using System; using System.Collections.Generic; using System.Linq; using System.IO; using System.Threading; using System.Text; using System.Text.RegularExpressions; using System.Diagnostics; using static util; using P = pair; class Program { static void Main(string[] args) { var sw = new StreamWriter(Console.OpenStandardOutput()) { AutoFlush = false }; var solver = new Solver(sw); // var t = new Thread(solver.solve, 1 << 28); // 256 MB // t.Start(); // t.Join(); solver.solve(); sw.Flush(); } } class Solver { StreamWriter sw; Scan sc; void Prt(string a) => sw.WriteLine(a); void Prt(IEnumerable a) => Prt(string.Join(" ", a)); void Prt(params object[] a) => Prt(string.Join(" ", a)); public Solver(StreamWriter sw) { this.sw = sw; this.sc = new Scan(); } public void solve() { int n = sc.Int; var a = sc.LongArr; var sg = new LazySegtree(n, Math.Min, (x, y, l, r) => x + y, (x, y) => x + y, LM, a); int q = sc.Int; for (int i = 0; i < q; i++) { int k, l, r, c; sc.Multi(out k, out l, out r, out c); --l; if (k == 1) { sg.update(l, r, c); } else { Prt(sg.run(l, r)); } } } } class pair : IComparable> { public T v1; public U v2; public pair() : this(default(T), default(U)) {} public pair(T v1, U v2) { this.v1 = v1; this.v2 = v2; } public int CompareTo(pair a) { int c = Comparer.Default.Compare(v1, a.v1); return c != 0 ? c : Comparer.Default.Compare(v2, a.v2); } public override string ToString() => v1 + " " + v2; public void Deconstruct(out T a, out U b) { a = v1; b = v2; } } static class util { public static readonly int M = 1000000007; // public static readonly int M = 998244353; public static readonly long LM = 1L << 60; public static readonly double eps = 1e-11; public static void DBG(string a) => Console.Error.WriteLine(a); public static void DBG(IEnumerable a) => DBG(string.Join(" ", a)); public static void DBG(params object[] a) => DBG(string.Join(" ", a)); public static void Assert(params bool[] conds) { if (conds.Any(x => !x)) throw new Exception(); } public static pair make_pair(T v1, U v2) => new pair(v1, v2); public static int CompareList(IList a, IList b) where T : IComparable { for (int i = 0; i < a.Count && i < b.Count; i++) if (a[i].CompareTo(b[i]) != 0) return a[i].CompareTo(b[i]); return a.Count.CompareTo(b.Count); } public static bool inside(int i, int j, int h, int w) => i >= 0 && i < h && j >= 0 && j < w; public static readonly int[] dd = { 0, 1, 0, -1 }; // static readonly string dstring = "RDLU"; public static IEnumerable

adjacents(int i, int j) => Enumerable.Range(0, dd.Length).Select(k => new P(i + dd[k], j + dd[k ^ 1])); public static IEnumerable

adjacents(int i, int j, int h, int w) => adjacents(i, j).Where(p => inside(p.v1, p.v2, h, w)); public static IEnumerable

adjacents(this P p) => adjacents(p.v1, p.v2); public static IEnumerable

adjacents(this P p, int h, int w) => adjacents(p.v1, p.v2, h, w); public static IEnumerable all_subset(this int p) { for (int i = 0; ; i = i - p & p) { yield return i; if (i == p) break; } } public static Dictionary compress(this IEnumerable a) => a.Distinct().OrderBy(v => v).Select((v, i) => new { v, i }).ToDictionary(p => p.v, p => p.i); public static Dictionary compress(params IEnumerable[] a) => compress(a.SelectMany(x => x)); public static T[] inv(this Dictionary dic) { var res = new T[dic.Count]; foreach (var item in dic) res[item.Value] = item.Key; return res; } public static void swap(ref T a, ref T b) where T : struct { var t = a; a = b; b = t; } public static void swap(this IList a, int i, int j) where T : struct { var t = a[i]; a[i] = a[j]; a[j] = t; } public static T[] copy(this IList a) { var ret = new T[a.Count]; for (int i = 0; i < a.Count; i++) ret[i] = a[i]; return ret; } } class Scan { StreamReader sr; public Scan() { sr = new StreamReader(Console.OpenStandardInput()); } public Scan(string path) { sr = new StreamReader(path); } public int Int => int.Parse(Str); public long Long => long.Parse(Str); public double Double => double.Parse(Str); public string Str => ReadLine.Trim(); public string ReadLine => sr.ReadLine(); public pair Pair() { T a; U b; Multi(out a, out b); return new pair(a, b); } public P P => Pair(); public int[] IntArr => StrArr.Select(int.Parse).ToArray(); public long[] LongArr => StrArr.Select(long.Parse).ToArray(); public double[] DoubleArr => StrArr.Select(double.Parse).ToArray(); public string[] StrArr => Str.Split(new[]{' '}, StringSplitOptions.RemoveEmptyEntries); bool eq() => typeof(T).Equals(typeof(U)); T ct(U a) => (T)Convert.ChangeType(a, typeof(T)); T cv(string s) => eq() ? ct(int.Parse(s)) : eq() ? ct(long.Parse(s)) : eq() ? ct(double.Parse(s)) : eq() ? ct(s[0]) : ct(s); public void Multi(out T a) => a = cv(Str); public void Multi(out T a, out U b) { var ar = StrArr; a = cv(ar[0]); b = cv(ar[1]); } public void Multi(out T a, out U b, out V c) { var ar = StrArr; a = cv(ar[0]); b = cv(ar[1]); c = cv(ar[2]); } public void Multi(out T a, out U b, out V c, out W d) { var ar = StrArr; a = cv(ar[0]); b = cv(ar[1]); c = cv(ar[2]); d = cv(ar[3]); } public void Multi(out T a, out U b, out V c, out W d, out X e) { var ar = StrArr; a = cv(ar[0]); b = cv(ar[1]); c = cv(ar[2]); d = cv(ar[3]); e = cv(ar[4]); } } class LazySegtree { int n; T[] data; U[] lazy; bool[] is_lazy; Func calc; Func apply; Func merge; T identity; public LazySegtree(int m, Func calc, Func apply, Func merge, T identity) { this.calc = calc; this.apply = apply; this.merge = merge; this.identity = identity; n = 1; while (n < m) n <<= 1; data = new T[n * 2 - 1]; lazy = new U[n * 2 - 1]; is_lazy = new bool[n * 2 - 1]; for (int i = 0; i < data.Length; i++) data[i] = identity; } public LazySegtree(int m, Func calc, Func apply, Func merge, T identity, T ini) : this(m, calc, apply, merge, identity) { for (int i = 0; i < m; i++) data[i + n - 1] = ini; for (int i = n - 2; i >= 0; i--) data[i] = calc(data[i * 2 + 1], data[i * 2 + 2]); } public LazySegtree(int m, Func calc, Func apply, Func merge, T identity, IList ini) : this(m, calc, apply, merge, identity) { for (int i = 0; i < m; i++) data[i + n - 1] = ini[i]; for (int i = n - 2; i >= 0; i--) data[i] = calc(data[i * 2 + 1], data[i * 2 + 2]); } void assign_lazy(int k, U x) { if (k >= lazy.Length) return; lazy[k] = is_lazy[k] ? merge(lazy[k], x) : x; is_lazy[k] = true; } void eval(int k, int l, int r){ if (!is_lazy[k]) return; assign_lazy(k * 2 + 1, lazy[k]); assign_lazy(k * 2 + 2, lazy[k]); data[k] = apply(data[k], lazy[k], l, r); is_lazy[k] = false; } T update(int s, int t, U x, int k, int l, int r) { eval(k, l, r); if (r <= s || t <= l) return data[k]; if (s <= l && r <= t) { assign_lazy(k, x); return apply(data[k], lazy[k], l, r); } return data[k] = calc(update(s, t, x, k * 2 + 1, l, (l + r) / 2), update(s, t, x, k * 2 + 2, (l + r) / 2, r)); } T run(int s, int t, int k, int l, int r) { eval(k, l, r); if (r <= s || t <= l) return identity; if (s <= l && r <= t) return data[k]; return calc(run(s, t, k * 2 + 1, l, (l + r) / 2), run(s, t, k * 2 + 2, (l + r) / 2, r)); } // [s, t) public void update(int s, int t, U x) => update(s, t, x, 0, 0, n); // [s, t) public T run(int s, int t) => run(s, t, 0, 0, n); }