import std.stdio, std.array, std.string, std.conv, std.algorithm; import std.typecons, std.range, std.random, std.math, std.container; import std.numeric, std.bigint, core.bitop; immutable long MOD = 998244353; void main() { auto s = readln.split.map!(to!int); auto N = s[0]; auto Q = s[1]; auto A = iota(Q).map!(_ => readln.split.map!(to!int).array).array; foreach (a; A) a[0]--, a[1]--; A.sort!"a[2] < b[2]"; auto st = new LazySegmentTree!(long, long, min, (a,b)=>b, (a,b)=>b, (a,b)=>a, 1L<<59, 1L<<59)(N); foreach (a; A) { auto l = a[0]; auto r = a[1]; auto x = a[2].to!long; st.update(l, r, x); } foreach (a; A) { auto l = a[0]; auto r = a[1]; auto x = a[2].to!long; if (st.query(l, r) != x) { writeln(-1); return; } } auto B = N.iota.map!(i => st.query(i, i)).map!(a => a > 10L^^9 ? 10L^^9 : a).array; B.map!(to!string).join(" ").writeln; } /* 参考元: https://github.com/yosupo06/dunkelheit/blob/master/source/dkh/datastructure/segtree.d */ /* T: 取得クエリで取得する値の型 L: 更新クエリで投げる値の型 opTT: 2つの区間の結果をマージする関数 (T, T) -> T opTL: クエリを適用する(作用させる)関数 (T, L) -> T opLL: 2つのクエリをまとめる関数 (L, L) -> L opPrd: (L, int) -> 区間の長さに応じて結果を変化させる関数. 区間和とかに使う (L, int) -> T eT: Tの単位元 eL: Lの単位元 */ /* 1. 区間代入 / 区間min auto st = new LazySegmentTree!(long, long, min, (a,b)=>b, (a,b)=>b, (a,b)=>a, 1L<<59, 1L<<59)(N); 2. 区間加算 / 区間sum auto st = new LazySegmentTree!(long, long, (a,b)=>a+b, (a,b)=>a+b, (a,b)=>a+b, (a,b)=>a*b, 0L, 0L)(N+1); 3. 区間加算 / 区間min auto st = new LazySegmentTree!(long, long, min, (a,b)=>a+b, (a,b)=>a+b, (a,b)=>a, 1L<<59, 0L)(N+1); st.table[] = 0L; 4. 区間代入 / 区間sum auto st = new LazySegmentTree!(long, long, (a,b)=>a+b, (a,b)=>b, (a,b)=>b, (a,b)=>a*b, 0L, 1L<<59)(N+1); いずれもAOJでverify済. 1. http://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=DSL_2_F 2. http://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=DSL_2_G 3. http://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=DSL_2_H 4. http://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=DSL_2_I */ class LazySegmentTree(T, L, alias opTT, alias opTL, alias opLL, alias opPrd, T eT, L eL) { T[] table; L[] lazy_; int n; int size; this(int n) { this.n = n; size = 1; while (size <= n) size <<= 1; size <<= 1; table = new T[](size); lazy_ = new L[](size); table[] = eT; lazy_[] = eL; } void push(int i, int a, int b) { if (lazy_[i] == eL) return; table[i] = opTL(table[i], opPrd(lazy_[i], b - a + 1)); if (i * 2 + 1 < size) { lazy_[i*2] = opLL(lazy_[i*2], lazy_[i]); lazy_[i*2+1] = opLL(lazy_[i*2+1], lazy_[i]); } lazy_[i] = eL; } T query(int l, int r) { if (l > r) return eT; return query(l, r, 1, 0, n-1); } T query(int l, int r, int i, int a, int b) { if (b < l || r < a) return eT; push(i, a, b); if (l <= a && b <= r) { return table[i]; } else { return opTT(query(l, r, i*2, a, (a+b)/2), query(l, r, i*2+1, (a+b)/2+1, b)); } } void update(int l, int r, L val) { if (l > r) return; update(l, r, 1, 0, n-1, val); } void update(int l, int r, int i, int a, int b, L val) { if (b < l || r < a) { push(i, a, b); } else if (l <= a && b <= r) { lazy_[i] = opLL(lazy_[i], val); push(i, a, b); } else { push(i, a, b); update(l, r, i*2, a, (a+b)/2, val); update(l, r, i*2+1, (a+b)/2+1, b, val); table[i] = opTT(table[i*2], table[i*2+1]); } } }