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* ci(pre-commit): Add ``flake8-builtins`` additional dependency to ``pre-commit`` (#7104) * refactor: Fix ``flake8-builtins`` (#7104) * fix(lru_cache): Fix naming conventions in docstrings (#7104) * ci(pre-commit): Order additional dependencies alphabetically (#7104) * fix(lfu_cache): Correct function name in docstring (#7104) * Update strings/snake_case_to_camel_pascal_case.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update data_structures/stacks/next_greater_element.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update digital_image_processing/index_calculation.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update graphs/prim.py Co-authored-by: Christian Clauss <cclauss@me.com> * Update hashes/djb2.py Co-authored-by: Christian Clauss <cclauss@me.com> * refactor: Rename `_builtin` to `builtin_` ( #7104) * fix: Rename all instances (#7104) * refactor: Update variable names (#7104) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * ci: Create ``tox.ini`` and ignore ``A003`` (#7123) * revert: Remove function name changes (#7104) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * Rename tox.ini to .flake8 * Update data_structures/heap/heap.py Co-authored-by: Dhruv Manilawala <dhruvmanila@gmail.com> * refactor: Rename `next_` to `next_item` (#7104) * ci(pre-commit): Add `flake8` plugin `flake8-bugbear` (#7127) * refactor: Follow `flake8-bugbear` plugin (#7127) * fix: Correct `knapsack` code (#7127) * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci Co-authored-by: Christian Clauss <cclauss@me.com> Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Dhruv Manilawala <dhruvmanila@gmail.com>
311 lines
8.2 KiB
Python
311 lines
8.2 KiB
Python
from collections import deque
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def _input(message):
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return input(message).strip().split(" ")
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def initialize_unweighted_directed_graph(
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node_count: int, edge_count: int
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) -> dict[int, list[int]]:
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graph: dict[int, list[int]] = {}
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for i in range(node_count):
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graph[i + 1] = []
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for e in range(edge_count):
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x, y = (int(i) for i in _input(f"Edge {e + 1}: <node1> <node2> "))
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graph[x].append(y)
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return graph
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def initialize_unweighted_undirected_graph(
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node_count: int, edge_count: int
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) -> dict[int, list[int]]:
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graph: dict[int, list[int]] = {}
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for i in range(node_count):
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graph[i + 1] = []
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for e in range(edge_count):
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x, y = (int(i) for i in _input(f"Edge {e + 1}: <node1> <node2> "))
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graph[x].append(y)
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graph[y].append(x)
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return graph
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def initialize_weighted_undirected_graph(
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node_count: int, edge_count: int
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) -> dict[int, list[tuple[int, int]]]:
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graph: dict[int, list[tuple[int, int]]] = {}
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for i in range(node_count):
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graph[i + 1] = []
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for e in range(edge_count):
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x, y, w = (int(i) for i in _input(f"Edge {e + 1}: <node1> <node2> <weight> "))
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graph[x].append((y, w))
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graph[y].append((x, w))
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return graph
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if __name__ == "__main__":
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n, m = (int(i) for i in _input("Number of nodes and edges: "))
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graph_choice = int(
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_input(
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"Press 1 or 2 or 3 \n"
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"1. Unweighted directed \n"
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"2. Unweighted undirected \n"
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"3. Weighted undirected \n"
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)[0]
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)
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g = {
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1: initialize_unweighted_directed_graph,
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2: initialize_unweighted_undirected_graph,
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3: initialize_weighted_undirected_graph,
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}[graph_choice](n, m)
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"""
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--------------------------------------------------------------------------------
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Depth First Search.
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Args : G - Dictionary of edges
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s - Starting Node
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Vars : vis - Set of visited nodes
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S - Traversal Stack
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--------------------------------------------------------------------------------
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"""
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def dfs(g, s):
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vis, _s = {s}, [s]
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print(s)
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while _s:
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flag = 0
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for i in g[_s[-1]]:
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if i not in vis:
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_s.append(i)
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vis.add(i)
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flag = 1
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print(i)
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break
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if not flag:
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_s.pop()
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"""
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--------------------------------------------------------------------------------
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Breadth First Search.
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Args : G - Dictionary of edges
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s - Starting Node
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Vars : vis - Set of visited nodes
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Q - Traversal Stack
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--------------------------------------------------------------------------------
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"""
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def bfs(g, s):
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vis, q = {s}, deque([s])
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print(s)
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while q:
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u = q.popleft()
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for v in g[u]:
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if v not in vis:
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vis.add(v)
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q.append(v)
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print(v)
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"""
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--------------------------------------------------------------------------------
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Dijkstra's shortest path Algorithm
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Args : G - Dictionary of edges
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s - Starting Node
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Vars : dist - Dictionary storing shortest distance from s to every other node
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known - Set of knows nodes
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path - Preceding node in path
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--------------------------------------------------------------------------------
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"""
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def dijk(g, s):
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dist, known, path = {s: 0}, set(), {s: 0}
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while True:
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if len(known) == len(g) - 1:
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break
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mini = 100000
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for i in dist:
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if i not in known and dist[i] < mini:
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mini = dist[i]
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u = i
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known.add(u)
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for v in g[u]:
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if v[0] not in known:
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if dist[u] + v[1] < dist.get(v[0], 100000):
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dist[v[0]] = dist[u] + v[1]
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path[v[0]] = u
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for i in dist:
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if i != s:
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print(dist[i])
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"""
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--------------------------------------------------------------------------------
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Topological Sort
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--------------------------------------------------------------------------------
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"""
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def topo(g, ind=None, q=None):
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if q is None:
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q = [1]
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if ind is None:
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ind = [0] * (len(g) + 1) # SInce oth Index is ignored
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for u in g:
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for v in g[u]:
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ind[v] += 1
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q = deque()
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for i in g:
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if ind[i] == 0:
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q.append(i)
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if len(q) == 0:
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return
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v = q.popleft()
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print(v)
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for w in g[v]:
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ind[w] -= 1
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if ind[w] == 0:
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q.append(w)
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topo(g, ind, q)
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"""
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--------------------------------------------------------------------------------
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Reading an Adjacency matrix
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--------------------------------------------------------------------------------
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"""
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def adjm():
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n = input().strip()
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a = []
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for _ in range(n):
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a.append(map(int, input().strip().split()))
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return a, n
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"""
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--------------------------------------------------------------------------------
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Floyd Warshall's algorithm
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Args : G - Dictionary of edges
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s - Starting Node
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Vars : dist - Dictionary storing shortest distance from s to every other node
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known - Set of knows nodes
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path - Preceding node in path
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--------------------------------------------------------------------------------
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"""
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def floy(a_and_n):
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(a, n) = a_and_n
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dist = list(a)
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path = [[0] * n for i in range(n)]
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for k in range(n):
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for i in range(n):
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for j in range(n):
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if dist[i][j] > dist[i][k] + dist[k][j]:
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dist[i][j] = dist[i][k] + dist[k][j]
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path[i][k] = k
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print(dist)
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"""
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--------------------------------------------------------------------------------
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Prim's MST Algorithm
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Args : G - Dictionary of edges
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s - Starting Node
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Vars : dist - Dictionary storing shortest distance from s to nearest node
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known - Set of knows nodes
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path - Preceding node in path
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--------------------------------------------------------------------------------
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"""
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def prim(g, s):
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dist, known, path = {s: 0}, set(), {s: 0}
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while True:
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if len(known) == len(g) - 1:
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break
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mini = 100000
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for i in dist:
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if i not in known and dist[i] < mini:
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mini = dist[i]
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u = i
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known.add(u)
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for v in g[u]:
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if v[0] not in known:
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if v[1] < dist.get(v[0], 100000):
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dist[v[0]] = v[1]
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path[v[0]] = u
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return dist
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"""
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--------------------------------------------------------------------------------
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Accepting Edge list
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Vars : n - Number of nodes
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m - Number of edges
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Returns : l - Edge list
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n - Number of Nodes
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--------------------------------------------------------------------------------
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"""
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def edglist():
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n, m = map(int, input().split(" "))
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edges = []
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for _ in range(m):
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edges.append(map(int, input().split(" ")))
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return edges, n
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"""
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--------------------------------------------------------------------------------
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Kruskal's MST Algorithm
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Args : E - Edge list
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n - Number of Nodes
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Vars : s - Set of all nodes as unique disjoint sets (initially)
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--------------------------------------------------------------------------------
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"""
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def krusk(e_and_n):
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# Sort edges on the basis of distance
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(e, n) = e_and_n
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e.sort(reverse=True, key=lambda x: x[2])
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s = [{i} for i in range(1, n + 1)]
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while True:
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if len(s) == 1:
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break
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print(s)
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x = e.pop()
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for i in range(len(s)):
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if x[0] in s[i]:
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break
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for j in range(len(s)):
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if x[1] in s[j]:
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if i == j:
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break
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s[j].update(s[i])
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s.pop(i)
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break
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# find the isolated node in the graph
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def find_isolated_nodes(graph):
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isolated = []
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for node in graph:
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if not graph[node]:
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isolated.append(node)
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return isolated
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