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USSU Algorithm Analyzer v4.0 - Graph Algorithms Suite
BFS, DFS, Shortest Path, MST, DAG, SCC, Topological Sort, and more.
"""
import heapq
import time
from collections import deque, defaultdict
from typing import Dict, List, Set, Tuple, Optional, Any
from utils.core import profile_algorithm, Graph, OperationCounter
class GraphAlgorithms(OperationCounter):
"""Complete graph algorithm suite with step tracking"""
def __init__(self):
super().__init__()
self.traversal_steps: List[Dict] = []
def reset(self):
self.reset_counters()
self.traversal_steps = []
def _make_result(self, name: str, time_c: str, space_c: str, **kwargs) -> Dict:
base = {
'algorithm': name,
'time_complexity': time_c,
'space_complexity': space_c,
'comparisons': self.comparisons,
'accesses': self.accesses,
'iterations': self.iterations,
}
base.update(kwargs)
return base
# ==================== BFS ====================
@profile_algorithm
def bfs(self, graph: Graph, start: int, target: Optional[int] = None) -> Dict:
self.reset()
visited = set()
queue = deque([(start, [start])])
traversal = []
levels = {start: 0}
parent = {start: None}
while queue:
self.iterations += 1
vertex, path = queue.popleft()
if vertex not in visited:
visited.add(vertex)
traversal.append(vertex)
self.traversal_steps.append({'node': vertex, 'frontier': list(queue), 'visited': list(visited)})
if target is not None and vertex == target:
return self._make_result('BFS', 'O(V + E)', 'O(V)',
traversal=traversal, path=path, levels=levels, parent=parent,
found=True, distance=len(path)-1, vertices=len(graph.vertices), edges=graph.edge_count)
for neighbor, _ in graph.get_neighbors(vertex):
self.accesses += 1
if neighbor not in visited:
queue.append((neighbor, path + [neighbor]))
levels[neighbor] = levels[vertex] + 1
parent[neighbor] = vertex
return self._make_result('BFS', 'O(V + E)', 'O(V)',
traversal=traversal, path=[], levels=levels, parent=parent,
found=False, vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== DFS ====================
@profile_algorithm
def dfs_iterative(self, graph: Graph, start: int, target: Optional[int] = None) -> Dict:
self.reset()
visited = set()
stack = [(start, [start])]
traversal = []
while stack:
self.iterations += 1
vertex, path = stack.pop()
if vertex not in visited:
visited.add(vertex)
traversal.append(vertex)
self.traversal_steps.append({'node': vertex, 'frontier': list(stack), 'visited': list(visited)})
if target is not None and vertex == target:
return self._make_result('DFS (Iterative)', 'O(V + E)', 'O(V)',
traversal=traversal, path=path, found=True, vertices=len(graph.vertices), edges=graph.edge_count)
for neighbor, _ in reversed(graph.get_neighbors(vertex)):
self.accesses += 1
if neighbor not in visited:
stack.append((neighbor, path + [neighbor]))
return self._make_result('DFS (Iterative)', 'O(V + E)', 'O(V)',
traversal=traversal, path=[], found=False, vertices=len(graph.vertices), edges=graph.edge_count)
@profile_algorithm
def dfs_recursive(self, graph: Graph, start: int, target: Optional[int] = None) -> Dict:
self.reset()
visited = set()
traversal = []
path_found = []
def dfs_helper(vertex, path):
self.recursions += 1
if vertex in visited:
return False
visited.add(vertex)
traversal.append(vertex)
self.traversal_steps.append({'node': vertex, 'visited': list(visited)})
if target is not None and vertex == target:
path_found.extend(path)
return True
for neighbor, _ in graph.get_neighbors(vertex):
self.accesses += 1
if dfs_helper(neighbor, path + [neighbor]):
return True
return False
found = dfs_helper(start, [start])
return self._make_result('DFS (Recursive)', 'O(V + E)', 'O(V)',
traversal=traversal, path=path_found if found else [],
found=found, vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== DIJKSTRA ====================
@profile_algorithm
def dijkstra(self, graph: Graph, start: int, target: Optional[int] = None) -> Dict:
self.reset()
if not graph.weighted:
return self.bfs(graph, start, target)
distances = {v: float('inf') for v in graph.vertices}
distances[start] = 0
parent = {v: None for v in graph.vertices}
visited = set()
pq = [(0, start)]
while pq:
self.iterations += 1
dist, vertex = heapq.heappop(pq)
if vertex in visited:
continue
visited.add(vertex)
if target is not None and vertex == target:
break
for neighbor, weight in graph.get_neighbors(vertex):
self.accesses += 1
self.comparisons += 1
w = weight if weight is not None else 1
new_dist = dist + w
if new_dist < distances[neighbor]:
distances[neighbor] = new_dist
parent[neighbor] = vertex
heapq.heappush(pq, (new_dist, neighbor))
# Reconstruct path
path = []
if target is not None and distances[target] != float('inf'):
curr = target
while curr is not None:
path.append(curr)
curr = parent[curr]
path.reverse()
return self._make_result('Dijkstra', 'O((V+E) log V)', 'O(V)',
distances=distances, parent=parent, path=path,
vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== BELLMAN-FORD ====================
@profile_algorithm
def bellman_ford(self, graph: Graph, start: int) -> Dict:
self.reset()
distances = {v: float('inf') for v in graph.vertices}
distances[start] = 0
parent = {v: None for v in graph.vertices}
V = len(graph.vertices)
for i in range(V - 1):
updated = False
for u, v, w in graph.edges:
weight = w if w is not None else 1
if distances[u] != float('inf') and distances[u] + weight < distances[v]:
distances[v] = distances[u] + weight
parent[v] = u
updated = True
self.comparisons += 1
if not updated:
break
# Negative cycle check
for u, v, w in graph.edges:
weight = w if w is not None else 1
if distances[u] != float('inf') and distances[u] + weight < distances[v]:
return self._make_result('Bellman-Ford', 'O(V × E)', 'O(V)', error='Negative cycle detected')
return self._make_result('Bellman-Ford', 'O(V × E)', 'O(V)',
distances=distances, parent=parent, vertices=V, edges=graph.edge_count)
# ==================== FLOYD-WARSHALL ====================
@profile_algorithm
def floyd_warshall(self, graph: Graph) -> Dict:
self.reset()
n = max(graph.vertices) + 1 if graph.vertices else 0
dist = [[float('inf')] * n for _ in range(n)]
next_v = [[None] * n for _ in range(n)]
for i in range(n):
dist[i][i] = 0
for u in graph.vertices:
for v, w in graph.get_neighbors(u):
weight = w if w is not None else 1
dist[u][v] = weight
next_v[u][v] = v
for k in range(n):
for i in range(n):
for j in range(n):
self.iterations += 1
self.comparisons += 1
if dist[i][k] + dist[k][j] < dist[i][j]:
dist[i][j] = dist[i][k] + dist[k][j]
next_v[i][j] = next_v[i][k]
return self._make_result('Floyd-Warshall', 'O(V³)', 'O(V²)',
distances=dist, next_vertex=next_v, vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== PRIM MST ====================
@profile_algorithm
def prim_mst(self, graph: Graph) -> Dict:
self.reset()
if graph.directed:
return self._make_result("Prim's MST", 'O((V+E) log V)', 'O(V)', error='Graph must be undirected')
start = min(graph.vertices)
visited = {start}
mst_edges = []
total_weight = 0
pq = []
for neighbor, weight in graph.get_neighbors(start):
w = weight if weight is not None else 1
heapq.heappush(pq, (w, start, neighbor))
while pq and len(visited) < len(graph.vertices):
self.iterations += 1
weight, u, v = heapq.heappop(pq)
if v in visited:
continue
visited.add(v)
mst_edges.append((u, v, weight))
total_weight += weight
for neighbor, w in graph.get_neighbors(v):
edge_weight = w if w is not None else 1
if neighbor not in visited:
heapq.heappush(pq, (edge_weight, v, neighbor))
return self._make_result("Prim's MST", 'O((V+E) log V)', 'O(V)',
mst_edges=mst_edges, total_weight=total_weight,
vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== KRUSKAL MST ====================
@profile_algorithm
def kruskal_mst(self, graph: Graph) -> Dict:
self.reset()
if graph.directed:
return self._make_result("Kruskal's MST", 'O(E log E)', 'O(V)', error='Graph must be undirected')
parent = {v: v for v in graph.vertices}
rank = {v: 0 for v in graph.vertices}
def find(v):
if parent[v] != v:
parent[v] = find(parent[v])
return parent[v]
def union(u, v):
ru, rv = find(u), find(v)
if ru != rv:
if rank[ru] < rank[rv]:
parent[ru] = rv
elif rank[ru] > rank[rv]:
parent[rv] = ru
else:
parent[rv] = ru
rank[ru] += 1
edges = sorted(graph.edges, key=lambda x: x[2] if x[2] is not None else 1)
mst_edges = []
total_weight = 0
for u, v, w in edges:
weight = w if w is not None else 1
if find(u) != find(v):
union(u, v)
mst_edges.append((u, v, weight))
total_weight += weight
if len(mst_edges) == len(graph.vertices) - 1:
break
return self._make_result("Kruskal's MST", 'O(E log E)', 'O(V)',
mst_edges=mst_edges, total_weight=total_weight,
vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== LONGEST PATH DAG ====================
@profile_algorithm
def longest_path_dag(self, graph: Graph, start: int) -> Dict:
self.reset()
in_degree = {v: 0 for v in graph.vertices}
for u in graph.vertices:
for v, _ in graph.get_neighbors(u):
in_degree[v] += 1
queue = deque([v for v in graph.vertices if in_degree[v] == 0])
topo_order = []
while queue:
self.iterations += 1
vertex = queue.popleft()
topo_order.append(vertex)
for neighbor, _ in graph.get_neighbors(vertex):
in_degree[neighbor] -= 1
if in_degree[neighbor] == 0:
queue.append(neighbor)
distances = {v: float('-inf') for v in graph.vertices}
distances[start] = 0
parent = {v: None for v in graph.vertices}
for vertex in topo_order:
if distances[vertex] != float('-inf'):
for neighbor, weight in graph.get_neighbors(vertex):
w = weight if weight is not None else 1
if distances[vertex] + w > distances[neighbor]:
distances[neighbor] = distances[vertex] + w
parent[neighbor] = vertex
return self._make_result('Longest Path (DAG)', 'O(V + E)', 'O(V)',
distances=distances, parent=parent, topological_order=topo_order,
vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== TOPOLOGICAL SORT (Kahn) ====================
@profile_algorithm
def topological_sort(self, graph: Graph) -> Dict:
self.reset()
in_degree = {v: 0 for v in graph.vertices}
for u in graph.vertices:
for v, _ in graph.get_neighbors(u):
in_degree[v] += 1
queue = deque([v for v in graph.vertices if in_degree[v] == 0])
topo_order = []
while queue:
self.iterations += 1
vertex = queue.popleft()
topo_order.append(vertex)
for neighbor, _ in graph.get_neighbors(vertex):
in_degree[neighbor] -= 1
if in_degree[neighbor] == 0:
queue.append(neighbor)
valid = len(topo_order) == len(graph.vertices)
return self._make_result('Topological Sort (Kahn)', 'O(V + E)', 'O(V)',
topological_order=topo_order, valid=valid,
vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== SCC (KOSARAJU) ====================
@profile_algorithm
def kosaraju_scc(self, graph: Graph) -> Dict:
self.reset()
if not graph.directed:
return self._make_result('Kosaraju SCC', 'O(V + E)', 'O(V)', error='Graph must be directed')
visited = set()
finish_order = []
def dfs1(v):
self.recursions += 1
visited.add(v)
for neighbor, _ in graph.get_neighbors(v):
if neighbor not in visited:
dfs1(neighbor)
finish_order.append(v)
for v in graph.vertices:
if v not in visited:
dfs1(v)
# Build transpose
transpose = Graph(directed=True)
for v in graph.vertices:
transpose.add_vertex(v)
for u, v, w in graph.edges:
transpose.add_edge(v, u, w if w else 1)
visited.clear()
sccs = []
for v in reversed(finish_order):
if v not in visited:
stack = [v]
component = []
while stack:
node = stack.pop()
if node not in visited:
visited.add(node)
component.append(node)
for neighbor, _ in transpose.get_neighbors(node):
if neighbor not in visited:
stack.append(neighbor)
sccs.append(component)
return self._make_result('Kosaraju SCC', 'O(V + E)', 'O(V)',
sccs=sccs, count=len(sccs), vertices=len(graph.vertices), edges=graph.edge_count)
# ==================== A* SEARCH ====================
@profile_algorithm
def a_star(self, graph: Graph, start: int, target: int, heuristic: Optional[Dict[int, float]] = None) -> Dict:
self.reset()
if heuristic is None:
heuristic = {v: 0 for v in graph.vertices}
g_score = {v: float('inf') for v in graph.vertices}
g_score[start] = 0
f_score = {v: float('inf') for v in graph.vertices}
f_score[start] = heuristic.get(start, 0)
parent = {v: None for v in graph.vertices}
open_set = [(f_score[start], start)]
visited = set()
while open_set:
self.iterations += 1
_, current = heapq.heappop(open_set)
if current in visited:
continue
visited.add(current)
if current == target:
path = []
curr = target
while curr is not None:
path.append(curr)
curr = parent[curr]
path.reverse()
return self._make_result('A* Search', 'O((V+E) log V)', 'O(V)',
path=path, cost=g_score[target], found=True,
vertices=len(graph.vertices), edges=graph.edge_count)
for neighbor, weight in graph.get_neighbors(current):
self.accesses += 1
self.comparisons += 1
w = weight if weight is not None else 1
tentative = g_score[current] + w
if tentative < g_score[neighbor]:
parent[neighbor] = current
g_score[neighbor] = tentative
f_score[neighbor] = tentative + heuristic.get(neighbor, 0)
heapq.heappush(open_set, (f_score[neighbor], neighbor))
return self._make_result('A* Search', 'O((V+E) log V)', 'O(V)',
path=[], cost=float('inf'), found=False,
vertices=len(graph.vertices), edges=graph.edge_count)
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