コンパイルメッセージ

Main.d(541): Deprecation: function `Main.IO!(makeGlobal, makeGlobal).IO.put!("{}", ModInt!1000000007).put.putMain!(c, ModInt!1000000007).putMain` function requires a dual-context, which is deprecated
Main.d-mixin-511(511):        instantiated from here: `putMain!(c, ModInt!1000000007)`
Main.d(92):        instantiated from here: `put!("{}", ModInt!1000000007)`

ソースコード

// URL: https://yukicoder.me/problems/no/1502

import std.algorithm, std.array, std.bitmanip, std.container, std.conv, std.format,
       std.functional, std.math, std.range, std.traits, std.typecons, std.stdio, std.string;

version(unittest) {} else
void main()
{
  int N, M, K; io.getV(N, M, K);

  auto g = GraphW!int(N);
  foreach (_; 0..M) {
    int Xi, Yi, Zi; io.getV(Xi, Yi, Zi); --Xi; --Yi;
    g.addEdgeB(Xi, Yi, Zi);
  }

  auto check(int a, int av)
  {
    auto mi = av, ma = av, b = new int[](N), visited = new bool[](N);
    auto q = DList!int(a);
    b[a] = av; visited[a] = true;
    while (!q.empty) {
      auto u = q.front; q.removeFront();
      foreach (e; g[u]) {
        auto v = e.dst, bv = e.wt - b[u];
        if (visited[v]) {
          if (b[v] != bv) return -1;
        } else {
          b[v] = bv;
          visited[v] = true;
          q.insertBack(v);
          mi.minU(bv);
          ma.maxU(bv);
        }
      }
    }
    return mi < 1 ? -1 : ma;
  }

  auto c0 = mint(1), c1 = mint(1);
  auto b = new int[](N), d = new int[](N), visited = new bool[](N);
  foreach (i; 0..N) {
    if (visited[i]) continue;
    auto q = DList!int(i), mi0 = 1, ma0 = K, mi1 = 1, ma1 = K-1;
    visited[i] = true;
  loop: while (!q.empty) {
      auto u = q.front; q.removeFront();
      foreach (e; g[u]) {
        auto v = e.dst, bv = e.wt - b[u];
        if (visited[v]) {
          if (d[v]%2 == (d[u]+1)%2) {
            if (b[v] != bv || (b[v]+bv)%2 == 1) {
              c0 = 0; c1 = 0;
              break loop;
            }
          } else {
            if ((b[v]+bv)%2 == 1) {
              c0 = 0;
              c1 = 0;
              break loop;
            } else {
              auto k = check(v, (b[v]+bv)/2);
              if (k == -1 || k > K) ma0 = 0;
              else ma0 = mi0;
              if (k == -1 || k > K-1) ma1 = 0;
              else ma1 = mi1;
              break loop;
            }
          }
        } else {
          b[v] = bv;
          d[v] = d[u] + 1;
          visited[v] = true;
          if (d[v]%2 == 1) {
            mi0.maxU(bv - K);
            ma0.minU(bv - 1);
            mi1.maxU(bv - (K-1));
            ma1.minU(bv - 1);
          } else {
            mi0.maxU(1 - bv);
            ma0.minU(K - bv);
            mi1.maxU(1 - bv);
            ma1.minU((K-1) - bv);
          }
          q.insertBack(v);
        }
      }
    }
    c0 *= max(0, ma0-mi0+1);
    c1 *= max(0, ma1-mi1+1);
  }
  io.put(c0 - c1);
}

const mod = 10^^9+7;
alias mint = ModInt!mod;

pragma(inline) pure nothrow @nogc @safe
{
  T minU(T, U)(ref T a, U b)
  { return a = min(a, b); }
  T maxU(T, U)(ref T a, U b)
  { return a = max(a, b); }
}
pure nothrow @safe
{
  T powr(alias pred = "a*b", T, U)(const T a, U n, T one)
    if (isIntegral!U)
  {
    auto b = T(a);
    alias predFun = binaryFun!pred;
    if (n == 0) return one;
    auto r = one;
    for (; n > 0; n >>= 1) {
      if (n&1) r = predFun(r, b);
      b = predFun(b, b);
    }
    return r;
  }
  T powr(alias pred = "a*b", T, U)(const T a, U n)
    if (isIntegral!U)
  {
    return powr!(pred, T, U)(a, n, T(1));
  }
}

pragma(inline) pure nothrow @nogc @safe
{
  T cdiv(T)(const T a, const T b)
  {
    return (a+b-1)/b;
  }
  T pmod(T)(const T a, const T b)
  {
    return a >= 0 ? a%b : a%b+b;
  }
}

pure nothrow @nogc @safe
{
  ExtGcdResult!T extGcd(T)(const T a, const T b)
  {
    if (a == 0) {
      return ExtGcdResult!T(T(b), T(0), T(1));
    } else {
      auto r = extGcd(b%a, a);
      return ExtGcdResult!T(r.gcd, r.y-(b/a)*r.x, r.x);
    }
  }

  private struct ExtGcdResult(T)
  {
    T gcd, x, y;
  }
}

struct ModInt(int m)
{
  pragma(inline) pure nothrow @nogc @safe
  {
    this(T)(T v)
      if (isIntegral!T)
    {
      i = nm(v);
    }
    this(ref return scope const Mint v)
    {
      i = v.i;
    }
    bool opEquals(T)(T v) const
      if (isIntegral!T)
    {
      return i == v;
    }
    bool opEquals(const Mint v) const
    {
      return i == v.i;
    }

    Mint opUnary(string op: "-")() const
    {
      return Mint(-i);
    }

    static if (m < int.max/2) {
      Mint opBinary(string op: "+")(int r) const
      {
        Mint m;
        m.i = nm(i+r);
        return m;
      }
      Mint opBinary(string op: "+")(const Mint r) const
      {
        Mint m;
        m.i = nmp(i+r.i);
        return m;
      }
      ref Mint opOpAssign(string op: "+")(int r)
      {
        i = nm(i+r);
        return this;
      }
      ref Mint opOpAssign(string op: "+")(const Mint r)
      {
        i = nmp(i+r.i);
        return this;
      }
    } else {
      Mint opBinary(string op: "+")(int r) const
      {
        Mint m;
        m.i = nm(l+r);
        return m;
      }
      Mint opBinary(string op: "+")(const Mint r) const
      {
        Mint m;
        m.i = nmp(l+r.i);
        return m;
      }
      ref Mint opOpAssign(string op: "+")(int r)
      {
        i = nm(l+r);
        return this;
      }
      ref Mint opOpAssign(string op: "+")(const Mint r)
      {
        i = nmp(l+r.i);
        return this;
      }
    }
    Mint opBinary(string op: "-")(int r) const
    {
      return Mint(i-r);
    }
    Mint opBinary(string op: "-")(const Mint r) const
    {
      return Mint(i-r.i);
    }
    ref Mint opOpAssign(string op: "-")(int r)
    {
      i = nm(i-r);
      return this;
    }
    ref Mint opOpAssign(string op: "-")(const Mint r)
    {
      i = nm(i-r.i);
      return this;
    }

    Mint opBinary(string op, T)(T r) const
      if ((op == "+" || op == "-") && isIntegral!T && !is(T == int))
    {
      return Mint(mixin("l"~op~"r"));
    }
    ref Mint opOpAssign(string op, T)(T r)
      if ((op == "+" || op == "-") && isIntegral!T && !is(T == int))
    {
      i = nm(mixin("l"~op~"r"));
      return this;
    }

    Mint opBinary(string op: "*", T)(T r) const
      if (isIntegral!T)
    {
      Mint m;
      m.i = nm(l*r);
      return m;
    }
    Mint opBinary(string op: "*")(const Mint r) const
    {
      Mint m;
      m.i = nmp(l*r.i);
      return m;
    }
    ref Mint opOpAssign(string op: "*", T)(T r)
      if (isIntegral!T)
    {
      i = nm(l*r);
      return this;
    }
    ref Mint opOpAssign(string op: "*")(const Mint r)
    {
      i = nmp(l*r.i);
      return this;
    }

    ref Mint opUnary(string op: "++")()
    {
      i = nmp(i+1);
      return this;
    }
    ref Mint opUnary(string op: "--")()
    {
      i = nm(i-1);
      return this;
    }

    Mint opBinary(string op: "^^", T)(T n)
      if (isIntegral!T)
    {
      return powr(this, n, Mint(1));
    }

    Mint opBinary(string op: "/")(const Mint r) const
    {
      return Mint(l*r.inv.i);
    }
    ref Mint opOpAssign(string op: "/")(const Mint r)
    {
      i = nm(l*r.inv.i);
      return this;
    }

    Mint opBinary(string op: "/", T)(T r) const
      if (isIntegral!T)
    {
      return opBinary!op(Mint(r));
    }
    ref Mint opOpAssign(string op: "/", T)(T r)
      if (isIntegral!T)
    {
      return opOpAssign!op(Mint(r));
    }

    Mint inv() const
    {
      return Mint(extGcd(i, m).x);
    }
  }

  pure nothrow @nogc @safe
  {
    ref Mint opAssign(T)(T v)
      if (isIntegral!T)
    {
      i = nm(v);
      return this;
    }
    ref Mint opAssign(const Mint v)
    {
      i = v.i;
      return this;
    }
  }

  pure nothrow @safe
  {
    string toString() const
    {
      return i.to!string;
    }
  }

  private
  {
    alias Mint = ModInt!m;
    version(BigEndian) union { long l; struct { int i2; int i; } }
    else union { long l; int i; }

    pragma(inline) pure nothrow @nogc @safe
    {
      int nm(T)(T v) const
        if (isIntegral!T)
      {
        return cast(int)pmod(v, m);
      }
      int nmp(T)(T v) const
        if (isIntegral!T)
      {
        return cast(int)(v%m);
      }
    }
  }
}
struct Graph
{
  alias Node = int;
  Node n;
  Node[][] g;
  alias g this;

  pure nothrow @safe
  {
    this(Node n)
    {
      this.n = n;
      g = new Node[][](n);
    }
    void addEdge(Node u, Node v)
      in { assert(0 <= u && u < n && 0 <= v && v < n); }
    do
    {
      g[u] ~= v;
    }
    void addEdgeB(Node u, Node v)
      in { assert(0 <= u && u < n && 0 <= v && v < n); }
    do
    {
      g[u] ~= v;
      g[v] ~= u;
    }
  }
}

struct GraphW(W = int, W i = 10^^9)
{
  alias Node = int, Wt = W, inf = i;
  struct Edge
  {
    Node src, dst;
    Wt wt;
    alias cap = wt;
  }
  Node n;
  Edge[][] g;
  alias g this;

  pure nothrow @safe
  {
    this(Node n)
    {
      this.n = n;
      g = new Edge[][](n);
    }
    void addEdge(Node u, Node v, Wt w)
      in { assert(0 <= u && u < n && 0 <= v && v < n); }
    do
    {
      g[u] ~= Edge(u, v, w);
    }
    void addEdgeB(Node u, Node v, Wt w)
      in { assert(0 <= u && u < n && 0 <= v && v < n); }
    do
    {
      g[u] ~= Edge(u, v, w);
      g[v] ~= Edge(v, u, w);
    }
  }
}

struct GraphM(W = int, W i = 10^^9)
{
  alias Node = int, Wt = W, inf = i;
  Node n;
  Wt[][] g;
  alias g this;

  pure nothrow @safe
  {
    this(int n)
    {
      this.n = n;
      g = new Wt[][](n, n);
    }
    static GraphM!(W, i) init(Node n)
    {
      auto g = GraphM!(W, i)(n);
      foreach (i; 0..n) { g[i][] = inf; g[i][i] = 0; }
      return g;
    }
  }
}

auto io = IO!()();
import std.stdio;
struct IO(alias IN = stdin, alias OUT = stdout)
{
  import std.meta : allSatisfy;
  import core.stdc.stdlib : exit;

  void getV(T...)(ref T v)
  {
    foreach (ref w; v) get(w);
  }
  void getA(T)(size_t n, ref T v)
    if (hasAssignableElements!T)
  {
    v = new T(n);
    foreach (ref w; v) get(w);
  }
  void getC(T...)(size_t n, ref T v)
    if (allSatisfy!(hasAssignableElements, T))
  {
    foreach (ref w; v) w = new typeof(w)(n);
    foreach (i; 0..n) foreach (ref w; v) get(w[i]);
  }
  void getM(T)(size_t r, size_t c, ref T v)
    if (hasAssignableElements!T && hasAssignableElements!(ElementType!T))
  {
    v = new T(r);
    foreach (ref w; v) getA(c, w);
  }
  template getS(E...)
  {
    void getS(T)(size_t n, ref T v)
    {
      v = new T(n);
      foreach (ref w; v) foreach (e; E) mixin("get(w."~e~");");
    }
  }

  const struct PutConf
  {
    bool newline = true, flush, exit;
    string floatFormat = "%.10f", delimiter = " ";
  }

  void put(alias conf = "{}", T...)(T v)
  {
    mixin("const PutConf c = "~conf~"; putMain!c(v);");
  }
  void putB(alias conf = "{}", S, T)(bool c, S t, T f)
  {
    if (c) put!conf(t);
    else put!conf(f);
  }
  void putRaw(T...)(T v)
  {
    OUT.write(v);
    OUT.writeln;
  }

  private
  {
    dchar[] buf;
    auto sp = (new dchar[](0)).splitter;

    void nextLine()
    {
      IN.readln(buf);
      sp = buf.splitter;
    }
    void get(T)(ref T v)
    {
      if (sp.empty) nextLine();
      v = sp.front.to!T;
      sp.popFront();
    }

    void putMain(PutConf c, T...)(T v)
    {
      foreach (i, w; v) {
        putOne!c(w);
        if (i+1 < v.length) OUT.write(c.delimiter);
      }
      static if (c.newline) OUT.writeln;
      static if (c.flush) OUT.flush();
      static if (c.exit) exit(0);
    }
    void putOne(PutConf c, T)(T v)
    {
      static if (isInputRange!T && !isSomeString!T) putRange!c(v);
      else static if (isFloatingPoint!T) OUT.write(format(c.floatFormat, v));
      else static if (hasMember!(T, "fprint")) v.fprint(OUT);
      else OUT.write(v);
    }
    void putRange(PutConf c, T)(T v)
    {
      auto w = v;
      while (!w.empty) {
        putOne!c(w.front); w.popFront();
        if (!w.empty) OUT.write(c.delimiter);
      }
    }
  }
}