package java.lang; import ej.annotation.Nullable; /** * The {@code Integer} class wraps a value of the primitive type {@code int} in an object. An object * of type {@code Integer} contains a single field whose type is {@code int}. * *

* In addition, this class provides several methods for converting an {@code int} to a * {@code String} and a {@code String} to an {@code int}, as well as other constants and methods * useful when dealing with an {@code int}. * */ public final class Integer extends Number implements Comparable { /** * A constant holding the maximum value an {@code int} can have, 231-1. */ public static final int MAX_VALUE = 0x7fffffff; /** * A constant holding the minimum value an {@code int} can have, -231. */ public static final int MIN_VALUE = 0x80000000; /** * The number of bits used to represent an {@code int} value in two's complement binary form. */ public static final int SIZE = 32; /** * Constructs a newly allocated {@code Integer} object that represents the specified {@code int} * value. * * @param value * the value to be represented by the {@code Integer} object. */ public Integer(int value) { throw new RuntimeException(); } /** * Constructs a newly allocated {@code Integer} object that represents the {@code int} value * indicated by the {@code String} parameter. The string is converted to an {@code int} value in * exactly the manner used by the {@code parseInt} method for radix 10. * *

* Null Analysis restriction: the parameter s is {@code @NonNull}, * to ensure that {@link NumberFormatException} is thrown only when the string * characters do not represent a valid number. This aligns with the behavior of * {@link Float#parseFloat(String)} and {@link Double#parseDouble(String)}. * * @param s * the {@code String} to be converted to an {@code Integer}. * @exception NumberFormatException * if the {@code String} does not contain a parsable integer. * @see java.lang.Integer#parseInt(java.lang.String, int) */ public Integer(String s) throws NumberFormatException { throw new RuntimeException(); } /** * Compares two {@code int} values numerically. The value returned is identical to what would be * returned by: * * 

	 * Integer.valueOf(x).compareTo(Integer.valueOf(y))
	 *
* * @param x * the first {@code int} to compare * @param y * the second {@code int} to compare * @return the value {@code 0} if {@code x == y}; a value less than {@code 0} if {@code x < y}; and * a value greater than {@code 0} if {@code x > y} */ public static int compare(int x, int y) { throw new RuntimeException(); } /** * Decodes a {@code String} into an {@code Integer}. Accepts decimal, hexadecimal, and octal numbers * given by the following grammar: * *
*
*
DecodableString: *
Signopt DecimalNumeral *
Signopt {@code 0x} HexDigits *
Signopt {@code 0X} HexDigits *
Signopt {@code #} HexDigits *
Signopt {@code 0} OctalDigits *
Sign: *
{@code -} *
{@code +} *
*
* * DecimalNumeral, HexDigits, and OctalDigits are as defined in section 3.10.1 * of The Java™ Language Specification, except that underscores are not accepted * between digits. * *

* The sequence of characters following an optional sign and/or radix specifier ("{@code 0x}", " * {@code 0X}", "{@code #}", or leading zero) is parsed as by the {@code Integer.parseInt} method * with the indicated radix (10, 16, or 8). This sequence of characters must represent a positive * value or a {@link NumberFormatException} will be thrown. The result is negated if first character * of the specified {@code String} is the minus sign. No whitespace characters are permitted in the * {@code String}. * * @param nm * the {@code String} to decode. * @return an {@code Integer} object holding the {@code int} value represented by {@code nm} * @exception NumberFormatException * if the {@code String} does not contain a parsable integer. * @see java.lang.Integer#parseInt(java.lang.String, int) */ public static Integer decode(String nm) throws NumberFormatException { throw new RuntimeException(); } /** * Determines the integer value of the system property with the specified name. * *

* The first argument is treated as the name of a system property. System properties are accessible * through the {@link java.lang.System#getProperty(java.lang.String)} method. The string value of * this property is then interpreted as an integer value and an {@code Integer} object representing * this value is returned. Details of possible numeric formats can be found with the definition of * {@code getProperty}. * *

* If there is no property with the specified name, if the specified name is empty or {@code null}, * or if the property does not have the correct numeric format, then {@code null} is returned. * *

* In other words, this method returns an {@code Integer} object equal to the value of: * *

{@code getInteger(nm, null)}
* * @param nm * property name. * @return the {@code Integer} value of the property. * @see java.lang.System#getProperty(java.lang.String) * @see java.lang.System#getProperty(java.lang.String, java.lang.String) */ @Nullable public static Integer getInteger(String nm) { throw new RuntimeException(); } /** * Determines the integer value of the system property with the specified name. * *

* The first argument is treated as the name of a system property. System properties are accessible * through the {@link java.lang.System#getProperty(java.lang.String)} method. The string value of * this property is then interpreted as an integer value and an {@code Integer} object representing * this value is returned. Details of possible numeric formats can be found with the definition of * {@code getProperty}. * *

* The second argument is the default value. An {@code Integer} object that represents the value of * the second argument is returned if there is no property of the specified name, if the property * does not have the correct numeric format, or if the specified name is empty or {@code null}. * *

* In other words, this method returns an {@code Integer} object equal to the value of: * *

{@code getInteger(nm, new Integer(val))}
* * but in practice it may be implemented in a manner such as: * *
* * 
	 * Integer result = getInteger(nm, null);
	 * return (result == null) ? new Integer(val) : result;
	 *
* *
* * to avoid the unnecessary allocation of an {@code Integer} object when the default value is not * needed. * * @param nm * property name. * @param val * default value. * @return the {@code Integer} value of the property. * @see java.lang.System#getProperty(java.lang.String) * @see java.lang.System#getProperty(java.lang.String, java.lang.String) */ public static Integer getInteger(String nm, int val) { throw new RuntimeException(); } /** * Returns the integer value of the system property with the specified name. The first argument is * treated as the name of a system property. System properties are accessible through the * {@link java.lang.System#getProperty(java.lang.String)} method. The string value of this property * is then interpreted as an integer value, as per the {@code Integer.decode} method, and an * {@code Integer} object representing this value is returned. * * * *

* The second argument is the default value. The default value is returned if there is no property * of the specified name, if the property does not have the correct numeric format, or if the * specified name is empty or {@code null}. * * @param nm * property name. * @param val * default value. * @return the {@code Integer} value of the property. * @see java.lang.System#getProperty(java.lang.String) * @see java.lang.System#getProperty(java.lang.String, java.lang.String) * @see java.lang.Integer#decode */ public static Integer getInteger(String nm, Integer val) { throw new RuntimeException(); } /** * Parses the string argument as a signed decimal integer. The characters in the string must all be * decimal digits, except that the first character may be an ASCII minus sign {@code '-'} ( * '\u002D') to indicate a negative value or an ASCII plus sign {@code '+'} ( * '\u002B') to indicate a positive value. The resulting integer value is returned, * exactly as if the argument and the radix 10 were given as arguments to the * {@link #parseInt(java.lang.String, int)} method. * *

* Null Analysis restriction: the parameter s is {@code @NonNull}, * to ensure that {@link NumberFormatException} is thrown only when the string * characters do not represent a valid number. This aligns with the behavior of * {@link Float#parseFloat(String)} and {@link Double#parseDouble(String)}. * * @param s * a {@code String} containing the {@code int} representation to be parsed * @return the integer value represented by the argument in decimal. * @exception NumberFormatException * if the string does not contain a parsable integer. */ public static int parseInt(String s) throws NumberFormatException { throw new RuntimeException(); } /** * Parses the string argument as a signed integer in the radix specified by the second argument. The * characters in the string must all be digits of the specified radix (as determined by whether * {@link java.lang.Character#digit(char, int)} returns a nonnegative value), except that the first * character may be an ASCII minus sign {@code '-'} ('\u002D') to indicate a * negative value or an ASCII plus sign {@code '+'} ('\u002B') to indicate a * positive value. The resulting integer value is returned. * *

* An exception of type {@code NumberFormatException} is thrown if any of the following situations * occurs: *

* *

* Examples:

* * 
	 * parseInt("0", 10) returns 0
	 * parseInt("473", 10) returns 473
	 * parseInt("+42", 10) returns 42
	 * parseInt("-0", 10) returns 0
	 * parseInt("-FF", 16) returns -255
	 * parseInt("1100110", 2) returns 102
	 * parseInt("2147483647", 10) returns 2147483647
	 * parseInt("-2147483648", 10) returns -2147483648
	 * parseInt("2147483648", 10) throws a NumberFormatException
	 * parseInt("99", 8) throws a NumberFormatException
	 * parseInt("Kona", 10) throws a NumberFormatException
	 * parseInt("Kona", 27) returns 411787
	 *
* *
* *

* Null Analysis restriction: the parameter s is {@code @NonNull}, * to ensure that {@link NumberFormatException} is thrown only when the string * characters do not represent a valid number. This aligns with the behavior of * {@link Float#parseFloat(String)} and {@link Double#parseDouble(String)}. * * @param s * the {@code String} containing the integer representation to be parsed * @param radix * the radix to be used while parsing {@code s}. * @return the integer represented by the string argument in the specified radix. * @exception NumberFormatException * if the {@code String} does not contain a parsable {@code int}. */ public static int parseInt(String s, int radix) throws NumberFormatException { throw new RuntimeException(); } /** * Returns the value obtained by rotating the two's complement binary representation of the * specified {@code int} value left by the specified number of bits. (Bits shifted out of the left * hand, or high-order, side reenter on the right, or low-order.) * *

* Note that left rotation with a negative distance is equivalent to right rotation: * {@code rotateLeft(val, -distance) == rotateRight(val, * distance)}. Note also that rotation by any multiple of 32 is a no-op, so all but the last five * bits of the rotation distance can be ignored, even if the distance is negative: * {@code rotateLeft(val, * distance) == rotateLeft(val, distance & 0x1F)}. * @param i the value whose bits are to be rotated left * @param distance the number of bit positions to rotate left * * @return the value obtained by rotating the two's complement binary representation of the * specified {@code int} value left by the specified number of bits. */ public static int rotateLeft(int i, int distance) { throw new RuntimeException(); } /** * Returns the value obtained by rotating the two's complement binary representation of the * specified {@code int} value right by the specified number of bits. (Bits shifted out of the right * hand, or low-order, side reenter on the left, or high-order.) * *

* Note that right rotation with a negative distance is equivalent to left rotation: * {@code rotateRight(val, -distance) == rotateLeft(val, * distance)}. Note also that rotation by any multiple of 32 is a no-op, so all but the last five * bits of the rotation distance can be ignored, even if the distance is negative: * {@code rotateRight(val, * distance) == rotateRight(val, distance & 0x1F)}. * @param i the value whose bits are to be rotated right * @param distance the number of bit positions to rotate right * * @return the value obtained by rotating the two's complement binary representation of the * specified {@code int} value right by the specified number of bits. */ public static int rotateRight(int i, int distance) { throw new RuntimeException(); } /** * Returns the signum function of the specified {@code int} value. (The return value is -1 if the * specified value is negative; 0 if the specified value is zero; and 1 if the specified value is * positive.) * @param i the value whose signum is to be computed * * @return the signum function of the specified {@code int} value. */ public static int signum(int i) { throw new RuntimeException(); } /** * Returns a string representation of the integer argument as an unsigned integer in base 2. * *

* The unsigned integer value is the argument plus 232 if the argument is negative; * otherwise it is equal to the argument. This value is converted to a string of ASCII digits in * binary (base 2) with no extra leading {@code 0}s. If the unsigned magnitude is zero, it is * represented by a single zero character {@code '0'} ('\u0030'); otherwise, the * first character of the representation of the unsigned magnitude will not be the zero character. * The characters {@code '0'} ('\u0030') and {@code '1'} ( * '\u0031') are used as binary digits. * * @param i * an integer to be converted to a string. * @return the string representation of the unsigned integer value represented by the argument in * binary (base 2). */ public static String toBinaryString(int i) { throw new RuntimeException(); } /** * Returns a string representation of the integer argument as an unsigned integer in base 16. * *

* The unsigned integer value is the argument plus 232 if the argument is negative; * otherwise, it is equal to the argument. This value is converted to a string of ASCII digits in * hexadecimal (base 16) with no extra leading {@code 0}s. If the unsigned magnitude is zero, * it is represented by a single zero character {@code '0'} ('\u0030'); otherwise, * the first character of the representation of the unsigned magnitude will not be the zero * character. The following characters are used as hexadecimal digits: * *

{@code 0123456789abcdef}
* * These are the characters '\u0030' through '\u0039' and * '\u0061' through '\u0066'. If uppercase letters are desired, * the {@link java.lang.String#toUpperCase()} method may be called on the result: * *
{@code Integer.toHexString(n).toUpperCase()}
* * @param i * an integer to be converted to a string. * @return the string representation of the unsigned integer value represented by the argument in * hexadecimal (base 16). */ public static String toHexString(int i) { throw new RuntimeException(); } /** * Returns a string representation of the integer argument as an unsigned integer in base 8. * *

* The unsigned integer value is the argument plus 232 if the argument is negative; * otherwise, it is equal to the argument. This value is converted to a string of ASCII digits in * octal (base 8) with no extra leading {@code 0}s. * *

* If the unsigned magnitude is zero, it is represented by a single zero character {@code '0'} ( * '\u0030'); otherwise, the first character of the representation of the unsigned * magnitude will not be the zero character. The following characters are used as octal digits: * *

{@code 01234567}
* * These are the characters '\u0030' through '\u0037'. * * @param i * an integer to be converted to a string. * @return the string representation of the unsigned integer value represented by the argument in * octal (base 8). */ public static String toOctalString(int i) { throw new RuntimeException(); } /** * Returns a {@code String} object representing the specified integer. The argument is converted to * signed decimal representation and returned as a string, exactly as if the argument and radix 10 * were given as arguments to the {@link #toString(int, int)} method. * * @param i * an integer to be converted. * @return a string representation of the argument in base 10. */ public static String toString(int i) { throw new RuntimeException(); } /** * Returns a string representation of the first argument in the radix specified by the second * argument. * *

* If the radix is smaller than {@code Character.MIN_RADIX} or larger than * {@code Character.MAX_RADIX}, then the radix {@code 10} is used instead. * *

* If the first argument is negative, the first element of the result is the ASCII minus character * {@code '-'} ('\u002D'). If the first argument is not negative, no sign character * appears in the result. * *

* The remaining characters of the result represent the magnitude of the first argument. If the * magnitude is zero, it is represented by a single zero character {@code '0'} ( * '\u0030'); otherwise, the first character of the representation of the magnitude * will not be the zero character. The following ASCII characters are used as digits: * *

{@code 0123456789abcdefghijklmnopqrstuvwxyz}
* * These are '\u0030' through '\u0039' and * '\u0061' through '\u007A'. If {@code radix} is N, * then the first N of these characters are used as radix-N digits in the * order shown. Thus, the digits for hexadecimal (radix 16) are {@code 0123456789abcdef}. If * uppercase letters are desired, the {@link java.lang.String#toUpperCase()} method may be called on * the result: * *
{@code Integer.toString(n, 16).toUpperCase()}
* * @param i * an integer to be converted to a string. * @param radix * the radix to use in the string representation. * @return a string representation of the argument in the specified radix. * @see java.lang.Character#MAX_RADIX * @see java.lang.Character#MIN_RADIX */ public static String toString(int i, int radix) { throw new RuntimeException(); } /** * Returns an {@code Integer} instance representing the specified {@code int} value. If a new * {@code Integer} instance is not required, this method should generally be used in preference to * the constructor {@link #Integer(int)}, as this method is likely to yield significantly better * space and time performance by caching frequently requested values. * * This method will always cache values in the range -128 to 127, inclusive, and may cache other * values outside of this range. * * @param i * an {@code int} value. * @return an {@code Integer} instance representing {@code i}. */ public static Integer valueOf(int i) { throw new RuntimeException(); } /** * Returns an {@code Integer} object holding the value of the specified {@code String}. The argument * is interpreted as representing a signed decimal integer, exactly as if the argument were given to * the {@link #parseInt(java.lang.String)} method. The result is an {@code Integer} object that * represents the integer value specified by the string. * *

* In other words, this method returns an {@code Integer} object equal to the value of: * *

{@code new Integer(Integer.parseInt(s))}
* *

* Null Analysis restriction: the parameter s is {@code @NonNull}, * to ensure that {@link NumberFormatException} is thrown only when the string * characters do not represent a valid number. This aligns with the behavior of * {@link Float#parseFloat(String)} and {@link Double#parseDouble(String)}. * * @param s * the string to be parsed. * @return an {@code Integer} object holding the value represented by the string argument. * @exception NumberFormatException * if the string cannot be parsed as an integer. */ public static Integer valueOf(String s) throws NumberFormatException { throw new RuntimeException(); } /** * Returns an {@code Integer} object holding the value extracted from the specified {@code String} * when parsed with the radix given by the second argument. The first argument is interpreted as * representing a signed integer in the radix specified by the second argument, exactly as if the * arguments were given to the {@link #parseInt(java.lang.String, int)} method. The result is an * {@code Integer} object that represents the integer value specified by the string. * *

* In other words, this method returns an {@code Integer} object equal to the value of: * *

{@code new Integer(Integer.parseInt(s, radix))}
* *

* Null Analysis restriction: the parameter s is {@code @NonNull}, * to ensure that {@link NumberFormatException} is thrown only when the string * characters do not represent a valid number. This aligns with the behavior of * {@link Float#parseFloat(String)} and {@link Double#parseDouble(String)}. * * @param s * the string to be parsed. * @param radix * the radix to be used in interpreting {@code s} * @return an {@code Integer} object holding the value represented by the string argument in the * specified radix. * @exception NumberFormatException * if the {@code String} does not contain a parsable {@code int}. */ public static Integer valueOf(String s, int radix) throws NumberFormatException { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as a {@code byte}. */ @Override public byte byteValue() { throw new RuntimeException(); } /** * Compares two {@code Integer} objects numerically. * * @param anotherInteger * the {@code Integer} to be compared. * @return the value {@code 0} if this {@code Integer} is equal to the argument {@code Integer}; a * value less than {@code 0} if this {@code Integer} is numerically less than the argument * {@code Integer}; and a value greater than {@code 0} if this {@code Integer} is * numerically greater than the argument {@code Integer} (signed comparison). */ @Override public int compareTo(Integer anotherInteger) { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as a {@code double}. */ @Override public double doubleValue() { throw new RuntimeException(); } /** * Compares this object to the specified object. The result is {@code true} if and only if the * argument is not {@code null} and is an {@code Integer} object that contains the same {@code int} * value as this object. * * @param obj * the object to compare with. * @return {@code true} if the objects are the same; {@code false} otherwise. */ @Override public boolean equals(@Nullable Object obj) { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as a {@code float}. */ @Override public float floatValue() { throw new RuntimeException(); } /** * Returns a hash code for this {@code Integer}. * * @return a hash code value for this object, equal to the primitive {@code int} value represented * by this {@code Integer} object. */ @Override public int hashCode() { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as an {@code int}. */ @Override public int intValue() { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as a {@code long}. */ @Override public long longValue() { throw new RuntimeException(); } /** * Returns the value of this {@code Integer} as a {@code short}. */ @Override public short shortValue() { throw new RuntimeException(); } /** * Returns a {@code String} object representing this {@code Integer}'s value. The value is converted * to signed decimal representation and returned as a string, exactly as if the integer value were * given as an argument to the {@link java.lang.Integer#toString(int)} method. * * @return a string representation of the value of this object in base 10. */ @Override public String toString() { throw new RuntimeException(); } }