結果
問題 | No.1233 割り切れない気持ち |
ユーザー | CuriousFairy315 |
提出日時 | 2019-07-30 23:23:21 |
言語 | Java21 (openjdk 21) |
結果 |
TLE
|
実行時間 | - |
コード長 | 48,793 bytes |
コンパイル時間 | 4,153 ms |
コンパイル使用メモリ | 100,328 KB |
実行使用メモリ | 51,224 KB |
最終ジャッジ日時 | 2024-06-22 16:30:01 |
合計ジャッジ時間 | 10,575 ms |
ジャッジサーバーID (参考情報) |
judge2 / judge5 |
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テストケース
テストケース表示入力 | 結果 | 実行時間 実行使用メモリ |
---|---|---|
testcase_00 | AC | 52 ms
50,112 KB |
testcase_01 | AC | 53 ms
50,144 KB |
testcase_02 | AC | 54 ms
50,696 KB |
testcase_03 | AC | 76 ms
51,216 KB |
testcase_04 | AC | 81 ms
51,224 KB |
testcase_05 | AC | 54 ms
50,692 KB |
testcase_06 | AC | 51 ms
50,284 KB |
testcase_07 | TLE | - |
testcase_08 | -- | - |
testcase_09 | -- | - |
testcase_10 | -- | - |
testcase_11 | -- | - |
testcase_12 | -- | - |
testcase_13 | -- | - |
testcase_14 | -- | - |
testcase_15 | -- | - |
testcase_16 | -- | - |
testcase_17 | -- | - |
testcase_18 | -- | - |
testcase_19 | -- | - |
testcase_20 | -- | - |
testcase_21 | -- | - |
testcase_22 | -- | - |
testcase_23 | -- | - |
testcase_24 | -- | - |
testcase_25 | -- | - |
testcase_26 | -- | - |
testcase_27 | -- | - |
testcase_28 | -- | - |
testcase_29 | -- | - |
testcase_30 | -- | - |
testcase_31 | -- | - |
testcase_32 | -- | - |
testcase_33 | -- | - |
testcase_34 | -- | - |
testcase_35 | -- | - |
testcase_36 | -- | - |
testcase_37 | -- | - |
testcase_38 | -- | - |
testcase_39 | -- | - |
testcase_40 | -- | - |
ソースコード
package yukicoder_3265; import java.awt.Point; import java.io.IOException; import java.io.InputStream; import java.io.PrintStream; import java.io.PrintWriter; import java.io.Serializable; import java.util.Arrays; import java.util.Collection; import java.util.Comparator; import java.util.Iterator; import java.util.Locale; import java.util.NoSuchElementException; import java.util.function.BinaryOperator; import java.util.function.UnaryOperator; public class Main { /** デバッグ用コードのお供に */ private static boolean DEBUG = false; private final FastIO io; private void solve(FastIO io) { /* * author: 31536000 * 考察メモ * まずは愚直コード */ int N = io.nextInt(); int[] A = io.nextInt(N); if (!IntRange.closed(1, 200000).contains(N)) System.exit(1); for (int i : A) if (!IntRange.closed(1, 200000).contains(i)) System.exit(1); long ans = 0; for (int i = 0;i < N;++ i) for (int j = 0;j < N;++ j) ans += A[i] % A[j]; io.println(ans); } public static void main(String[] args) { new Main(); } public Main() { io = new FastIO(); //assert (DEBUG = true) & true; // 絶対に許されないコード、こういう使い方は止めようね! if (DEBUG) io.println("debug mode"); solve(io); io.flush(); } // 以下、ライブラリ public class FastIO { private final InputStream in; private final byte[] buffer = new byte[1024]; private int read = 0; private int length = 0; public final PrintWriter out; public final PrintWriter err; private boolean autoFlush = false; public FastIO() { this(System.in, System.out, System.err); } public FastIO(InputStream in, PrintStream out, PrintStream err) { this.in = in; this.out = new PrintWriter(out, false); this.err = new PrintWriter(err, false); } public void setAutoFlush(boolean flush) { autoFlush = flush; } private boolean hasNextByte() { if (read < length) return true; read = 0; try { length = in.read(buffer); } catch (IOException e) { e.printStackTrace(); } return length > 0; } private int readByte() { return hasNextByte() ? buffer[read++] : -1; } private boolean isPrintableChar(int c) { return 33 <= c && c <= 126; } private boolean isNumber(int c) { return '0' <= c && c <= '9'; } public boolean hasNext() { while (hasNextByte() && !isPrintableChar(buffer[read])) read++; return hasNextByte(); } public char nextChar() { if (!hasNextByte()) throw new NoSuchElementException(); return (char)readByte(); } public char[][] nextChar(int height) { char[][] ret = new char[height][]; for (int i = 0;i < ret.length;++ i) ret[i] = next().toCharArray(); return ret; } public String next() { if (!hasNext()) throw new NoSuchElementException(); StringBuilder sb = new StringBuilder(); int b; while (isPrintableChar(b = readByte())) sb.appendCodePoint(b); return sb.toString(); } public String nextLine() { StringBuilder sb = new StringBuilder(); int b; while(!isPrintableChar(b = readByte())); do sb.appendCodePoint(b); while(isPrintableChar(b = readByte()) || b == ' '); return sb.toString(); } public long nextLong() { if (!hasNext()) throw new NoSuchElementException(); long n = 0; boolean minus = false; int b = readByte(); if (b == '-') { minus = true; b = readByte(); } if (!isNumber(b)) throw new NumberFormatException(); while (true) { if (isNumber(b)) { n *= 10; n += b - '0'; } else if (b == -1 || !isPrintableChar(b)) return minus ? -n : n; else throw new NumberFormatException(); b = readByte(); } } public int nextInt() { long nl = nextLong(); if (nl < Integer.MIN_VALUE || nl > Integer.MAX_VALUE) throw new NumberFormatException(); return (int) nl; } public double nextDouble() { return Double.parseDouble(next()); } public int[] nextInt(int width) { int[] ret = new int[width]; for (int i = 0;i < width;++ i) ret[i] = nextInt(); return ret; } public int[] nextInts() { return nextInts(" "); } public int[] nextInts(String parse) { String[] get = nextLine().split(parse); int[] ret = new int[get.length]; for (int i = 0;i < ret.length;++ i) ret[i] = Integer.valueOf(ret[i]); return ret; } public long[] nextLong(int width) { long[] ret = new long[width]; for (int i = 0;i < width;++ i) ret[i] = nextLong(); return ret; } public long[] nextLongs() { return nextLongs(" "); } public long[] nextLongs(String parse) { String[] get = nextLine().split(parse); long[] ret = new long[get.length]; for (int i = 0;i < ret.length;++ i) ret[i] = Long.valueOf(ret[i]); return ret; } public int[][] nextInt(int width, int height) { int[][] ret = new int[height][width]; for (int i = 0, j;i < height;++ i) for (j = 0;j < width;++ j) ret[i][j] = nextInt(); return ret; } public long[][] nextLong(int width, int height) { long[][] ret = new long[height][width]; for (int i = 0, j;i < height;++ i) for (j = 0;j < width;++ j) ret[j][i] = nextLong(); return ret; } public boolean[] nextBoolean(char T) { char[] s = next().toCharArray(); boolean[] ret = new boolean[s.length]; for (int i = 0;i < ret.length;++ i) ret[i] = s[i] == T; return ret; } public boolean[][] nextBoolean(char T, int height) { boolean[][] ret = new boolean[height][]; for (int i = 0;i < ret.length;++ i) { char[] s = next().toCharArray(); ret[i] = new boolean[s.length]; for (int j = 0;j < ret[i].length;++ j) ret[i][j] = s[j] == T; } return ret; } public Point nextPoint() { return new Point(nextInt(), nextInt()); } public Point[] nextPoint(int width) { Point[] ret = new Point[width]; for (int i = 0;i < width;++ i) ret[i] = nextPoint(); return ret; } @Override protected void finalize() throws Throwable { try { super.finalize(); } finally { in.close(); out.close(); err.close(); } } public boolean print(boolean b) { out.print(b); if (autoFlush) flush(); return b; } public Object print(boolean b, Object t, Object f) { return b ? print(t) : print(f); } public char print(char c) { out.print(c); if (autoFlush) flush(); return c; } public char[] print(char[] s) { out.print(s); return s; } public double print(double d) { out.print(d); if (autoFlush) flush(); return d; } public double print(double d, int length) { if (d < 0) { out.print('-'); d = -d; } d += Math.pow(10, -length) / 2; out.print((long)d); out.print('.'); d -= (long)d; for (int i = 0;i < length;++ i) { d *= 10; out.print((int)d); d -= (int)d; } if (autoFlush) flush(); return d; } public float print(float f) { out.print(f); if (autoFlush) flush(); return f; } public int print(int i) { out.print(i); if (autoFlush) flush(); return i; } public long print(long l) { out.print(l); if (autoFlush) flush(); return l; } public Object print(Object obj) { if (obj.getClass().isArray()) { if (obj instanceof boolean[][]) print(obj, "\n", " "); else if (obj instanceof byte[][]) print(obj, "\n", " "); else if (obj instanceof short[][]) print(obj, "\n", " "); else if (obj instanceof int[][]) print(obj, "\n", " "); else if (obj instanceof long[][]) print(obj, "\n", " "); else if (obj instanceof float[][]) print(obj, "\n", " "); else if (obj instanceof double[][]) print(obj, "\n", " "); else if (obj instanceof char[][]) print(obj, "\n", " "); else if (obj instanceof Object[][]) print(obj, "\n", " "); else print(obj, " "); } else { out.print(obj); if (autoFlush) flush(); } return obj; } public String print(String s) { out.print(s); if (autoFlush) flush(); return s; } public Object print(Object array, String... parse) { print(array, 0, parse); if (autoFlush) flush(); return array; } private Object print(Object array, int check, String... parse) { if (check >= parse.length) { if (array.getClass().isArray()) throw new IllegalArgumentException("not equal dimension"); print(array); return array; } String str = parse[check]; if (array instanceof Object[]) { Object[] obj = (Object[]) array; if (obj.length == 0) return array; print(obj[0], check + 1, parse); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i], check + 1, parse); } return array; } if (array instanceof Collection) { Iterator<?> iter = ((Collection<?>)array).iterator(); if (!iter.hasNext()) return array; print(iter.next(), check + 1, parse); while(iter.hasNext()) { print(str); print(iter.next(), check + 1, parse); } return array; } if (!array.getClass().isArray()) throw new IllegalArgumentException("not equal dimension"); if (check != parse.length - 1) throw new IllegalArgumentException("not equal dimension"); if (array instanceof boolean[]) { boolean[] obj = (boolean[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof byte[]) { byte[] obj = (byte[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof short[]) { short[] obj = (short[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof int[]) { int[] obj = (int[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof long[]) { long[] obj = (long[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof float[]) { float[] obj = (float[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof double[]) { double[] obj = (double[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } else if (array instanceof char[]) { char[] obj = (char[]) array; if (obj.length == 0) return array; print(obj[0]); for (int i = 1;i < obj.length;++ i) { print(str); print(obj[i]); } } throw new AssertionError(); } public Object[] print(String parse, Object... args) { print(args[0]); for (int i = 1;i < args.length;++ i) { print(parse); print(args[i]); } return args; } public Object[] printf(String format, Object... args) { out.printf(format, args); if (autoFlush) flush(); return args; } public Object printf(Locale l, String format, Object... args) { out.printf(l, format, args); if (autoFlush) flush(); return args; } public void println() { out.println(); if (autoFlush) flush(); } public boolean println(boolean b) { out.println(b); if (autoFlush) flush(); return b; } public Object println(boolean b, Object t, Object f) { return b ? println(t) : println(f); } public char println(char c) { out.println(c); if (autoFlush) flush(); return c; } public char[] println(char[] s) { out.println(s); if (autoFlush) flush(); return s; } public double println(double d) { out.println(d); if (autoFlush) flush(); return d; } public double println(double d, int length) { print(d, length); println(); return d; } public float println(float f) { out.println(f); if (autoFlush) flush(); return f; } public int println(int i) { out.println(i); if (autoFlush) flush(); return i; } public long println(long l) { out.println(l); if (autoFlush) flush(); return l; } public Object println(Object obj) { print(obj); println(); return obj; } public String println(String s) { out.println(s); if (autoFlush) flush(); return s; } public Object println(Object array, String... parse) { print(array, parse); println(); return array; } public void flush() { out.flush(); err.flush(); } } public enum BoundType { CLOSED, OPEN; } public static class Range<C> implements Serializable{ private static final long serialVersionUID = -4702828934863023392L; protected C lower; protected C upper; protected BoundType lowerType; protected BoundType upperType; private Comparator<? super C> comparator; protected Range(C lower, BoundType lowerType, C upper, BoundType upperType) { this(lower, lowerType, upper, upperType, null); } protected Range(C lower, BoundType lowerType, C upper, BoundType upperType, Comparator<? super C> comparator) { this.lower = lower; this.upper = upper; this.lowerType = lowerType; this.upperType = upperType; this.comparator = comparator; } public static <C extends Comparable<? super C>> Range<C> range(C lower, BoundType lowerType, C upper, BoundType upperType) { if (lower != null && upper != null) { int comp = lower.compareTo(upper); if (comp > 0) return new Range<C>(null, BoundType.CLOSED, null, BoundType.CLOSED); else if (comp == 0 && (lowerType == BoundType.OPEN || upperType == BoundType.OPEN))return new Range<C>(null, BoundType.CLOSED, null, BoundType.CLOSED); } return new Range<C>(lower, lowerType, upper, upperType); } public static <C> Range<C> range(C lower, BoundType lowerType, C upper, BoundType upperType, Comparator<? super C> comparator) { if (lower != null && upper != null) { int comp = comparator.compare(lower, upper); if (comp > 0) return new Range<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, comparator); else if (comp == 0 && (lowerType == BoundType.OPEN || upperType == BoundType.OPEN)) return new Range<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, comparator); } return new Range<C>(lower, lowerType, upper, upperType, comparator); } public static <C extends Comparable<? super C>> Range<C> all() { return range((C)null, BoundType.OPEN, null, BoundType.OPEN); } public static <C> Range<C> all(Comparator<? super C> comparator) { return range((C)null, BoundType.OPEN, null, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> atMost(C upper) { return range(null, BoundType.OPEN, upper, BoundType.CLOSED); } public static <C> Range<C> atMost(C upper, Comparator<? super C> comparator) { return range(null, BoundType.OPEN, upper, BoundType.CLOSED, comparator); } public static <C extends Comparable<? super C>> Range<C> lessThan(C upper) { return range(null, BoundType.OPEN, upper, BoundType.OPEN); } public static <C> Range<C> lessThan(C upper, Comparator<? super C> comparator) { return range(null, BoundType.OPEN, upper, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> downTo(C upper, BoundType boundType) { return range(null, BoundType.OPEN, upper, boundType); } public static <C> Range<C> downTo(C upper, BoundType boundType, Comparator<? super C> comparator) { return range(null, BoundType.OPEN, upper, boundType, comparator); } public static <C extends Comparable<? super C>> Range<C> atLeast(C lower) { return range(lower, BoundType.CLOSED, null, BoundType.OPEN); } public static <C> Range<C> atLeast(C lower, Comparator<? super C> comparator) { return range(lower, BoundType.CLOSED, null, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> greaterThan(C lower) { return range(lower, BoundType.OPEN, null, BoundType.OPEN); } public static <C> Range<C> greaterThan(C lower, Comparator<? super C> comparator) { return range(lower, BoundType.OPEN, null, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> upTo(C lower, BoundType boundType) { return range(lower, boundType, null, BoundType.OPEN); } public static <C> Range<C> upTo(C lower, BoundType boundType, Comparator<? super C> comparator) { return range(lower, boundType, null, BoundType.OPEN, comparator ); } public static <C extends Comparable<? super C>> Range<C> open(C lower, C upper) { return range(lower, BoundType.OPEN, upper, BoundType.OPEN); } public static <C> Range<C> open(C lower, C upper, Comparator<? super C> comparator) { return range(lower, BoundType.OPEN, upper, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> openClosed(C lower, C upper) { return range(lower, BoundType.OPEN, upper, BoundType.CLOSED); } public static <C> Range<C> openClosed(C lower, C upper, Comparator<? super C> comparator) { return range(lower, BoundType.OPEN, upper, BoundType.CLOSED, comparator); } public static <C extends Comparable<? super C>> Range<C> closedOpen(C lower, C upper) { return range(lower, BoundType.CLOSED, upper, BoundType.OPEN); } public static <C> Range<C> closedOpen(C lower, C upper, Comparator<? super C> comparator) { return range(lower, BoundType.CLOSED, upper, BoundType.OPEN, comparator); } public static <C extends Comparable<? super C>> Range<C> closed(C lower, C upper) { return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED); } public static <C> Range<C> closed(C lower, C upper, Comparator<? super C> comparator) { return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED, comparator); } public static <C extends Comparable<? super C>> Range<C> singleton(C value) { return range(value, BoundType.CLOSED, value, BoundType.CLOSED); } public static <C> Range<C> singleton(C value, Comparator<? super C> comparator) { return range(value, BoundType.CLOSED, value, BoundType.CLOSED, comparator); } public static <C extends Comparable<? super C>> Range<C> empty() { return range((C)null, BoundType.CLOSED, null, BoundType.CLOSED); } public static <C> Range<C> empty(Comparator<? super C> comparator) { return range((C)null, BoundType.CLOSED, null, BoundType.CLOSED, comparator); } public static <C extends Comparable<? super C>> Range<C> encloseAll(Iterable<C> values) { C lower = values.iterator().next(); C upper = lower; for (C i : values) { if (lower.compareTo(i) > 0) lower = i; if (upper.compareTo(i) < 0) upper = i; } return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED); } public static <C> Range<C> encloseAll(Iterable<C> values, Comparator<? super C> comparator) { C lower = values.iterator().next(); C upper = lower; for (C i : values) { if (comparator.compare(lower, i) > 0) lower = i; if (comparator.compare(upper, i) < 0) upper = i; } return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED, comparator); } protected int compareLower(C value) { return compareLower(value, BoundType.CLOSED); } protected int compareLower(C value, BoundType boundType) { return compareLower(lower, lowerType, value, boundType); } protected int compareLower(C lower, BoundType lowerType, C value) { return compareLower(lower, lowerType, value, BoundType.CLOSED); } protected int compareLower(C lower, BoundType lowerType, C value, BoundType boundType) { if (lower == null) return value == null ? 0 : -1; else if (value == null) return 1; int compare; if (comparator == null) { @SuppressWarnings("unchecked") Comparable<C> comp = (Comparable<C>)lower; compare = comp.compareTo(value); } else compare = comparator.compare(lower, value); if (compare == 0) { if (lowerType == BoundType.CLOSED) -- compare; if (boundType == BoundType.CLOSED) ++ compare; } return compare; } protected int compareUpper(C value) { return compareUpper(value, BoundType.CLOSED); } protected int compareUpper(C value, BoundType boundType) { return compareUpper(upper, upperType, value, boundType); } protected int compareUpper(C upper, BoundType upperType, C value) { return compareUpper(upper, upperType, value, BoundType.CLOSED); } protected int compareUpper(C upper, BoundType upperType, C value, BoundType boundType) { if (upper == null) return value == null ? 0 : 1; if (value == null) return -1; int compare; if (comparator == null) { @SuppressWarnings("unchecked") Comparable<C> comp = (Comparable<C>)upper; compare = comp.compareTo(value); } else compare = comparator.compare(upper, value); if (compare == 0) { if (upperType == BoundType.CLOSED) ++ compare; if (boundType == BoundType.CLOSED) -- compare; } return compare; } public boolean hasLowerBound() { return lower != null; } public C lowerEndpoint() { if (hasLowerBound()) return lower; throw new IllegalStateException(); } public BoundType lowerBoundType() { if (hasLowerBound()) return lowerType; throw new IllegalStateException(); } public boolean hasUpperBound() { return upper != null; } public C upperEndpoint() { if (hasUpperBound()) return upper; throw new IllegalStateException(); } public BoundType upperBoundType() { if (hasUpperBound()) return upperType; throw new IllegalStateException(); } /** * この区間が空集合か判定します。 * @return 空集合ならばtrue */ public boolean isEmpty() { return lower == null && upper == null && lowerType == BoundType.CLOSED; } /** * 与えられた引数が区間の左側に位置するか判定します。<br> * 接する場合は区間の左側ではないと判定します。 * @param value 調べる引数 * @return 区間の左側に位置するならtrue */ public boolean isLess(C value) { return isLess(value, BoundType.CLOSED); } protected boolean isLess(C value, BoundType boundType) { return compareLower(value, boundType) > 0; } /** * 与えられた引数が区間の右側に位置するか判定します。<br> * 接する場合は区間の右側ではないと判定します。 * @param value 調べる引数 * @return 区間の右側に位置するならtrue */ public boolean isGreater(C value) { return isGreater(value, BoundType.CLOSED); } private boolean isGreater(C value, BoundType boundType) { return compareUpper(value, boundType) < 0; } /** * 与えられた引数が区間内に位置するか判定します。<br> * 接する場合も区間内に位置すると判定します。 * @param value 調べる引数 * @return 区間内に位置するならtrue */ public boolean contains(C value) { return !isLess(value) && !isGreater(value) && !isEmpty(); } /** * 与えられた引数すべてが区間内に位置するか判定します。<br> * 接する場合も区間内に位置すると判定します。 * @param value 調べる要素 * @return 全ての要素が区間内に位置するならtrue */ public boolean containsAll(Iterable<? extends C> values) { for (C i : values) if (!contains(i)) return false; return true; } /** * 与えられた区間がこの区間に内包されるか判定します。<br> * * @param other * @return 与えられた区間がこの区間に内包されるならtrue */ public boolean encloses(Range<C> other) { return !isLess(other.lower, other.lowerType) && !isGreater(other.upper, other.upperType); } /** * 与えられた区間がこの区間と公差するか判定します。<br> * 接する場合は公差するものとします。 * @param value 調べる引数 * @return 区間が交差するならtrue */ public boolean isConnected(Range<C> other) { if (this.isEmpty() || other.isEmpty()) return false; C lower, upper; BoundType lowerType, upperType; if (isLess(other.lower, other.lowerType)) { lower = other.lower; lowerType = other.lowerType; } else { lower = this.lower; lowerType = this.lowerType; } if (isGreater(other.upper, other.upperType)) { upper = other.upper; upperType = other.upperType; } else { upper = this.upper; upperType = this.upperType; } if (lower == null || upper == null) return true; int comp = compareLower(lower, lowerType, upper, upperType); return comp <= 0; } /** * この区間との積集合を返します。 * @param connectedRange 積集合を求める区間 * @return 積集合 */ public Range<C> intersection(Range<C> connectedRange) { if (this.isEmpty() || connectedRange.isEmpty()) { if (comparator == null) return new Range<C>(null, BoundType.CLOSED, null, BoundType.CLOSED); return empty(comparator); } C lower, upper; BoundType lowerType, upperType; if (isLess(connectedRange.lower, connectedRange.lowerType)) { lower = connectedRange.lower; lowerType = connectedRange.lowerType; } else { lower = this.lower; lowerType = this.lowerType; } if (isGreater(connectedRange.upper, connectedRange.upperType)) { upper = connectedRange.upper; upperType = connectedRange.upperType; } else { upper = this.upper; upperType = this.upperType; } if (comparator == null) { return new Range<C>(lower, lowerType, upper, upperType); } return range(lower, lowerType, upper, upperType, comparator); } /** * この区間との和集合を返します。 * @param other 和集合を求める区間 * @return 和集合 */ public Range<C> span(Range<C> other) { if (other.isEmpty()) return new Range<C>(lower, lowerType, upper, upperType); C lower, upper; BoundType lowerType, upperType; if (isLess(other.lower, other.lowerType)) { lower = this.lower; lowerType = this.lowerType; } else { lower = other.lower; lowerType = other.lowerType; } if (isGreater(other.upper, other.upperType)) { upper = this.upper; upperType = this.upperType; } else { upper = other.upper; upperType = other.upperType; } return new Range<C>(lower, lowerType, upper, upperType, comparator); } @Override public boolean equals(Object object) { if (this == object) return true; if (object instanceof Range) { @SuppressWarnings("unchecked") Range<C> comp = (Range<C>) object; return compareLower(comp.lower, comp.lowerType) == 0 && compareUpper(comp.upper, comp.upperType) == 0 && lowerType == comp.lowerType && upperType == comp.upperType; } return false; } @Override public int hashCode() { if (lower == null && upper == null) return 0; else if (lower == null) return upper.hashCode(); else if (upper == null) return lower.hashCode(); return lower.hashCode() ^ upper.hashCode(); } @Override public String toString() { if (isEmpty()) return "()"; return (lowerType == BoundType.OPEN ? "(" : "[") + (lower == null ? "" : lower.toString()) + ".." + (upper == null ? "" : upper.toString()) + (upperType == BoundType.OPEN ? ")" : "]"); } } public static class IterableRange<C> extends Range<C> implements Iterable<C>{ private static final long serialVersionUID = 9065915259748260688L; protected UnaryOperator<C> func; protected IterableRange(C lower, BoundType lowerType, C upper, BoundType upperType, UnaryOperator<C> func) { super(lower, lowerType, upper, upperType); this.func = func; } public static <C extends Comparable<? super C>> IterableRange<C> range(C lower, BoundType lowerType, C upper, BoundType upperType, UnaryOperator<C> func) { if (lower == null || upper == null) return new IterableRange<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, func); int comp = lower.compareTo(upper); if (comp > 0) return new IterableRange<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, func); else if (comp == 0 && (lowerType == BoundType.OPEN || upperType == BoundType.OPEN)) return new IterableRange<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, func); return new IterableRange<C>(lower, lowerType, upper, upperType, func); } public static <C extends Comparable<? super C>> IterableRange<C> open(C lower, C upper, UnaryOperator<C> func) { if (lower == null) return new IterableRange<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, func); return range(func.apply(lower), BoundType.CLOSED, upper, BoundType.OPEN, func); } public static <C extends Comparable<? super C>> IterableRange<C> openClosed(C lower, C upper, UnaryOperator<C> func) { if (lower == null) return new IterableRange<C>(null, BoundType.CLOSED, null, BoundType.CLOSED, func); return range(func.apply(lower), BoundType.CLOSED, upper, BoundType.CLOSED, func); } public static <C extends Comparable<? super C>> IterableRange<C> closedOpen(C lower, C upper, UnaryOperator<C> func) { return range(lower, BoundType.CLOSED, upper, BoundType.OPEN, func); } public static <C extends Comparable<? super C>> IterableRange<C> closed(C lower, C upper, UnaryOperator<C> func) { return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED, func); } public static <C extends Comparable<? super C>> IterableRange<C> singleton(C value, UnaryOperator<C> func) { return range(value, BoundType.CLOSED, value, BoundType.CLOSED, func); } protected class Iter implements Iterator<C> { C now; Iter() { now = lower; } @Override public final boolean hasNext() { return !isGreater(now); } @Override public final C next() { C ret = now; now = func.apply(now); return ret; } @Override public final void remove() { throw new UnsupportedOperationException(); } } protected class EmptyIter implements Iterator<C> { @Override public boolean hasNext() { return false; } @Override public C next() { return null; } @Override public final void remove() { throw new UnsupportedOperationException(); } } @Override public Iterator<C> iterator() { return lower == null || upper == null ? new EmptyIter() : new Iter(); } public int getDistance() { C check = upper; int ret = 0; while (lower != check) { check = func.apply(check); ++ ret; } return ret; } } public static class IntRange extends IterableRange<Integer>{ private static final long serialVersionUID = 5623995336491967216L; private final boolean useFastIter; private static class Next implements UnaryOperator<Integer> { @Override public Integer apply(Integer value) { return value + 1; } } protected IntRange() { super(null, BoundType.CLOSED, null, BoundType.CLOSED, new Next()); useFastIter = true; } protected IntRange(UnaryOperator<Integer> func) { super(null, BoundType.CLOSED, null, BoundType.CLOSED, func); useFastIter = false; } protected IntRange(int lower, BoundType lowerType, int upper, BoundType upperType) { super(lower, lowerType, upper, upperType, new Next()); useFastIter = true; } protected IntRange(int lower, BoundType lowerType, int upper, BoundType upperType, UnaryOperator<Integer> func) { super(lower, lowerType, upper, upperType, func); useFastIter = false; } public static IntRange range(int lower, BoundType lowerType, int upper, BoundType upperType) { if (lower > upper) return new IntRange(); if (lowerType == BoundType.OPEN) ++ lower; if (upperType == BoundType.OPEN) -- upper; return new IntRange(lower, BoundType.CLOSED, upper, BoundType.CLOSED); } public static IntRange range(int lower, BoundType lowerType, int upper, BoundType upperType, UnaryOperator<Integer> func) { if (lower > upper) return new IntRange(func); if (lowerType == BoundType.OPEN) ++ lower; if (upperType == BoundType.OPEN) -- upper; return new IntRange(lower, BoundType.CLOSED, upper, BoundType.CLOSED, func); } public static IntRange open(int lower, int upper) { return range(lower, BoundType.OPEN, upper, BoundType.OPEN); } public static IntRange open(int lower, int upper, UnaryOperator<Integer> func) { return range(lower, BoundType.OPEN, upper, BoundType.OPEN, func); } public static IntRange open(int upper) { return range(0, BoundType.CLOSED, upper, BoundType.OPEN); } public static IntRange open(int upper, UnaryOperator<Integer> func) { return range(0, BoundType.CLOSED, upper, BoundType.OPEN, func); } public static IntRange openClosed(int lower, int upper) { return range(lower, BoundType.OPEN, upper, BoundType.CLOSED); } public static IntRange openClosed(int lower, int upper, UnaryOperator<Integer> func) { return range(lower, BoundType.OPEN, upper, BoundType.CLOSED, func); } public static IntRange closedOpen(int lower, int upper) { return range(lower, BoundType.CLOSED, upper, BoundType.OPEN); } public static IntRange closedOpen(int lower, int upper, UnaryOperator<Integer> func) { return range(lower, BoundType.CLOSED, upper, BoundType.OPEN, func); } public static IntRange closed(int lower, int upper) { return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED); } public static IntRange closed(int lower, int upper, UnaryOperator<Integer> func) { return range(lower, BoundType.CLOSED, upper, BoundType.CLOSED, func); } public static IntRange closed(int upper) { return range(0, BoundType.CLOSED, upper, BoundType.CLOSED); } public static IntRange closed(int upper, UnaryOperator<Integer> func) { return range(0, BoundType.CLOSED, upper, BoundType.CLOSED, func); } public static IntRange singleton(int value) { return range(value, BoundType.CLOSED, value, BoundType.CLOSED); } public static IntRange singleton(int value, UnaryOperator<Integer> func) { return range(value, BoundType.CLOSED, value, BoundType.CLOSED, func); } private class FastIter implements Iterator<Integer> { int now; public FastIter() { now = lower; } @Override public final boolean hasNext() { return now <= upper; } @Override public final Integer next() { return now++; } @Override public final void remove() { throw new UnsupportedOperationException(); } } private class Iter implements Iterator<Integer> { int now; public Iter() { now = lower; } @Override public final boolean hasNext() { return now <= upper; } @Override public final Integer next() { int ret = now; now = func.apply(now); return ret; } @Override public final void remove() { throw new UnsupportedOperationException(); } } @Override public Iterator<Integer> iterator() { return lower == null || upper == null ? new EmptyIter() : useFastIter ? new FastIter() : new Iter(); } @Override public int getDistance() { int ret = upper - lower; if (upperType == BoundType.CLOSED) ++ ret; return ret; } public int getClosedLower() { return lower; } public int getOpenLower() { return lower - 1; } public int getClosedUpper() { return upperType == BoundType.CLOSED ? upper : upper - 1; } public int getOpenUpper() { return upperType == BoundType.CLOSED ? upper + 1 : upper; } } public interface Associative<T> extends BinaryOperator<T>{ } public interface Inverse<T> { public T inverse(T element); } public interface Commutative<T> extends BinaryOperator<T>{ } public interface Unit<T> { public T unit(); } public interface Group<T> extends Monoid<T>, Inverse<T>{ } public interface CommutativeMonoid<T> extends Monoid<T>, Commutative<T> { } public interface Abelian<T> extends Group<T>, CommutativeMonoid<T> { } public interface Monoid<T> extends Associative<T>, Unit<T> { } public interface Semiring<T, A extends CommutativeMonoid<T>, M extends Monoid<T>> { } public interface Ring<T, A extends Abelian<T>, M extends Monoid<T>> extends Semiring<T, A, M>{ public A getAddition(); public M getMultiplication(); } public interface CommutativeRing<T, A extends Abelian<T>, M extends CommutativeMonoid<T>> extends Ring<T, A, M>{ } public class ModInteger extends Number implements CommutativeRing<ModInteger, Abelian<ModInteger>, CommutativeMonoid<ModInteger>>{ private static final long serialVersionUID = -8595710127161317579L; private final int mod; private int num; private final Addition add; private final Multiplication mul; private class Addition implements Abelian<ModInteger> { @Override public ModInteger unit() { return new ModInteger(mod, 0); } @Override public ModInteger inverse(ModInteger element) { return new ModInteger(element, element.mod - element.num); } @Override public ModInteger apply(ModInteger left, ModInteger right) { return new ModInteger(left).addEqual(right); } } private class Multiplication implements Abelian<ModInteger> { @Override public ModInteger unit() { return new ModInteger(mod, 1); } @Override public ModInteger apply(ModInteger left, ModInteger right) { return new ModInteger(left).multiplyEqual(right); } @Override public ModInteger inverse(ModInteger element) { return new ModInteger(element, element.inverse(element.num)); } } public ModInteger(int mod) { this.mod = mod; num = 0; add = new Addition(); mul = new Multiplication(); } public ModInteger(int mod, int num) { this.mod = mod; this.num = validNum(num); add = new Addition(); mul = new Multiplication(); } public ModInteger(ModInteger n) { mod = n.mod; num = n.num; add = n.add; mul = n.mul; } private ModInteger(ModInteger n, int num) { mod = n.mod; this.num = num; add = n.add; mul = n.mul; } private int validNum(int n) { n %= mod; if (n < 0) n += mod; return n; } private int validNum(long n) { n %= mod; if (n < 0) n += mod; return (int)n; } protected int inverse(int n) { int m = mod, u = 0, v = 1, t; while(n != 0) { t = m / n; m -= t * n; u -= t * v; if (m != 0) { t = n / m; n -= t * m; v -= t * u; } else { v %= mod; if (v < 0) v += mod; return v; } } u %= mod; if (u < 0) u += mod; return u; } public boolean isPrime(int n) { if ((n & 1) == 0) return false; // 偶数 for (int i = 3, j = 8, k = 9;k <= n;i += 2, k += j += 8) if (n % i == 0) return false; return true; } @Override public int intValue() { return num; } @Override public long longValue() { return num; } @Override public float floatValue() { return num; } @Override public double doubleValue() { return num; } public ModInteger add(int n) { return new ModInteger(this).addEqual(n); } public ModInteger add(long n) { return new ModInteger(this).addEqual(n); } public ModInteger add(ModInteger n) { return new ModInteger(this).addEqual(n); } public ModInteger addEqual(int n) { num = validNum(num + n); return this; } public ModInteger addEqual(long n) { num = validNum(num + n); return this; } public ModInteger addEqual(ModInteger n) { if ((num += n.num) >= mod) num -= mod; return this; } public ModInteger subtract(int n) { return new ModInteger(this).subtractEqual(n); } public ModInteger subtract(long n) { return new ModInteger(this).subtractEqual(n); } public ModInteger subtract(ModInteger n) { return new ModInteger(this).subtractEqual(n); } public ModInteger subtractEqual(int n) { num = validNum(num - n); return this; } public ModInteger subtractEqual(long n) { num = validNum(num - n); return this; } public ModInteger subtractEqual(ModInteger n) { if ((num -= n.num) < 0) num += mod; return this; } public ModInteger multiply(int n) { return new ModInteger(this).multiplyEqual(n); } public ModInteger multiply(long n) { return new ModInteger(this).multiplyEqual(n); } public ModInteger multiply(ModInteger n) { return new ModInteger(this).multiplyEqual(n); } public ModInteger multiplyEqual(int n) { num = (int)((long)num * n % mod); if (num < 0) num += mod; return this; } public ModInteger multiplyEqual(long n) { return multiplyEqual((int) (n % mod)); } public ModInteger multiplyEqual(ModInteger n) { num = (int)((long)num * n.num % mod); return this; } public ModInteger divide(int n) { return new ModInteger(this).divideEqual(n); } public ModInteger divide(long n) { return new ModInteger(this).divideEqual(n); } public ModInteger divide(ModInteger n) { return new ModInteger(this).divideEqual(n); } public ModInteger divideEqual(int n) { num = (int)((long)num * inverse(validNum(n)) % mod); return this; } public ModInteger divideEqual(long n) { return divideEqual((int)(n % mod)); } public ModInteger divideEqual(ModInteger n) { num = (int)((long)num * n.inverse(n.num) % mod); return this; } public ModInteger pow(int n) { return new ModInteger(this).powEqual(n); } public ModInteger pow(long n) { return new ModInteger(this).powEqual(n); } public ModInteger pow(ModInteger n) { return new ModInteger(this).powEqual(n); } public ModInteger powEqual(int n) { long ans = 1, num = this.num; if (n < 0) { n = -n; while (n != 0) { if ((n & 1) != 0) ans = ans * num % mod; n >>>= 1; num = num * num % mod; } this.num = inverse((int)ans); return this; } while (n != 0) { if ((n & 1) != 0) ans = ans * num % mod; n >>>= 1; num = num * num % mod; } this.num = (int)ans; return this; } public ModInteger powEqual(long n) { return powEqual((int)(n % (mod - 1))); } public ModInteger powEqual(ModInteger n) { long num = this.num; this.num = 1; int mul = n.num; while (mul != 0) { if ((mul & 1) != 0) this.num *= num; mul >>>= 1; num *= num; num %= mod; } return this; } public ModInteger equal(int n) { num = validNum(n); return this; } public ModInteger equal(long n) { num = validNum(n); return this; } public ModInteger equal(ModInteger n) { num = n.num; return this; } public int toInt() { return num; } public int getMod() { return mod; } @Override public boolean equals(Object x) { if (x instanceof ModInteger) return ((ModInteger)x).num == num && ((ModInteger)x).mod == mod; return false; } @Override public int hashCode() { return num ^ mod; } @Override public String toString() { return String.valueOf(num); } @Deprecated public String debug() { int min = num, ans = 1; for (int i = 2;i < min;++ i) { int tmp = multiply(i).num; if (min > tmp) { min = tmp; ans = i; } } return min + "/" + ans; } @Override public Addition getAddition() { return add; } @Override public Multiplication getMultiplication() { return mul; } } /** * 素数を法とする演算上で、組み合わせの計算を高速に行います。 * @author 31536000 * */ public class ModUtility { private final int mod, totient; private int[] fact, inv, invfact; /** * modを法とする * @param mod */ public ModUtility(int mod) { this(mod, 2); } public ModUtility(int mod, int calc) { if (mod <= 0) throw new IllegalArgumentException("illegal mod: " + mod); this.mod = mod; int totient = mod; for (int i = 2;i * i <= mod;++ i) { if (mod % i == 0) { totient = totient / i * (i - 1); while ((mod %= i) % i == 0); } } this.totient = totient; precalc(calc); } public void precalc(int calc) { if (calc < 2) calc = 2; fact = new int[calc]; inv = new int[calc]; invfact = new int[calc]; fact[0] = invfact[0] = fact[1] = invfact[1] = inv[1] = 1; for (int i = 2;i < calc;++ i) { fact[i] = (int)((long)fact[i - 1] * i % mod); inv[i] = (int)(mod - (long)inv[mod % i] * (mod / i) % mod); invfact[i] = (int)((long)invfact[i - 1] * inv[i] % mod); } } public ModInteger create() { return create(0); } public ModInteger create(int n) { return new ModInt(n); } private class ModInt extends ModInteger { private static final long serialVersionUID = -2435281861935422575L; public ModInt(int n) { super(mod, n); } @Override protected int inverse(int n) { return ModUtility.this.inverse(n); } } public int inverse(int n) { try { if (inv.length > n) return inv[n]; int m = mod, u = 0, v = 1, t; while(n != 0) { t = m / n; m -= t * n; u -= t * v; if (m != 0) { t = n / m; n -= t * m; v -= t * u; } else { v %= mod; if (v < 0) v += mod; return v; } } u %= mod; if (u < 0) u += mod; return u; } catch (ArrayIndexOutOfBoundsException e) { throw new IllegalArgumentException(); } } public int factorial(int n) { try { if (fact.length > n) return fact[n]; long ret = fact[fact.length - 1]; for (int i = fact.length;i <= n;++ i) ret = ret * i % mod; return (int)ret; } catch (ArrayIndexOutOfBoundsException e) { throw new IllegalArgumentException(); } } public int permutation(int n, int k) { if (k < 0) throw new IllegalArgumentException(); if (n < k) return 0; if (fact.length > n) return (int)((long)fact[n] * invfact[n - k] % mod); long ret = 1; for (int i = n - k + 1;i <= n;++ i) ret = ret * i % mod; return (int)ret; } public int combination(int n, int k) { if (k < 0) throw new IllegalArgumentException(); if (n < k) return 0; if (fact.length > n) return (int)((long)fact[n] * invfact[k] % mod * invfact[n - k] % mod); long ret = 1; if (n < 2 * k) k = n - k; if (invfact.length > k) ret = invfact[k]; else ret = inverse(factorial(k)); for (int i = n - k + 1;i <= n;++ i) ret = ret * i % mod; return (int)ret; } public int multinomial(int n, int... k) { int sum = 0; for (int i : k) sum += i; long ret = factorial(n); if (fact.length > n) { for (int i : k) { if (i < 0) throw new IllegalArgumentException(); ret = ret * invfact[i] % mod; sum += i; } if (sum > n) return 0; ret = ret * invfact[n - sum] % mod; } else { for (int i : k) { if (i < 0) throw new IllegalArgumentException(); if (invfact.length > i) ret = ret * invfact[i] % mod; else ret = ret * inverse(factorial(i)) % mod; sum += i; } if (sum > n) return 0; if (invfact.length > n - sum) ret = ret * invfact[n - sum] % mod; else ret = ret * inverse(factorial(n - sum)) % mod; } return (int)ret; } public int multichoose(int n, int k) { return combination(mod(n + k - 1), k); } public int catalan(int n) { return divide(combination(mod(2 * n), n), mod(n + 1)); } public int pow(int n, int m) { long ans = 1, num = n; if (m < 0) { m = -m; while (m != 0) { if ((m & 1) != 0) ans = ans * num % mod; m >>>= 1; num = num * num % mod; } return inverse((int)ans); } while (m != 0) { if ((m & 1) != 0) ans = ans * num % mod; m >>>= 1; num = num * num % mod; } return (int)ans; } public int pow(long n, long m) { return pow((int)(n % mod), (int)(m % (mod - 1))); } public int totient() { return totient; } public boolean isPrime() { return totient == mod - 1; } public int mod(int n) { return (n %= mod) < 0 ? n + mod : n; } public int mod(long n) { return (int)((n %= mod) < 0 ? n + mod : n); } public int add(int n, int m) { return mod(n + m); } public int add(long n, long m) { return mod(n + m); } public int subtract(int n, int m) { return mod(n - m); } public int subtract(long n, long m) { return mod(n - m); } public int multiply(int n, int m) { int ans = (int)((long)n * m % mod); return ans < 0 ? ans + mod : ans; } public int multiply(long n, long m) { return multiply(mod(n), mod(m)); } public int divide(int n, int m) { return multiply(n, inverse(mod(m))); } public int divide(long n, long m) { return multiply(n, inverse(mod(m))); } } }