Added edmonds_blossom_algorithm.py. For maximum matching in the graph.

graphs/edmonds_blossom_algorithm.py

@@ -0,0 +1,236 @@
+from collections import defaultdict, deque
+
+UNMATCHED = -1  # Constant to represent unmatched vertices
+
+
+class EdmondsBlossomAlgorithm:
+    @staticmethod
+    def maximum_matching(edges: list[tuple[int, int]], vertex_count: int) \
+            -> list[tuple[int, int]]:
+        """
+        Finds the maximum matching in a general graph using Edmonds' Blossom Algorithm.
+
+        :param edges: List of edges in the graph.
+        :param vertex_count: Number of vertices in the graph.
+        :return: A list of matched pairs of vertices.
+
+        >>> EdmondsBlossomAlgorithm.maximum_matching([(0, 1), (1, 2), (2, 3)], 4)
+        [(0, 1), (2, 3)]
+        """
+        graph: dict[int, list[int]] = defaultdict(list)
+
+        # Populate the graph with the edges
+        for vertex_u, vertex_v in edges:
+            graph[vertex_u].append(vertex_v)
+            graph[vertex_v].append(vertex_u)
+
+        # Initial matching array and auxiliary data structures
+        match = [UNMATCHED] * vertex_count
+        parent = [UNMATCHED] * vertex_count
+        base = list(range(vertex_count))
+        in_blossom = [False] * vertex_count
+        in_queue = [False] * vertex_count
+
+        # Main logic for finding maximum matching
+        for vertex_u in range(vertex_count):
+            if match[vertex_u] == UNMATCHED:
+                # BFS initialization
+                parent = [UNMATCHED] * vertex_count
+                base = list(range(vertex_count))
+                in_blossom = [False] * vertex_count
+                in_queue = [False] * vertex_count
+
+                queue = deque([vertex_u])
+                in_queue[vertex_u] = True
+
+                augmenting_path_found = False
+
+                # BFS to find augmenting paths
+                while queue and not augmenting_path_found:
+                    current_vertex = queue.popleft()
+                    for neighbor in graph[current_vertex]:
+                        if match[current_vertex] == neighbor:
+                            continue
+
+                        if base[current_vertex] == base[neighbor]:
+                            continue  # Avoid self-loops
+
+                        if parent[neighbor] == UNMATCHED:
+                            # Case 1: neighbor is unmatched,
+                            # we've found an augmenting path
+                            if match[neighbor] == UNMATCHED:
+                                parent[neighbor] = current_vertex
+                                augmenting_path_found = True
+                                EdmondsBlossomAlgorithm.update_matching(
+                                    match, parent, neighbor
+                                )
+                                break
+
+                            # Case 2: neighbor is matched,
+                            # add neighbor's match to the queue
+                            matched_vertex = match[neighbor]
+                            parent[neighbor] = current_vertex
+                            parent[matched_vertex] = neighbor
+                            if not in_queue[matched_vertex]:
+                                queue.append(matched_vertex)
+                                in_queue[matched_vertex] = True
+                        else:
+                            # Case 3: Both current_vertex and neighbor have a parent;
+                            # check for a cycle/blossom
+                            base_vertex = EdmondsBlossomAlgorithm.find_base(
+                                base, parent, current_vertex, neighbor
+                            )
+                            if base_vertex != UNMATCHED:
+                                EdmondsBlossomAlgorithm.contract_blossom(
+                                    BlossomData(
+                                        BlossomAuxData(
+                                            queue, parent, base, in_blossom,
+                                            match, in_queue
+                                        ),
+                                        current_vertex, neighbor, base_vertex
+                                    )
+                                )
+
+        # Create result list of matched pairs
+        matching_result = []
+        for vertex in range(vertex_count):
+            if match[vertex] != UNMATCHED and vertex < match[vertex]:
+                matching_result.append((vertex, match[vertex]))
+
+        return matching_result
+
+    @staticmethod
+    def update_matching(match: list[int],
+                        parent: list[int], current_vertex: int) -> None:
+        """
+        Updates the matching along the augmenting path found.
+
+        :param match: The matching array.
+        :param parent: The parent array used during the BFS.
+        :param current_vertex: The starting node of the augmenting path.
+
+        >>> match = [UNMATCHED, UNMATCHED, UNMATCHED]
+        >>> parent = [1, 0, UNMATCHED]
+        >>> EdmondsBlossomAlgorithm.update_matching(match, parent, 2)
+        >>> match
+        [1, 0, -1]
+        """
+        while current_vertex != UNMATCHED:
+            matched_vertex = parent[current_vertex]
+            next_vertex = match[matched_vertex]
+            match[matched_vertex] = current_vertex
+            match[current_vertex] = matched_vertex
+            current_vertex = next_vertex
+
+    @staticmethod
+    def find_base(
+        base: list[int], parent: list[int], vertex_u: int, vertex_v: int
+    ) -> int:
+        """
+        Finds the base of a node in the blossom.
+
+        :param base: The base array.
+        :param parent: The parent array.
+        :param vertex_u: One end of the edge.
+        :param vertex_v: The other end of the edge.
+        :return: The base of the node or UNMATCHED.
+
+        >>> base = [0, 1, 2, 3]
+        >>> parent = [1, 0, UNMATCHED, UNMATCHED]
+        >>> EdmondsBlossomAlgorithm.find_base(base, parent, 2, 3)
+        2
+        """
+        visited = [False] * len(base)
+
+        # Mark ancestors of vertex_u
+        current_vertex_u = vertex_u
+        while True:
+            current_vertex_u = base[current_vertex_u]
+            visited[current_vertex_u] = True
+            if parent[current_vertex_u] == UNMATCHED:
+                break
+            current_vertex_u = parent[current_vertex_u]
+
+        # Find the common ancestor of vertex_v
+        current_vertex_v = vertex_v
+        while True:
+            current_vertex_v = base[current_vertex_v]
+            if visited[current_vertex_v]:
+                return current_vertex_v
+            current_vertex_v = parent[current_vertex_v]
+
+    @staticmethod
+    def contract_blossom(blossom_data: 'BlossomData') -> None:
+        """
+        Contracts a blossom in the graph, modifying the base array
+        and marking the vertices involved.
+
+        :param blossom_data: An object containing the necessary data
+        to perform the contraction.
+
+        >>> aux_data = BlossomAuxData(deque(), [], [], [], [], [])
+        >>> blossom_data = BlossomData(aux_data, 0, 1, 2)
+        >>> EdmondsBlossomAlgorithm.contract_blossom(blossom_data)
+        """
+        # Mark all vertices in the blossom
+        current_vertex_u = blossom_data.u
+        while blossom_data.aux_data.base[current_vertex_u] != blossom_data.lca:
+            base_u = blossom_data.aux_data.base[current_vertex_u]
+            match_base_u = blossom_data.aux_data.base[blossom_data.aux_data.match
+                                        [current_vertex_u]
+                                        ]
+            blossom_data.aux_data.in_blossom[base_u] = True
+            blossom_data.aux_data.in_blossom[match_base_u] = True
+            current_vertex_u = blossom_data.aux_data.parent[
+                blossom_data.aux_data.match[current_vertex_u]
+            ]
+
+        current_vertex_v = blossom_data.v
+        while blossom_data.aux_data.base[current_vertex_v] != blossom_data.lca:
+            base_v = blossom_data.aux_data.base[current_vertex_v]
+            match_base_v = blossom_data.aux_data.base[blossom_data.aux_data.match
+                                                [current_vertex_v]
+                                                ]
+            blossom_data.aux_data.in_blossom[base_v] = True
+            blossom_data.aux_data.in_blossom[match_base_v] = True
+            current_vertex_v = blossom_data.aux_data.parent[
+                blossom_data.aux_data.match[current_vertex_v]
+            ]
+
+        # Update the base for all marked vertices
+        for i in range(len(blossom_data.aux_data.base)):
+            if blossom_data.aux_data.in_blossom[blossom_data.aux_data.base[i]]:
+                blossom_data.aux_data.base[i] = blossom_data.lca
+                if not blossom_data.aux_data.in_queue[i]:
+                    blossom_data.aux_data.queue.append(i)
+                    blossom_data.aux_data.in_queue[i] = True
+
+
+class BlossomAuxData:
+    """
+    Auxiliary data class to encapsulate common parameters for the blossom operations.
+    """
+
+    def __init__(
+        self, queue: deque, parent: list[int], base: list[int], in_blossom: list[bool],
+        match: list[int], in_queue: list[bool]
+    ) -> None:
+        self.queue = queue
+        self.parent = parent
+        self.base = base
+        self.in_blossom = in_blossom
+        self.match = match
+        self.in_queue = in_queue
+
+
+class BlossomData:
+    """
+    BlossomData class with reduced parameters.
+    """
+
+    def __init__(self, aux_data: BlossomAuxData, u: int, v: int, lca: int) -> None:
+        self.aux_data = aux_data
+        self.u = u
+        self.v = v
+        self.lca = lca
+