import std.algorithm, std.array, std.container, std.range;
import std.string, std.conv, std.math;
import std.stdio, std.typecons;

alias Tuple!(int, "v", int, "c") side;

void main()
{
  auto n = readln.chomp.to!int;
  auto sti = iota(n).map!(i => readln.chomp.to!int).array;

  auto graph = new side[][n];

  auto m = readln.chomp.to!int;
  foreach (i; 0..m) {
    auto rd = readln.split.map!(to!int);
    graph[rd[0]] ~= side(rd[1], rd[2]);
    graph[rd[1]] ~= side(rd[0], rd[2]);
  }

  auto min = int.max;
  foreach (s1; 1..(n - 1)) {
    foreach (s2; 1..(n - 1)) {
      if (s1 == s2)
        continue;

      auto r1 = dijkstra(n, 0,  s1,    graph);
      auto r2 = dijkstra(n, s1, s2,    graph);
      auto r3 = dijkstra(n, s2, n - 1, graph);

      if (r1 > 0 && r2 > 0 && r3 > 0) {
        auto r = r1 + r2 + r3 + sti[s1] + sti[s2];
        if (r < min)
          min = r;
      }
    }
  }

  writeln(min);
}

int dijkstra(int n, int s, int e, side[][] graph)
{
  auto memo = new int[n];
  auto visited = new bool[n];
  visited[s] = true;

  auto pq = Array!side().heapify!("a.c > b.c");
  foreach (si; graph[s])
    pq.insert(si);

  while (!pq.empty) {
    auto si = pq.front;
    pq.removeFront;
    if (visited[si.v])
      continue;

    if (si.v == e)
      return si.c;

    memo[si.v] = si.c;
    visited[si.v] = true;

    foreach (c; graph[si.v]) {
      if (!visited[c.v]) {
        pq.insert(side(c.v, si.c + c.c));
      }
    }
  }

  return -1;
}