class DirectedGraph: def __init__(self, order): self._order = order self._size = 0 self._vertex = [[[], []] for _ in range(order)] self._edge = [] def order(self): return self._order def size(self): return self._size def __get__(self, key): if key == 0: return self._vertex elif key == 1: return self._edge def add_vertex(self, *args): self._order += 1 self._vertex.append([[], [], *args]) def add_arc(self, v1, v2, *args): e = self._size self._size += 1 self._vertex[v1][0].append(e) self._vertex[v2][1].append(e) self._edge.append([v1, v2, *args]) def endpoint(self, e, v=None): v1, v2 = self._edge[e][:2] if v is None: return v1, v2 return v ^ v1 ^ v2 def indegree(self, v): return len(self._vertex[v][0]) def outdegree(self, v): return len(self._vertex[v][1]) class UndirectedGraph(DirectedGraph): def add_edge(self, v1, v2, *args): e = self._size self._size += 1 self._vertex[v1][0].append(e) self._vertex[v2][0].append(e) self._edge.append([v1, v2, *args]) def degree(self, v): return len(self._vertex[v][0]) class ConnectedComponents(UndirectedGraph): def __init__(self, order): super().__init__(order) self._components = [] self._component = [] def build(self): for i in range(self._order): self._vertex[i][1] = [-1]*2 self._components.clear() self._component.clear() for i in range(self._order): if self._vertex[i][1][0] != -1: continue comp_idx = len(self._components) self._vertex[i][1] = [comp_idx, 0] que, flg = [i], True for v in que: v_clr = self._vertex[v][1][1] for e in self._vertex[v][0]: v2 = self.endpoint(e, v) if self._vertex[v2][1][0] == -1: self._vertex[v2][1][0] = comp_idx if flg: self._vertex[v2][1][1] = v_clr ^ 1 que.append(v2) elif flg and self._vertex[v2][1][1] == v_clr: flg = False self._components.append([[], [], []]) self._component.append([len(que), 0]) for v in que: if not flg: self._vertex[v][1][1] = -1 v_clr = self._vertex[v][1][1] self._components[comp_idx][v_clr].append(v) self._component[comp_idx][1] += self.degree(v) self._component[comp_idx][1] //= 2 def __call__(self, k=None): if k is None: return self._components return sum(self._components[k], []) def __len__(self): return len(self._components) def order(self, k=None): if k is None: return self._order return self._component[k][0] def size(self, k=None): if k is None: return self._size return self._component[k][1] def __get__(self, key): if key == 2: return self._component return super().__get__(key) def is_connected(self): return len(self._components) <= 1 def is_bipartite(self, k=None): if k is None: return all(not comp[-1] for comp in self._components) return not self._components[-1][3] n, m = map(int, input().split()) X = ConnectedComponents(n) for _ in range(m): a, b = map(int, input().split()) X.add_edge(a-1, b-1) print("Yes" if X.is_bipartite() else "No")