Exemplo n.º 1
0
 /** Convert an amount expressed in the way humans are used to into satoshis. */
 public static Coin valueOf(final int coins, final int cents) {
   checkArgument(cents < 100);
   checkArgument(cents >= 0);
   checkArgument(coins >= 0);
   final Coin coin = COIN.multiply(coins).add(CENT.multiply(cents));
   checkArgument(coin.compareTo(NetworkParameters.MAX_MONEY) <= 0);
   return coin;
 }
  @GuardedBy("lock")
  private void receiveUpdatePaymentMessage(Protos.UpdatePayment msg, boolean sendAck)
      throws VerificationException, ValueOutOfRangeException, InsufficientMoneyException {
    log.info("Got a payment update");

    Coin lastBestPayment = state.getBestValueToMe();
    final Coin refundSize = Coin.valueOf(msg.getClientChangeValue());
    boolean stillUsable = state.incrementPayment(refundSize, msg.getSignature().toByteArray());
    Coin bestPaymentChange = state.getBestValueToMe().subtract(lastBestPayment);

    ListenableFuture<ByteString> ackInfoFuture = null;
    if (bestPaymentChange.signum() > 0) {
      ByteString info = (msg.hasInfo()) ? msg.getInfo() : null;
      ackInfoFuture = conn.paymentIncrease(bestPaymentChange, state.getBestValueToMe(), info);
    }

    if (sendAck) {
      final Protos.TwoWayChannelMessage.Builder ack = Protos.TwoWayChannelMessage.newBuilder();
      ack.setType(Protos.TwoWayChannelMessage.MessageType.PAYMENT_ACK);
      if (ackInfoFuture == null) {
        conn.sendToClient(ack.build());
      } else {
        Futures.addCallback(
            ackInfoFuture,
            new FutureCallback<ByteString>() {
              @Override
              public void onSuccess(@Nullable ByteString result) {
                if (result != null) ack.setPaymentAck(ack.getPaymentAckBuilder().setInfo(result));
                conn.sendToClient(ack.build());
              }

              @Override
              public void onFailure(Throwable t) {
                log.info("Failed retrieving paymentIncrease info future");
                error(
                    "Failed processing payment update",
                    Protos.Error.ErrorCode.OTHER,
                    CloseReason.UPDATE_PAYMENT_FAILED);
              }
            });
      }
    }

    if (!stillUsable) {
      log.info("Channel is now fully exhausted, closing/initiating settlement");
      settlePayment(CloseReason.CHANNEL_EXHAUSTED);
    }
  }
Exemplo n.º 3
0
 /** Similar to parseCoin, but allows for inexact representations to be rounded */
 public static Coin parseCoinInexact(final String str) {
   return Coin.valueOf(
       new BigDecimal(str)
           .movePointRight(SMALLEST_UNIT_EXPONENT)
           .setScale(0, BigDecimal.ROUND_HALF_UP)
           .toBigInteger()
           .longValue());
 }
Exemplo n.º 4
0
/** Represents a monetary Bitcoin value. This class is immutable. */
public final class Coin implements Monetary, Comparable<Coin>, Serializable {

  /**
   * Number of decimals for one Peercoin. This constant is useful for quick adapting to other coins
   * because a lot of constants derive from it.
   */
  public static final int SMALLEST_UNIT_EXPONENT = 6;

  /** The number of satoshis equal to one peercoin. */
  private static final long COIN_VALUE = LongMath.pow(10, SMALLEST_UNIT_EXPONENT);

  /** Zero Peercoins. */
  public static final Coin ZERO = Coin.valueOf(0);

  /** One Peercoin. */
  public static final Coin COIN = Coin.valueOf(COIN_VALUE);

  /** 0.01 Peercoins. This unit is not really used much. */
  public static final Coin CENT = COIN.divide(100);

  /** 0.001 Peercoins, also known as 1 mPPC. */
  public static final Coin MILLICOIN = COIN.divide(1000);

  /** 0.000001 Peercoin, also known as 1 µPPC or 1 uPPC. */
  public static final Coin MICROCOIN = MILLICOIN.divide(1000);

  /**
   * A satoshi is the smallest unit that can be transferred. 1 million of them fit into a Peercoin.
   */
  public static final Coin SATOSHI = Coin.valueOf(1);

  /** Represents a monetary value of minus one satoshi. */
  public static final Coin NEGATIVE_SATOSHI = Coin.valueOf(-1);

  /** The number of satoshis of this monetary value. */
  public final long value;

  private final long MAX_SATOSHIS = COIN_VALUE * NetworkParameters.MAX_COINS;

  private Coin(final long satoshis) {
    checkArgument(
        -MAX_SATOSHIS <= satoshis && satoshis <= MAX_SATOSHIS,
        "%s satoshis exceeds maximum possible quantity of Peercoin.",
        satoshis);
    this.value = satoshis;
  }

  public static Coin valueOf(final long satoshis) {
    return new Coin(satoshis);
  }

  @Override
  public int smallestUnitExponent() {
    return SMALLEST_UNIT_EXPONENT;
  }

  /** Returns the number of satoshis of this monetary value. */
  @Override
  public long getValue() {
    return value;
  }

  /** Convert an amount expressed in the way humans are used to into satoshis. */
  public static Coin valueOf(final int coins, final int cents) {
    checkArgument(cents < 100);
    checkArgument(cents >= 0);
    checkArgument(coins >= 0);
    final Coin coin = COIN.multiply(coins).add(CENT.multiply(cents));
    checkArgument(coin.compareTo(NetworkParameters.MAX_MONEY) <= 0);
    return coin;
  }

  /**
   * Parses an amount expressed in the way humans are used to.
   *
   * <p>
   *
   * <p>This takes string in a format understood by {@link BigDecimal#BigDecimal(String)}, for
   * example "0", "1", "0.10", "1.23E3", "1234.5E-5".
   *
   * @throws IllegalArgumentException if you try to specify fractional satoshis, or a value out of
   *     range.
   */
  public static Coin parseCoin(final String str) {
    return Coin.valueOf(
        new BigDecimal(str).movePointRight(SMALLEST_UNIT_EXPONENT).toBigIntegerExact().longValue());
  }

  /** Similar to parseCoin, but allows for inexact representations to be rounded */
  public static Coin parseCoinInexact(final String str) {
    return Coin.valueOf(
        new BigDecimal(str)
            .movePointRight(SMALLEST_UNIT_EXPONENT)
            .setScale(0, BigDecimal.ROUND_HALF_UP)
            .toBigInteger()
            .longValue());
  }

  public Coin add(final Coin value) {
    return new Coin(LongMath.checkedAdd(this.value, value.value));
  }

  public Coin subtract(final Coin value) {
    return new Coin(LongMath.checkedSubtract(this.value, value.value));
  }

  public Coin multiply(final long factor) {
    return new Coin(LongMath.checkedMultiply(this.value, factor));
  }

  public Coin divide(final long divisor) {
    return new Coin(this.value / divisor);
  }

  public Coin[] divideAndRemainder(final long divisor) {
    return new Coin[] {new Coin(this.value / divisor), new Coin(this.value % divisor)};
  }

  public long divide(final Coin divisor) {
    return this.value / divisor.value;
  }

  /**
   * Returns true if and only if this instance represents a monetary value greater than zero,
   * otherwise false.
   */
  public boolean isPositive() {
    return signum() == 1;
  }

  /**
   * Returns true if and only if this instance represents a monetary value less than zero, otherwise
   * false.
   */
  public boolean isNegative() {
    return signum() == -1;
  }

  /** Returns true if and only if this instance represents zero monetary value, otherwise false. */
  public boolean isZero() {
    return signum() == 0;
  }

  /**
   * Returns true if the monetary value represented by this instance is greater than that of the
   * given other Coin, otherwise false.
   */
  public boolean isGreaterThan(Coin other) {
    return compareTo(other) > 0;
  }

  /**
   * Returns true if the monetary value represented by this instance is less than that of the given
   * other Coin, otherwise false.
   */
  public boolean isLessThan(Coin other) {
    return compareTo(other) < 0;
  }

  public Coin shiftLeft(final int n) {
    return new Coin(this.value << n);
  }

  public Coin shiftRight(final int n) {
    return new Coin(this.value >> n);
  }

  @Override
  public int signum() {
    if (this.value == 0) return 0;
    return this.value < 0 ? -1 : 1;
  }

  public Coin negate() {
    return new Coin(-this.value);
  }

  /**
   * Returns the number of satoshis of this monetary value. It's deprecated in favour of accessing
   * {@link #value} directly.
   */
  public long longValue() {
    return this.value;
  }

  private static final MonetaryFormat FRIENDLY_FORMAT =
      MonetaryFormat.PPC.minDecimals(2).repeatOptionalDecimals(1, 4).postfixCode();

  /**
   * Returns the value as a 0.12 type string. More digits after the decimal place will be used if
   * necessary, but two will always be present.
   */
  public String toFriendlyString() {
    return FRIENDLY_FORMAT.format(this).toString();
  }

  private static final MonetaryFormat PLAIN_FORMAT =
      MonetaryFormat.PPC.minDecimals(0).repeatOptionalDecimals(1, 6).noCode();

  /**
   * Returns the value as a plain string denominated in PPC. The result is unformatted with no
   * trailing zeroes. For instance, a value of 150000 satoshis gives an output string of "0.0015"
   * PPC
   */
  public String toPlainString() {
    return PLAIN_FORMAT.format(this).toString();
  }

  @Override
  public String toString() {
    return Long.toString(value);
  }

  @Override
  public boolean equals(final Object o) {
    if (o == this) return true;
    if (o == null || o.getClass() != getClass()) return false;
    final Coin other = (Coin) o;
    if (this.value != other.value) return false;
    return true;
  }

  @Override
  public int hashCode() {
    return (int) this.value;
  }

  @Override
  public int compareTo(final Coin other) {
    if (this.value == other.value) return 0;
    return this.value > other.value ? 1 : -1;
  }
}
Exemplo n.º 5
0
 /**
  * Parses an amount expressed in the way humans are used to.
  *
  * <p>
  *
  * <p>This takes string in a format understood by {@link BigDecimal#BigDecimal(String)}, for
  * example "0", "1", "0.10", "1.23E3", "1234.5E-5".
  *
  * @throws IllegalArgumentException if you try to specify fractional satoshis, or a value out of
  *     range.
  */
 public static Coin parseCoin(final String str) {
   return Coin.valueOf(
       new BigDecimal(str).movePointRight(SMALLEST_UNIT_EXPONENT).toBigIntegerExact().longValue());
 }