# #    ⋀_⋀  #   (・ω・) # ./ U ∽ U\ # │* 合 *│ # │* 格 *│ # │* 祈 *│ # │* 願 *│ # │*   *│ #  ̄ # import sys sys.setrecursionlimit(10**6) input=sys.stdin.readline from math import floor,ceil,sqrt,factorial,log #log2ないyp from heapq import heappop, heappush, heappushpop from collections import Counter,defaultdict,deque from itertools import accumulate,permutations,combinations,product,combinations_with_replacement from bisect import bisect_left,bisect_right from copy import deepcopy inf=float('inf') mod = 10**9+7 def pprint(*A): for a in A: print(*a,sep='\n') def INT_(n): return int(n)-1 def MI(): return map(int,input().split()) def MF(): return map(float, input().split()) def MI_(): return map(INT_,input().split()) def LI(): return list(MI()) def LI_(): return [int(x) - 1 for x in input().split()] def LF(): return list(MF()) def LIN(n:int): return [I() for _ in range(n)] def LLIN(n: int): return [LI() for _ in range(n)] def LLIN_(n: int): return [LI_() for _ in range(n)] def LLI(): return [list(map(int, l.split() )) for l in input()] def I(): return int(input()) def F(): return float(input()) def ST(): return input().replace('\n', '') class Dinitz: #edge := (to, capa, rev_index) def __init__(self, N): self.__N = N self.__Graph = [[] for _ in range(N)] #to, capa, rev_index self.__level = [0] * N self.__iter = [0]*N def add_edge(self, from_, to, capa): self.__Graph[from_].append([to, capa, len(self.__Graph[to])]) self.__Graph[to].append([from_, 0, len(self.__Graph[from_])-1 ]) def solve(self, source:int, target:int): self.__target = target flow = 0 while self.leveling_bfs(source): self.__iter = [0] * self.__N while True: delta = self.dfs(source, inf) if not delta: break flow += delta return flow def leveling_bfs(self, source: int) -> bool: self.__level = [-1] * self.__N self.__level[source] = 0 queue = deque([source]) pop = queue.popleft append = queue.append while queue: from_ = pop() for to, capa, _ in self.__Graph[from_]: if capa > 0 > self.__level[to]: self.__level[to] = self.__level[from_] + 1 append(to) return self.__level[self.__target] != -1 #到達可能ならTrue def dfs(self, from_:int, flow:int) ->int: if from_ == self.__target: return flow for i in range(self.__iter[from_], len(self.__Graph[from_])): self.__iter[from_] = i to, capa, rev = edge = self.__Graph[from_][i] if capa and self.__level[from_] < self.__level[to]: delta = self.dfs(to, min(flow,capa)) if delta: #増加パス edge[1] -= delta #capaをへらす self.__Graph[to][rev][1] += delta #逆辺のcapaを増やす return delta return 0 def main(): N,M,D = MI() UVPQW = [] times = [set()for _ in range(N)] for _ in range(M): u,v,p,q,w = MI() u-=1 v-=1 UVPQW.append((u,v,p,q,w)) times[u].add(p) times[v].add(q+D) for i,n in enumerate(times): times[i] = sorted(list(n)) ID = [{} for _ in range(N)] cnt = 0 for i,time in enumerate(times): for t in time: ID[i][t] = cnt cnt += 1 dinic = Dinitz(cnt) add_edge = dinic.add_edge solve = dinic.solve #飛行機で移動する辺 for u,v,p,q,w in UVPQW: from_ = ID[u][p] to = ID[v][q+D] add_edge(from_, to, w) #空港で待つ辺 for i,time in enumerate(times): for j,t in enumerate(time[:-1]): from_ = ID[i][t] to_time = time[j+1] to = ID[i][to_time] add_edge(from_, to, inf) ans = solve(0,cnt-1) print(ans) edges = [[]for _ in range(N)] """ for _ in range(M): edges[u].append(v) nodes # uvpqw=[] for _ in range(M): u-=1 v-=1 uvpqw.append() ans = solve(0,N-1)""" if __name__ == '__main__': main()