private static Either<String, RegistrationsUpdate> registrationsUpdate(JsonNode jsonNode) {
    Either<String, BillingCompany> billingCompany =
        ArgoUtils.stringValue(jsonNode, "billingCompany").right().map(BillingCompany::new);
    Either<String, Badge> badge = ArgoUtils.stringValue(jsonNode, "badge").right().map(Badge::new);
    Either<String, String> dietaryRequirements =
        ArgoUtils.stringValue(jsonNode, "dietaryRequirements");
    Either<String, Option<String>> bundle =
        ArgoUtils.stringValue(jsonNode, "bundle")
            .right()
            .map(Option::fromNull)
            .right()
            .map(r -> r.filter(Strings.isNotNullOrEmpty));

    return bundle
        .right()
        .apply(
            dietaryRequirements
                .right()
                .apply(
                    badge
                        .right()
                        .apply(
                            billingCompany
                                .right()
                                .apply(Either.right(Function.curry(RegistrationsUpdate::new))))));
  }
Beispiel #2
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 /**
  * Invariant functor map over this enumerator.
  *
  * @param f The covariant map.
  * @param g The contra-variant map.
  * @return An enumerator after the given functions are applied.
  */
 public <B> Enumerator<B> xmap(final F<A, B> f, final F<B, A> g) {
   final F<Option<A>, Option<B>> of = o -> o.map(f);
   return enumerator(
       compose(compose(of, successor), g),
       compose(compose(of, predecessor), g),
       max.map(f),
       min.map(f),
       order.contramap(g),
       compose(compose(Function.<Long, Option<A>, Option<B>>compose().f(of), plus), g));
 }
Beispiel #3
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/**
 * Abstracts over a type that may have a successor and/or predecessor value. This implies ordering
 * for that type. A user may construct an enumerator with an optimised version for <code>plus</code>
 * , otherwise a default is implemented using the given successor/predecessor implementations.
 *
 * <p>For any enumerator e, the following laws must satisfy:
 *
 * <ul>
 *   <li>forall a. e.successor(a).forall(\t -> e.predecessor(t).forall(\z -> z == a))
 *   <li>forall a. e.predecessor(a).forall(\t -> e.successor(t).forall(\z -> z == a))
 *   <li>e.max().forall(\t -> e.successor(t).isNone)
 *   <li>e.min().forall(\t -> e.predecessor(t).isNone)
 *   <li>forall a n. e.plus(a, 0) == Some(a)
 *   <li>forall a n | n > 0. e.plus(a, n) == e.plus(a, n - 1)
 *   <li>forall a n | n < 0. e.plus(a, n) == e.plus(a, n + 1)
 * </ul>
 *
 * @version %build.number%
 */
public final class Enumerator<A> {
  private final F<A, Option<A>> successor;
  private final F<A, Option<A>> predecessor;
  private final Option<A> max;
  private final Option<A> min;
  private final Ord<A> order;
  private final F<A, F<Long, Option<A>>> plus;

  private Enumerator(
      final F<A, Option<A>> successor,
      final F<A, Option<A>> predecessor,
      final Option<A> max,
      final Option<A> min,
      final Ord<A> order,
      final F<A, F<Long, Option<A>>> plus) {
    this.successor = successor;
    this.predecessor = predecessor;
    this.max = max;
    this.min = min;
    this.order = order;
    this.plus = plus;
  }

  /**
   * Returns the potential successor of a value for this enumerator in curried form.
   *
   * @return The potential successor of a value for this enumerator in curried form.
   */
  public F<A, Option<A>> successor() {
    return successor;
  }

  /**
   * Returns the potential successor of a value for this enumerator.
   *
   * @param a The value to return the successor of.
   * @return The potential successor of a value for this enumerator.
   */
  public Option<A> successor(final A a) {
    return successor.f(a);
  }

  /**
   * Returns the potential predecessor of a value for this enumerator in curried form.
   *
   * @return The potential predecessor of a value for this enumerator in curried form.
   */
  public F<A, Option<A>> predecessor() {
    return predecessor;
  }

  /**
   * Returns the potential predecessor of a value for this enumerator.
   *
   * @param a The value to return the predecessor of.
   * @return The potential predecessor of a value for this enumerator.
   */
  public Option<A> predecessor(final A a) {
    return predecessor.f(a);
  }

  /**
   * Returns the maximum value for this enumerator if there is one.
   *
   * @return The maximum value for this enumerator if there is one.
   */
  public Option<A> max() {
    return max;
  }

  /**
   * Returns the minimum value for this enumerator if there is one.
   *
   * @return The minimum value for this enumerator if there is one.
   */
  public Option<A> min() {
    return min;
  }

  /**
   * Returns a function that moves a value along the enumerator a given number of times.
   *
   * @return A function that moves a value along the enumerator a given number of times.
   */
  public F<A, F<Long, Option<A>>> plus() {
    return plus;
  }

  /**
   * Returns a function that moves a value along the enumerator a given number of times.
   *
   * @param a The value to begin moving along from.
   * @return A function that moves a value along the enumerator a given number of times.
   */
  public F<Long, Option<A>> plus(final A a) {
    return plus.f(a);
  }

  /**
   * Returns a function that moves a value along the enumerator a given number of times.
   *
   * @param l The number of times to move along the enumerator.
   * @return A function that moves a value along the enumerator a given number of times.
   */
  public F<A, Option<A>> plus(final long l) {
    return flip(plus).f(l);
  }

  /**
   * Moves a value along the enumerator a given number of times.
   *
   * @param a The value to begin moving along from.
   * @param l The number of times to move along the enumerator.
   * @return A potential value after having moved the given number of times.
   */
  public Option<A> plus(final A a, final long l) {
    return plus.f(a).f(l);
  }

  /**
   * Returns the ordering for the enumerator.
   *
   * @return The ordering for the enumerator.
   */
  public Ord<A> order() {
    return order;
  }

  /**
   * Invariant functor map over this enumerator.
   *
   * @param f The covariant map.
   * @param g The contra-variant map.
   * @return An enumerator after the given functions are applied.
   */
  public <B> Enumerator<B> xmap(final F<A, B> f, final F<B, A> g) {
    final F<Option<A>, Option<B>> of = o -> o.map(f);
    return enumerator(
        compose(compose(of, successor), g),
        compose(compose(of, predecessor), g),
        max.map(f),
        min.map(f),
        order.contramap(g),
        compose(compose(Function.<Long, Option<A>, Option<B>>compose().f(of), plus), g));
  }

  /**
   * Returns a stream of the values from this enumerator, starting at the given value, counting up.
   *
   * @param a A value at which to begin the stream.
   * @return a stream of the values from this enumerator, starting at the given value, counting up.
   */
  public Stream<A> toStream(final A a) {
    final F<A, A> id = identity();
    return Stream.fromFunction(this, id, a);
  }

  /**
   * Create a new enumerator with the given minimum value.
   *
   * @param min A minimum value.
   * @return A new enumerator identical to this one, but with the given minimum value.
   */
  public Enumerator<A> setMin(final Option<A> min) {
    return enumerator(successor, predecessor, max, min, order, plus);
  }

  /**
   * Create a new enumerator with the given maximum value.
   *
   * @param max A maximum value.
   * @return A new enumerator identical to this one, but with the given maximum value.
   */
  public Enumerator<A> setMax(final Option<A> max) {
    return enumerator(successor, predecessor, max, min, order, plus);
  }

  /**
   * Construct an enumerator. `
   *
   * @param successor The successor function.
   * @param predecessor The predecessor function.
   * @param max The potential maximum value.
   * @param min The potential minimum value.
   * @param order The ordering for the type.
   * @param plus The function to move the enumeration a given number of times. This may be supplied
   *     for a performance enhancement for certain types.
   * @return An enumerator with the given values.
   */
  public static <A> Enumerator<A> enumerator(
      final F<A, Option<A>> successor,
      final F<A, Option<A>> predecessor,
      final Option<A> max,
      final Option<A> min,
      final Ord<A> order,
      final F<A, F<Long, Option<A>>> plus) {
    return new Enumerator<A>(successor, predecessor, max, min, order, plus);
  }

  /**
   * Construct an enumerator. The <code>plus</code> function is derived from the <code>successor
   * </code> and <code>predecessor</code>.
   *
   * @param successor The successor function.
   * @param predecessor The predecessor function.
   * @param max The potential maximum value.
   * @param min The potential minimum value.
   * @param order The ordering for the type.
   * @return An enumerator with the given values.
   */
  public static <A> Enumerator<A> enumerator(
      final F<A, Option<A>> successor,
      final F<A, Option<A>> predecessor,
      final Option<A> max,
      final Option<A> min,
      final Ord<A> order) {
    return new Enumerator<A>(
        successor,
        predecessor,
        max,
        min,
        order,
        curry(
            (a, l) -> {
              if (l == 0L) return some(a);
              else if (l < 0L) {
                A aa = a;
                for (long x = l; x < 0; x++) {
                  final Option<A> s = predecessor.f(aa);
                  if (s.isNone()) return none();
                  else aa = s.some();
                }
                return some(aa);
              } else {
                A aa = a;
                for (long x = l; x > 0; x--) {
                  final Option<A> s = successor.f(aa);
                  if (s.isNone()) return none();
                  else aa = s.some();
                }
                return some(aa);
              }
            }));
  }

  /** An enumerator for <code>boolean</code>. */
  public static final Enumerator<Boolean> booleanEnumerator =
      enumerator(
          b -> b ? Option.<Boolean>none() : some(true),
          b -> b ? some(false) : Option.<Boolean>none(),
          some(true),
          some(false),
          booleanOrd);

  /** An enumerator for <code>byte</code>. */
  public static final Enumerator<Byte> byteEnumerator =
      enumerator(
          b -> b == Byte.MAX_VALUE ? Option.<Byte>none() : some((byte) (b + 1)),
          b -> b == Byte.MIN_VALUE ? Option.<Byte>none() : some((byte) (b - 1)),
          some(Byte.MAX_VALUE),
          some(Byte.MIN_VALUE),
          byteOrd);

  /** An enumerator for <code>char</code>. */
  public static final Enumerator<Character> charEnumerator =
      enumerator(
          c -> c == Character.MAX_VALUE ? Option.<Character>none() : some((char) (c + 1)),
          c -> c == Character.MIN_VALUE ? Option.<Character>none() : some((char) (c - 1)),
          some(Character.MAX_VALUE),
          some(Character.MIN_VALUE),
          charOrd);

  /** An enumerator for <code>double</code>. */
  public static final Enumerator<Double> doubleEnumerator =
      enumerator(
          d -> d == Double.MAX_VALUE ? Option.<Double>none() : some(d + 1D),
          d -> d == Double.MIN_VALUE ? Option.<Double>none() : some(d - 1D),
          some(Double.MAX_VALUE),
          some(Double.MIN_VALUE),
          doubleOrd);

  /** An enumerator for <code>float</code>. */
  public static final Enumerator<Float> floatEnumerator =
      enumerator(
          f -> f == Float.MAX_VALUE ? Option.<Float>none() : some(f + 1F),
          f -> f == Float.MIN_VALUE ? Option.<Float>none() : some(f - 1F),
          some(Float.MAX_VALUE),
          some(Float.MIN_VALUE),
          floatOrd);

  /** An enumerator for <code>int</code>. */
  public static final Enumerator<Integer> intEnumerator =
      enumerator(
          i -> i == Integer.MAX_VALUE ? Option.<Integer>none() : some(i + 1),
          i -> i == Integer.MIN_VALUE ? Option.<Integer>none() : some(i - 1),
          some(Integer.MAX_VALUE),
          some(Integer.MIN_VALUE),
          intOrd);

  /** An enumerator for <code>BigInteger</code>. */
  public static final Enumerator<BigInteger> bigintEnumerator =
      enumerator(
          i -> some(i.add(BigInteger.ONE)),
          i -> some(i.subtract(BigInteger.ONE)),
          Option.<BigInteger>none(),
          Option.<BigInteger>none(),
          bigintOrd,
          curry((i, l) -> some(i.add(BigInteger.valueOf(l)))));

  /** An enumerator for <code>BigDecimal</code>. */
  public static final Enumerator<BigDecimal> bigdecimalEnumerator =
      enumerator(
          i -> some(i.add(BigDecimal.ONE)),
          i -> some(i.subtract(BigDecimal.ONE)),
          Option.<BigDecimal>none(),
          Option.<BigDecimal>none(),
          bigdecimalOrd,
          curry((d, l) -> some(d.add(BigDecimal.valueOf(l)))));

  /** An enumerator for <code>long</code>. */
  public static final Enumerator<Long> longEnumerator =
      enumerator(
          i -> i == Long.MAX_VALUE ? Option.<Long>none() : some(i + 1L),
          i -> i == Long.MIN_VALUE ? Option.<Long>none() : some(i - 1L),
          some(Long.MAX_VALUE),
          some(Long.MIN_VALUE),
          longOrd);

  /** An enumerator for <code>short</code>. */
  public static final Enumerator<Short> shortEnumerator =
      enumerator(
          i -> i == Short.MAX_VALUE ? Option.<Short>none() : some((short) (i + 1)),
          i -> i == Short.MIN_VALUE ? Option.<Short>none() : some((short) (i - 1)),
          some(Short.MAX_VALUE),
          some(Short.MIN_VALUE),
          shortOrd);

  /** An enumerator for <code>Ordering</code>. */
  public static final Enumerator<Ordering> orderingEnumerator =
      enumerator(
          o -> o == LT ? some(EQ) : o == EQ ? some(GT) : Option.<Ordering>none(),
          o -> o == GT ? some(EQ) : o == EQ ? some(LT) : Option.<Ordering>none(),
          some(GT),
          some(LT),
          orderingOrd);

  /** An enumerator for <code>Natural</code> */
  public static final Enumerator<Natural> naturalEnumerator =
      enumerator(
          n -> Option.some(n.succ()),
          n -> n.pred(),
          Option.<Natural>none(),
          some(Natural.ZERO),
          naturalOrd,
          curry(
              (n, l) ->
                  some(n).apply(Natural.natural(l).map(Function.curry((n1, n2) -> n1.add(n2))))));
}
Beispiel #4
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 public <B> HashMap<K, B> mapValues(F<V, B> function) {
   return map(Function.identity(), function, e, h);
 }
Beispiel #5
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 public <A> HashMap<A, V> mapKeys(F<K, A> keyFunction, Equal<A> equal, Hash<A> hash) {
   return map(keyFunction, Function.identity(), equal, hash);
 }
Beispiel #6
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 /**
  * Anonymous bind through this projection.
  *
  * @param e The value to bind with.
  * @return An either after binding through this projection.
  */
 public <X> Either<A, X> sequence(final Either<A, X> e) {
   return bind(Function.<B, Either<A, X>>constant(e));
 }
Beispiel #7
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 /**
  * Anonymous bind through this projection.
  *
  * @param e The value to bind with.
  * @return An either after binding through this projection.
  */
 public <X> Either<X, B> sequence(final Either<X, B> e) {
   return bind(Function.<A, Either<X, B>>constant(e));
 }