BigInteger

The BigInteger constant 1.

The BigInteger constant 10.

The BigInteger constant 0.

Constructs a random non-negative BigInteger instance in the range [0, pow(2, numBits)-1].

Constructs a random BigInteger instance in the range [0, pow(2, bitLength)-1] which is probably prime. The probability that the returned BigInteger is prime is beyond 1 - 1/pow(2, certainty).

Implementation Note: the Random argument is ignored. This implementation uses OpenSSL's bn_rand as a source of cryptographically strong pseudo-random numbers.

Constructs a new BigInteger by parsing value. The string representation consists of an optional plus or minus sign followed by a non-empty sequence of decimal digits. Digits are interpreted as if by Character.digit(char,10).

Constructs a new BigInteger instance by parsing value. The string representation consists of an optional plus or minus sign followed by a non-empty sequence of digits in the specified radix. Digits are interpreted as if by Character.digit(char, radix).

Constructs a new BigInteger instance with the given sign and magnitude.

Constructs a new BigInteger from the given two's complement representation. The most significant byte is the entry at index 0. The most significant bit of this entry determines the sign of the new BigInteger instance. The array must be nonempty.

Returns a BigInteger whose value is the absolute value of this.

Returns a BigInteger whose value is this + value.

Returns a BigInteger whose value is this & value.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns a BigInteger whose value is this & ~value. Evaluating x.andNot(value) returns the same result as x.and(value.not()).

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns the number of bits in the two's complement representation of this which differ from the sign bit. If this is negative, the result is equivalent to the number of bits set in the two's complement representation of -this - 1.

Use bitLength(0) to find the length of the binary value in bits.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns the length of the value's two's complement representation without leading zeros for positive numbers / without leading ones for negative values.

The two's complement representation of this will be at least bitLength() + 1 bits long.

The value will fit into an int if bitLength() < 32 or into a long if bitLength() < 64.

Returns a BigInteger which has the same binary representation as this but with the bit at position n cleared. The result is equivalent to this & ~pow(2, n).

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Compares this BigInteger with value. Returns -1 if this < value, 0 if this == value and 1 if this > value, .

Returns a BigInteger whose value is this / divisor.

Returns a two element BigInteger array containing this / divisor at index 0 and this % divisor at index 1.

Returns this BigInteger as a double. If this is too big to be represented as a double, then Double.POSITIVE_INFINITY or Double.NEGATIVE_INFINITY is returned. Note that not all integers in the range [-Double.MAX_VALUE, Double.MAX_VALUE] can be exactly represented as a double.

Compares this instance with the specified object and indicates if they are equal. In order to be equal, o must represent the same object as this instance using a class-specific comparison. The general contract is that this comparison should be reflexive, symmetric, and transitive. Also, no object reference other than null is equal to null.

The default implementation returns true only if this == o. See Writing a correct equals method if you intend implementing your own equals method.

The general contract for the equals and hashCode() methods is that if equals returns true for any two objects, then hashCode() must return the same value for these objects. This means that subclasses of Object usually override either both methods or neither of them.

Returns a BigInteger which has the same binary representation as this but with the bit at position n flipped. The result is equivalent to this ^ pow(2, n).

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns this BigInteger as a float. If this is too big to be represented as a float, then Float.POSITIVE_INFINITY or Float.NEGATIVE_INFINITY is returned. Note that not all integers in the range [-Float.MAX_VALUE, Float.MAX_VALUE] can be exactly represented as a float.

Returns a BigInteger whose value is greatest common divisor of this and value. If this == 0 and value == 0 then zero is returned, otherwise the result is positive.

Returns the position of the lowest set bit in the two's complement representation of this BigInteger. If all bits are zero (this==0) then -1 is returned as result.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns an integer hash code for this object. By contract, any two objects for which equals(Object) returns true must return the same hash code value. This means that subclasses of Object usually override both methods or neither method.

Note that hash values must not change over time unless information used in equals comparisons also changes.

See Writing a correct hashCode method if you intend implementing your own hashCode method.

Returns this BigInteger as an int value. If this is too big to be represented as an int, then this % (1 << 32) is returned.

Tests whether this BigInteger is probably prime. If true is returned, then this is prime with a probability beyond 1 - 1/pow(2, certainty). If false is returned, then this is definitely composite. If the argument certainty <= 0, then this method returns true.

Returns this BigInteger as a long value. If this is too big to be represented as a long, then this % pow(2, 64) is returned.

Returns the maximum of this BigInteger and value.

Returns the minimum of this BigInteger and value.

Returns a BigInteger whose value is this mod m. The modulus m must be positive. The result is guaranteed to be in the interval [0, m) (0 inclusive, m exclusive). The behavior of this function is not equivalent to the behavior of the % operator defined for the built-in int's.

Returns a BigInteger whose value is 1/this mod m. The modulus m must be positive. The result is guaranteed to be in the interval [0, m) (0 inclusive, m exclusive). If this is not relatively prime to m, then an exception is thrown.

Returns a BigInteger whose value is pow(this, exponent) mod m. The modulus m must be positive. The result is guaranteed to be in the interval [0, m) (0 inclusive, m exclusive). If the exponent is negative, then pow(this.modInverse(m), -exponent) mod m is computed. The inverse of this only exists if this is relatively prime to m, otherwise an exception is thrown.

Returns a BigInteger whose value is this * value.

Returns a BigInteger whose value is the -this.

Returns the smallest integer x > this which is probably prime as a BigInteger instance. The probability that the returned BigInteger is prime is beyond 1 - 1/pow(2, 80).

Returns a BigInteger whose value is ~this. The result of this operation is -this-1.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns a BigInteger whose value is this | value.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns a BigInteger whose value is pow(this, exp).

Returns a random positive BigInteger instance in the range [0, pow(2, bitLength)-1] which is probably prime. The probability that the returned BigInteger is prime is beyond 1 - 1/pow(2, 80).

Implementation Note: Currently random is ignored.

Returns a BigInteger whose value is this % divisor. Regarding signs this methods has the same behavior as the % operator on ints: the sign of the remainder is the same as the sign of this.

Returns a BigInteger which has the same binary representation as this but with the bit at position n set. The result is equivalent to this | pow(2, n).

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns a BigInteger whose value is this << n. The result is equivalent to this * pow(2, n) if n >= 0. The shift distance may be negative which means that this is shifted right. The result then corresponds to floor(this / pow(2, -n)).

Implementation Note: Usage of this method on negative values is not recommended as the current implementation is not efficient.

Returns a BigInteger whose value is this >> n. For negative arguments, the result is also negative. The shift distance may be negative which means that this is shifted left.

Implementation Note: Usage of this method on negative values is not recommended as the current implementation is not efficient.

Returns the sign of this BigInteger.

Returns a BigInteger whose value is this - value.

Tests whether the bit at position n in this is set. The result is equivalent to this & pow(2, n) != 0.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.

Returns the two's complement representation of this BigInteger in a byte array.

Returns a string representation of this BigInteger in decimal form.

Returns a string containing a string representation of this BigInteger with base radix. If radix < Character.MIN_RADIX or radix > Character.MAX_RADIX then a decimal representation is returned. The characters of the string representation are generated with method Character.forDigit.

Returns a BigInteger whose value is equal to value.

Returns a BigInteger whose value is this ^ value.

Implementation Note: Usage of this method is not recommended as the current implementation is not efficient.