage

Card sorts are represented as collections of sets of cards: `Colection[Set[T]]`
where each set represents a group.

### Edit Distance

The edit distance between two sorts can be computed with the distance function:

```python
from cardy import distance

sort1 = ({1, 2, 3}, {4, 5, 6}, {7, 8, 9})
sort2 = ({1, 2}, {3, 4}, {5, 6, 7}, {8, 9})

dist = distance(sort1, sort2)
print("Distance:", dist)  # Distance: 3
```

When comparing sorts for equality, assert an edit distance of zero:

```python
if distance(sort1, sort2) == 0:
    ...
```

#### Maximum and Normalised Edit Distances

Normalized edit distances can be computed with the `norm_distance` function:

```python
from cardy import norm_distance

sort1 = (
    {"a1", "a2", "a3"},
    {"b1", "b2", "b3", "b4", "b5"},
    {"c1", "c2", "c3", "c4", "c5"},
    {"d1", "d2", "d3", "d4"},
)
sort2 = (
    {"a1", "b1", "b5", "c1", "c5", "d1"},
    {"a2", "b2", "c2", "d2"},
    {"a3", "b3", "c3", "d3"},
    {"b4", "c4", "d4"},
)

print(norm_distance(sort1, sort2))  # 0.92...
print(norm_distance(sort1, sort2, num_groups=4))  # 1.0
```

The `num_groups` option specifies the normalized distance should be computed
under the assumption the maximum number of groups in either card sort will not
exceed `num_groups`. If this option is not given, distances are normalized with
no limit on the number of groups.

The maximum edit distance any other card sort can be from a given card sort can
be computed with the `max_distance` function.

```python
from cardy import max_distance

# Using sort1 from the previous example
print(max_distance(sort1))  # 13
print(max_distance(sort1, num_groups=4))  # 12
```

As before, the `num_groups` option places a restriction on the maximum number of
groups another card sort may have.

### Cliques and Neighbourhoods

Cliques and neighbourhoods can be calculated using the `clique`
and `neighbourhood` functions. Given a mapping of sort IDs to card sorts:
`Mapping[K, Collection[Set[T]]]`, a neighbourhood or clique is represented as a
set of IDs: `Set[K]` of card sorts

#### Neighbourhoods

Neighbourhoods are always deterministic:

```python
from cardy import neighbourhood

probe = ({1, 2, 3, 4, 5},)
sorts = {
    0: ({1, 2, 3}, {4, 5}),
    1: ({1, 2, 3}, {4, 5}, set()),
    2: ({1, 2}, {3}, {4, 5}),
    3: ({1, 2}, {3, 4}, {5}),
    4: ({1, 2, 4}, {3, 5}),
}

two_neighbourhood = neighbourhood(2, probe, sorts)
print(f"2-neighbourhood around `{probe}`: {two_neighbourhood}")
# 2-neighbourhood around `({1, 2, 3, 4, 5},)`: {0, 1, 4}
```

Neighbourhoods can be calculated using normalized edit distances by passing a
custom edit distance function as a named argument:

```python
dist = lambda probe, sort: norm_distance(probe, sort, num_groups=3)
upper_quart_neighbourhood = neighbourhood(0.75, probe, sorts, distance=dist)
print(f"Sorts within 75% of `{probe}` are {upper_quart_neighbourhood}")
# Sorts within 75% of `({1, 2, 3, 4, 5},)` are {0, 1, 4}
```

#### Cliques

Cliques can be non-deterministic — even when using a greedy strategy (default):

```python
from cardy import clique

probe = ({1, 2}, {3})
sorts = {
    0: ({1}, {2}, {3}),
    1: ({2, 3}, {1}),
    2: ({1, 2, 3},),
}
one_clique = clique(1, probe, sorts)
print(f"1-clique around `{probe}`: {one_clique}")
# 1-clique around `({1, 2}, {3})`: {0, 1}
# OR
# 1-clique around `({1, 2}, {3})`: {1, 2}
```

The clique function allows for various heuristic strategies for selecting
candidate card sorts (via ID). Heuristic functions are of the form:
`(int, Mapping[K, Collection[Set[T]]]) -> K` — that is, a function that takes a
the maximum clique diameter and a key to card sort mapping of viable candidates,
and returns a key of a viable candidate based on some heuristic.

Two heuristic functions have been provided: `random_strategy` and
`greedy_strategy`. `random_strategy` will select a candidate at random.
`greedy_strategy` will select a candidate that reduces the size of the candidate
pool by the smallest amount. In the case two or more candidates reduce the pool
by the same amount, one is selected at random.

This behaviour can be changed by providing a deterministic heuristic function,
or a deterministic `Selector` which provides a select method that picks a
candidate in the case of ambiguity:

```python
from cardy import clique
from cardy.clique import Selector, greedy_strategy


class MinSelector(Selector):
    def select(self, collection):
        # selects the candidate with the smallest key in case of ties
        # for greedy strategy
        return min(collection)


probe = ({1, 2}, {3})
sorts = {
    0: ({1}, {2}, {3}),
    1: ({2, 3}, {1}),
    2: ({1, 2, 3},),
}
one_clique = clique(
    1,
    probe,
    sorts,
    strategy=lambda d, c: greedy_strategy(d, c, MinSelector())
)
print(f"1-clique around `{probe}`: {one_clique}")
# 1-clique around `({1, 2}, {3})`: {0, 1}
```

Alternatively, a seed can be passed to the base `Selector` constructor.

### Orthogonality

The orthogonality of a collection of sorts can be calculated with the
`orthogonality` function:

```python
from cardy import orthogonality

p1 = (
    ({1, 3, 4, 5, 6, 7, 13, 14, 15, 22, 23},
     {2, 8, 9, 10, 11, 12, 16, 17, 18, 19, 20, 21, 24, 25, 26}),
    ({1, 3, 4, 6, 7, 10, 13, 14, 15, 18, 23, 26},
     {2, 5, 8, 9, 11, 12, 16, 17, 19, 20, 21, 22, 24, 25}),
    ({1, 2, 5, 8, 9, 11, 12, 16, 17, 18, 19, 20, 21, 22, 24, 25},
     {3, 4, 6, 7, 10, 13, 14, 15, 23, 26}),
)
p1_orthogonality = orthogonality(p1)
print(f"P1 orthogonality: {p1_orthogonality:.2f}")  # P1 orthogonality: 2.33
```

### Similarity and Dissimilarity Matrices

Card similarity/dissimilarity matrices for a set of card sorts can be computed
with the `similarity_matrix` and `dissimilarity_matrix` functions. These return
an n + 1 by n + 1 similarity matrix where the first row and column are the card
labels. For example, given the following four sorts:

```python
sorts = (
    ({"a1", "a2"}, {"a3", "b1", "b2"}),
    ({"a1", "a2"}, {"a3", "b1", "b2"}),
    ({"a1", "a3", "b1"}, {"a2", "b2"}),
    ({"a1", "a3"}, {"a2", "b1", "b2"}),
)
```

The co-occurrence or co-nonoccurrence of cards can be counted:

```python
from pprint import pprint
from cardy import similarity_matrix, dissimilarity_matrix

pprint(similarity_matrix(sorts))
# [[None, 'a1', 'a2', 'b2', 'a3', 'b1'],
#  ['a1', 4, 2, 0, 2, 1],
#  ['a2', 2, 4, 2, 0, 1],
#  ['b2', 0, 2, 4, 2, 3],
#  ['a3', 2, 0, 2, 4, 3],
#  ['b1', 1, 1, 3, 3, 4]]
pprint(dissimilarity_matrix(sorts))
# [[None, 'a1', 'a2', 'b2', 'a3', 'b1'],
#  ['a1', 0, 2, 4, 2, 3],
#  ['a2', 2, 0, 2, 4, 3],
#  ['b2', 4, 2, 0, 2, 1],
#  ['a3', 2, 4, 2, 0, 1],
#  ['b1', 3, 3, 1, 1, 0]]
```

Or, scaled to be a proportion of times the cards co-occur/nonoccur by providing
the `scale` flag:

```python
from pprint import pprint
from cardy import similarity_matrix, dissimilarity_matrix

pprint(similarity_matrix(sorts, scale=True))
# [[None, 'a1', 'a2', 'b2', 'a3', 'b1'],
#  ['a1', 1.0, 0.5, 0.0, 0.5, 0.25],
#  ['a2', 0.5, 1.0, 0.5, 0.0, 0.25],
#  ['b2', 0.0, 0.5, 1.0, 0.5, 0.75],
#  ['a3', 0.5, 0.0, 0.5, 1.0, 0.75],
#  ['b1', 0.25, 0.25, 0.75, 0.75, 1.0]]
pprint(dissimilarity_matrix(sorts, scale=True))
# [[None, 'a1', 'a2', 'b2', 'a3', 'b1'],
#  ['a1', 0.0, 0.5, 1.0, 0.5, 0.75],
#  ['a2', 0.5, 0.0, 0.5, 1.0, 0.75],
#  ['b2', 1.0, 0.5, 0.0, 0.5, 0.25],
#  ['a3', 0.5, 1.0, 0.5, 0.0, 0.25],
#  ['b1', 0.75, 0.75, 0.25, 0.25, 0.0]]
```

Note that the columns are not guaranteed to be in any particular order.

For programmatic use, it may be more convenient to use the `similarity_mapping`
and `dissimilarity_mapping` functions. These behave in the same way as their
matrix counterparts, but return the results as a nested map:

```python
from pprint import pprint
from cardy import similarity_mapping

pprint(similarity_mapping(sorts))
# {'a1': {'a1': 4, 'a2': 2, 'a3': 2, 'b1': 1, 'b2': 0},
#  'a2': {'a1': 2, 'a2': 4, 'a3': 0, 'b1': 1, 'b2': 2},
#  'a3': {'a1': 2, 'a2': 0, 'a3': 4, 'b1': 3, 'b2': 2},
#  'b1': {'a1': 1, 'a2': 1, 'a3': 3, 'b1': 4, 'b2': 3},
#  'b2': {'a1': 0, 'a2': 2, 'a3': 2, 'b1': 3, 'b2': 4}}
```

As before, a `scale` flag can be given to scale results to a proportion of
sorts.

### Counting Sorts

The `n_sorts` function returns the number of possible configurations in which
`c`
cards can be sorted. This is, in effect, the `c`th
[Bell Number](https://en.wikipedia.org/wiki/Bell_number)[^3]:

```python
from cardy import n_sorts

print(n_sorts(5))  # 52
print(n_sorts(10))  # 115975
print(n_sorts(15))  # 1382958545
print(n_sorts(20))  # 51724158235372
```

Providing a second parameter to `n_sorts` will count the number of possible
configurations of sorting `c` cards into at most `g` groups:

```python
from cardy import n_sorts

print(n_sorts(5, 3))  # 41
print(n_sorts(10, 3))  # 9842
print(n_sorts(15, 3))  # 2391485
print(n_sorts(20, 3))  # 581130734
```

To compute the number of card sorts of `c` cards into exactly `g` groups,
subtract `n_sorts(c, g - 1)` from `n_sorts(c, g)`:

```python
from cardy import n_sorts

print(n_sorts(5, 3) - n_sorts(5, 2))  # 25
print(n_sorts(10, 3) - n_sorts(10, 2))  # 9330
print(n_sorts(15, 3) - n_sorts(15, 2))  # 2375101
print(n_sorts(20, 3) - n_sorts(20, 2))  # 580606446
```


[^1]: Deibel, K., Anderson, R. and Anderson, R. (2005), Using edit distance to
analyze card sorts. Expert Systems, 22: 129-138.
https://doi.org/10.1111/j.1468-0394.2005.00304.x

[^2]: Fossum, T. and Haller, S. (2005), Measuring card sort orthogonality.
Expert Systems, 22: 139-146. https://doi.org/10.1111/j.1468-0394.2005.00305.x

[^3]: https://en.wikipedia.org/wiki/Bell_number
