import sys input = sys.stdin.readline # https://tjkendev.github.io/procon-library/python/min_cost_flow/primal-dual.html # 最小費用流(minimum cost flow) class MinCostFlow: def __init__(self, n): self.n = n self.G = [[] for i in range(n)] def addEdge(self, f, t, cap, cost): # [to, cap, cost, rev] self.G[f].append([t, cap, cost, len(self.G[t])]) self.G[t].append([f, 0, -cost, len(self.G[f])-1]) def minCostFlow(self, s, t, f): n = self.n G = self.G prevv = [0]*n; preve = [0]*n INF = 10**9+7 res = 0 while f: dist = [INF]*n dist[s] = 0 update = 1 while update: update = 0 for v in range(n): if dist[v] == INF: continue gv = G[v] for i in range(len(gv)): to, cap, cost, rev = gv[i] if cap > 0 and dist[v] + cost < dist[to]: dist[to] = dist[v] + cost prevv[to] = v; preve[to] = i update = 1 if dist[t] == INF: return -1 d = f; v = t while v != s: d = min(d, G[prevv[v]][preve[v]][1]) v = prevv[v] f -= d res += d * dist[t] v = t while v != s: e = G[prevv[v]][preve[v]] e[1] -= d G[v][e[3]][1] += d v = prevv[v] return res N, M = map(int, input().split()) G = MinCostFlow(N) for i in range(M): u, v, c, d = map(int, input().split()) u, v = u - 1, v - 1 G.addEdge(u, v, 1, c) G.addEdge(u, v, 1, d) G.addEdge(v, u, 1, c) G.addEdge(v, u, 1, d) print(G.minCostFlow(0, N-1, 2))