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JDK 17 java.base.jmod - Base Module
JDK 17 java.base.jmod is the JMOD file for JDK 17 Base module.
JDK 17 Base module compiled class files are stored in \fyicenter\jdk-17.0.5\jmods\java.base.jmod.
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JDK 17 Base module source code files are stored in \fyicenter\jdk-17.0.5\lib\src.zip\java.base.
You can click and view the content of each source code file in the list below.
✍: FYIcenter
⏎ java/lang/Float.java
/* * Copyright (c) 1994, 2021, Oracle and/or its affiliates. All rights reserved. * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms. * * * * * * * * * * * * * * * * * * * * */ package java.lang; import java.lang.invoke.MethodHandles; import java.lang.constant.Constable; import java.lang.constant.ConstantDesc; import java.util.Optional; import jdk.internal.math.FloatingDecimal; import jdk.internal.vm.annotation.IntrinsicCandidate; /** * The {@code Float} class wraps a value of primitive type * {@code float} in an object. An object of type * {@code Float} contains a single field whose type is * {@code float}. * * <p>In addition, this class provides several methods for converting a * {@code float} to a {@code String} and a * {@code String} to a {@code float}, as well as other * constants and methods useful when dealing with a * {@code float}. * * <p>This is a <a href="{@docRoot}/java.base/java/lang/doc-files/ValueBased.html">value-based</a> * class; programmers should treat instances that are * {@linkplain #equals(Object) equal} as interchangeable and should not * use instances for synchronization, or unpredictable behavior may * occur. For example, in a future release, synchronization may fail. * * <h2><a id=equivalenceRelation>Floating-point Equality, Equivalence, * and Comparison</a></h2> * * The class {@code java.lang.Double} has a <a * href="Double.html#equivalenceRelation">discussion of equality, * equivalence, and comparison of floating-point values</a> that is * equality applicable to {@code float} values. * * @author Lee Boynton * @author Arthur van Hoff * @author Joseph D. Darcy * @since 1.0 */ @jdk.internal.ValueBased public final class Float extends Number implements Comparable<Float>, Constable, ConstantDesc { /** * A constant holding the positive infinity of type * {@code float}. It is equal to the value returned by * {@code Float.intBitsToFloat(0x7f800000)}. */ public static final float POSITIVE_INFINITY = 1.0f / 0.0f; /** * A constant holding the negative infinity of type * {@code float}. It is equal to the value returned by * {@code Float.intBitsToFloat(0xff800000)}. */ public static final float NEGATIVE_INFINITY = -1.0f / 0.0f; /** * A constant holding a Not-a-Number (NaN) value of type * {@code float}. It is equivalent to the value returned by * {@code Float.intBitsToFloat(0x7fc00000)}. */ public static final float NaN = 0.0f / 0.0f; /** * A constant holding the largest positive finite value of type * {@code float}, (2-2<sup>-23</sup>)·2<sup>127</sup>. * It is equal to the hexadecimal floating-point literal * {@code 0x1.fffffeP+127f} and also equal to * {@code Float.intBitsToFloat(0x7f7fffff)}. */ public static final float MAX_VALUE = 0x1.fffffeP+127f; // 3.4028235e+38f /** * A constant holding the smallest positive normal value of type * {@code float}, 2<sup>-126</sup>. It is equal to the * hexadecimal floating-point literal {@code 0x1.0p-126f} and also * equal to {@code Float.intBitsToFloat(0x00800000)}. * * @since 1.6 */ public static final float MIN_NORMAL = 0x1.0p-126f; // 1.17549435E-38f /** * A constant holding the smallest positive nonzero value of type * {@code float}, 2<sup>-149</sup>. It is equal to the * hexadecimal floating-point literal {@code 0x0.000002P-126f} * and also equal to {@code Float.intBitsToFloat(0x1)}. */ public static final float MIN_VALUE = 0x0.000002P-126f; // 1.4e-45f /** * Maximum exponent a finite {@code float} variable may have. It * is equal to the value returned by {@code * Math.getExponent(Float.MAX_VALUE)}. * * @since 1.6 */ public static final int MAX_EXPONENT = 127; /** * Minimum exponent a normalized {@code float} variable may have. * It is equal to the value returned by {@code * Math.getExponent(Float.MIN_NORMAL)}. * * @since 1.6 */ public static final int MIN_EXPONENT = -126; /** * The number of bits used to represent a {@code float} value. * * @since 1.5 */ public static final int SIZE = 32; /** * The number of bytes used to represent a {@code float} value. * * @since 1.8 */ public static final int BYTES = SIZE / Byte.SIZE; /** * The {@code Class} instance representing the primitive type * {@code float}. * * @since 1.1 */ @SuppressWarnings("unchecked") public static final Class<Float> TYPE = (Class<Float>) Class.getPrimitiveClass("float"); /** * Returns a string representation of the {@code float} * argument. All characters mentioned below are ASCII characters. * <ul> * <li>If the argument is NaN, the result is the string * "{@code NaN}". * <li>Otherwise, the result is a string that represents the sign and * magnitude (absolute value) of the argument. If the sign is * negative, the first character of the result is * '{@code -}' ({@code '\u005Cu002D'}); if the sign is * positive, no sign character appears in the result. As for * the magnitude <i>m</i>: * <ul> * <li>If <i>m</i> is infinity, it is represented by the characters * {@code "Infinity"}; thus, positive infinity produces * the result {@code "Infinity"} and negative infinity * produces the result {@code "-Infinity"}. * <li>If <i>m</i> is zero, it is represented by the characters * {@code "0.0"}; thus, negative zero produces the result * {@code "-0.0"} and positive zero produces the result * {@code "0.0"}. * <li> If <i>m</i> is greater than or equal to 10<sup>-3</sup> but * less than 10<sup>7</sup>, then it is represented as the * integer part of <i>m</i>, in decimal form with no leading * zeroes, followed by '{@code .}' * ({@code '\u005Cu002E'}), followed by one or more * decimal digits representing the fractional part of * <i>m</i>. * <li> If <i>m</i> is less than 10<sup>-3</sup> or greater than or * equal to 10<sup>7</sup>, then it is represented in * so-called "computerized scientific notation." Let <i>n</i> * be the unique integer such that 10<sup><i>n</i> </sup>≤ * <i>m</i> {@literal <} 10<sup><i>n</i>+1</sup>; then let <i>a</i> * be the mathematically exact quotient of <i>m</i> and * 10<sup><i>n</i></sup> so that 1 ≤ <i>a</i> {@literal <} 10. * The magnitude is then represented as the integer part of * <i>a</i>, as a single decimal digit, followed by * '{@code .}' ({@code '\u005Cu002E'}), followed by * decimal digits representing the fractional part of * <i>a</i>, followed by the letter '{@code E}' * ({@code '\u005Cu0045'}), followed by a representation * of <i>n</i> as a decimal integer, as produced by the * method {@link java.lang.Integer#toString(int)}. * * </ul> * </ul> * How many digits must be printed for the fractional part of * <i>m</i> or <i>a</i>? There must be at least one digit * to represent the fractional part, and beyond that as many, but * only as many, more digits as are needed to uniquely distinguish * the argument value from adjacent values of type * {@code float}. That is, suppose that <i>x</i> is the * exact mathematical value represented by the decimal * representation produced by this method for a finite nonzero * argument <i>f</i>. Then <i>f</i> must be the {@code float} * value nearest to <i>x</i>; or, if two {@code float} values are * equally close to <i>x</i>, then <i>f</i> must be one of * them and the least significant bit of the significand of * <i>f</i> must be {@code 0}. * * <p>To create localized string representations of a floating-point * value, use subclasses of {@link java.text.NumberFormat}. * * @param f the float to be converted. * @return a string representation of the argument. */ public static String toString(float f) { return FloatingDecimal.toJavaFormatString(f); } /** * Returns a hexadecimal string representation of the * {@code float} argument. All characters mentioned below are * ASCII characters. * * <ul> * <li>If the argument is NaN, the result is the string * "{@code NaN}". * <li>Otherwise, the result is a string that represents the sign and * magnitude (absolute value) of the argument. If the sign is negative, * the first character of the result is '{@code -}' * ({@code '\u005Cu002D'}); if the sign is positive, no sign character * appears in the result. As for the magnitude <i>m</i>: * * <ul> * <li>If <i>m</i> is infinity, it is represented by the string * {@code "Infinity"}; thus, positive infinity produces the * result {@code "Infinity"} and negative infinity produces * the result {@code "-Infinity"}. * * <li>If <i>m</i> is zero, it is represented by the string * {@code "0x0.0p0"}; thus, negative zero produces the result * {@code "-0x0.0p0"} and positive zero produces the result * {@code "0x0.0p0"}. * * <li>If <i>m</i> is a {@code float} value with a * normalized representation, substrings are used to represent the * significand and exponent fields. The significand is * represented by the characters {@code "0x1."} * followed by a lowercase hexadecimal representation of the rest * of the significand as a fraction. Trailing zeros in the * hexadecimal representation are removed unless all the digits * are zero, in which case a single zero is used. Next, the * exponent is represented by {@code "p"} followed * by a decimal string of the unbiased exponent as if produced by * a call to {@link Integer#toString(int) Integer.toString} on the * exponent value. * * <li>If <i>m</i> is a {@code float} value with a subnormal * representation, the significand is represented by the * characters {@code "0x0."} followed by a * hexadecimal representation of the rest of the significand as a * fraction. Trailing zeros in the hexadecimal representation are * removed. Next, the exponent is represented by * {@code "p-126"}. Note that there must be at * least one nonzero digit in a subnormal significand. * * </ul> * * </ul> * * <table class="striped"> * <caption>Examples</caption> * <thead> * <tr><th scope="col">Floating-point Value</th><th scope="col">Hexadecimal String</th> * </thead> * <tbody> * <tr><th scope="row">{@code 1.0}</th> <td>{@code 0x1.0p0}</td> * <tr><th scope="row">{@code -1.0}</th> <td>{@code -0x1.0p0}</td> * <tr><th scope="row">{@code 2.0}</th> <td>{@code 0x1.0p1}</td> * <tr><th scope="row">{@code 3.0}</th> <td>{@code 0x1.8p1}</td> * <tr><th scope="row">{@code 0.5}</th> <td>{@code 0x1.0p-1}</td> * <tr><th scope="row">{@code 0.25}</th> <td>{@code 0x1.0p-2}</td> * <tr><th scope="row">{@code Float.MAX_VALUE}</th> * <td>{@code 0x1.fffffep127}</td> * <tr><th scope="row">{@code Minimum Normal Value}</th> * <td>{@code 0x1.0p-126}</td> * <tr><th scope="row">{@code Maximum Subnormal Value}</th> * <td>{@code 0x0.fffffep-126}</td> * <tr><th scope="row">{@code Float.MIN_VALUE}</th> * <td>{@code 0x0.000002p-126}</td> * </tbody> * </table> * @param f the {@code float} to be converted. * @return a hex string representation of the argument. * @since 1.5 * @author Joseph D. Darcy */ public static String toHexString(float f) { if (Math.abs(f) < Float.MIN_NORMAL && f != 0.0f ) {// float subnormal // Adjust exponent to create subnormal double, then // replace subnormal double exponent with subnormal float // exponent String s = Double.toHexString(Math.scalb((double)f, /* -1022+126 */ Double.MIN_EXPONENT- Float.MIN_EXPONENT)); return s.replaceFirst("p-1022$", "p-126"); } else // double string will be the same as float string return Double.toHexString(f); } /** * Returns a {@code Float} object holding the * {@code float} value represented by the argument string * {@code s}. * * <p>If {@code s} is {@code null}, then a * {@code NullPointerException} is thrown. * * <p>Leading and trailing whitespace characters in {@code s} * are ignored. Whitespace is removed as if by the {@link * String#trim} method; that is, both ASCII space and control * characters are removed. The rest of {@code s} should * constitute a <i>FloatValue</i> as described by the lexical * syntax rules: * * <blockquote> * <dl> * <dt><i>FloatValue:</i> * <dd><i>Sign<sub>opt</sub></i> {@code NaN} * <dd><i>Sign<sub>opt</sub></i> {@code Infinity} * <dd><i>Sign<sub>opt</sub> FloatingPointLiteral</i> * <dd><i>Sign<sub>opt</sub> HexFloatingPointLiteral</i> * <dd><i>SignedInteger</i> * </dl> * * <dl> * <dt><i>HexFloatingPointLiteral</i>: * <dd> <i>HexSignificand BinaryExponent FloatTypeSuffix<sub>opt</sub></i> * </dl> * * <dl> * <dt><i>HexSignificand:</i> * <dd><i>HexNumeral</i> * <dd><i>HexNumeral</i> {@code .} * <dd>{@code 0x} <i>HexDigits<sub>opt</sub> * </i>{@code .}<i> HexDigits</i> * <dd>{@code 0X}<i> HexDigits<sub>opt</sub> * </i>{@code .} <i>HexDigits</i> * </dl> * * <dl> * <dt><i>BinaryExponent:</i> * <dd><i>BinaryExponentIndicator SignedInteger</i> * </dl> * * <dl> * <dt><i>BinaryExponentIndicator:</i> * <dd>{@code p} * <dd>{@code P} * </dl> * * </blockquote> * * where <i>Sign</i>, <i>FloatingPointLiteral</i>, * <i>HexNumeral</i>, <i>HexDigits</i>, <i>SignedInteger</i> and * <i>FloatTypeSuffix</i> are as defined in the lexical structure * sections of * <cite>The Java Language Specification</cite>, * except that underscores are not accepted between digits. * If {@code s} does not have the form of * a <i>FloatValue</i>, then a {@code NumberFormatException} * is thrown. Otherwise, {@code s} is regarded as * representing an exact decimal value in the usual * "computerized scientific notation" or as an exact * hexadecimal value; this exact numerical value is then * conceptually converted to an "infinitely precise" * binary value that is then rounded to type {@code float} * by the usual round-to-nearest rule of IEEE 754 floating-point * arithmetic, which includes preserving the sign of a zero * value. * * Note that the round-to-nearest rule also implies overflow and * underflow behaviour; if the exact value of {@code s} is large * enough in magnitude (greater than or equal to ({@link * #MAX_VALUE} + {@link Math#ulp(float) ulp(MAX_VALUE)}/2), * rounding to {@code float} will result in an infinity and if the * exact value of {@code s} is small enough in magnitude (less * than or equal to {@link #MIN_VALUE}/2), rounding to float will * result in a zero. * * Finally, after rounding a {@code Float} object representing * this {@code float} value is returned. * * <p>To interpret localized string representations of a * floating-point value, use subclasses of {@link * java.text.NumberFormat}. * * <p>Note that trailing format specifiers, specifiers that * determine the type of a floating-point literal * ({@code 1.0f} is a {@code float} value; * {@code 1.0d} is a {@code double} value), do * <em>not</em> influence the results of this method. In other * words, the numerical value of the input string is converted * directly to the target floating-point type. In general, the * two-step sequence of conversions, string to {@code double} * followed by {@code double} to {@code float}, is * <em>not</em> equivalent to converting a string directly to * {@code float}. For example, if first converted to an * intermediate {@code double} and then to * {@code float}, the string<br> * {@code "1.00000017881393421514957253748434595763683319091796875001d"}<br> * results in the {@code float} value * {@code 1.0000002f}; if the string is converted directly to * {@code float}, <code>1.000000<b>1</b>f</code> results. * * <p>To avoid calling this method on an invalid string and having * a {@code NumberFormatException} be thrown, the documentation * for {@link Double#valueOf Double.valueOf} lists a regular * expression which can be used to screen the input. * * @param s the string to be parsed. * @return a {@code Float} object holding the value * represented by the {@code String} argument. * @throws NumberFormatException if the string does not contain a * parsable number. */ public static Float valueOf(String s) throws NumberFormatException { return new Float(parseFloat(s)); } /** * Returns a {@code Float} instance representing the specified * {@code float} value. * If a new {@code Float} instance is not required, this method * should generally be used in preference to the constructor * {@link #Float(float)}, as this method is likely to yield * significantly better space and time performance by caching * frequently requested values. * * @param f a float value. * @return a {@code Float} instance representing {@code f}. * @since 1.5 */ @IntrinsicCandidate public static Float valueOf(float f) { return new Float(f); } /** * Returns a new {@code float} initialized to the value * represented by the specified {@code String}, as performed * by the {@code valueOf} method of class {@code Float}. * * @param s the string to be parsed. * @return the {@code float} value represented by the string * argument. * @throws NullPointerException if the string is null * @throws NumberFormatException if the string does not contain a * parsable {@code float}. * @see java.lang.Float#valueOf(String) * @since 1.2 */ public static float parseFloat(String s) throws NumberFormatException { return FloatingDecimal.parseFloat(s); } /** * Returns {@code true} if the specified number is a * Not-a-Number (NaN) value, {@code false} otherwise. * * @param v the value to be tested. * @return {@code true} if the argument is NaN; * {@code false} otherwise. */ public static boolean isNaN(float v) { return (v != v); } /** * Returns {@code true} if the specified number is infinitely * large in magnitude, {@code false} otherwise. * * @param v the value to be tested. * @return {@code true} if the argument is positive infinity or * negative infinity; {@code false} otherwise. */ public static boolean isInfinite(float v) { return (v == POSITIVE_INFINITY) || (v == NEGATIVE_INFINITY); } /** * Returns {@code true} if the argument is a finite floating-point * value; returns {@code false} otherwise (for NaN and infinity * arguments). * * @param f the {@code float} value to be tested * @return {@code true} if the argument is a finite * floating-point value, {@code false} otherwise. * @since 1.8 */ public static boolean isFinite(float f) { return Math.abs(f) <= Float.MAX_VALUE; } /** * The value of the Float. * * @serial */ private final float value; /** * Constructs a newly allocated {@code Float} object that * represents the primitive {@code float} argument. * * @param value the value to be represented by the {@code Float}. * * @deprecated * It is rarely appropriate to use this constructor. The static factory * {@link #valueOf(float)} is generally a better choice, as it is * likely to yield significantly better space and time performance. */ @Deprecated(since="9", forRemoval = true) public Float(float value) { this.value = value; } /** * Constructs a newly allocated {@code Float} object that * represents the argument converted to type {@code float}. * * @param value the value to be represented by the {@code Float}. * * @deprecated * It is rarely appropriate to use this constructor. Instead, use the * static factory method {@link #valueOf(float)} method as follows: * {@code Float.valueOf((float)value)}. */ @Deprecated(since="9", forRemoval = true) public Float(double value) { this.value = (float)value; } /** * Constructs a newly allocated {@code Float} object that * represents the floating-point value of type {@code float} * represented by the string. The string is converted to a * {@code float} value as if by the {@code valueOf} method. * * @param s a string to be converted to a {@code Float}. * @throws NumberFormatException if the string does not contain a * parsable number. * * @deprecated * It is rarely appropriate to use this constructor. * Use {@link #parseFloat(String)} to convert a string to a * {@code float} primitive, or use {@link #valueOf(String)} * to convert a string to a {@code Float} object. */ @Deprecated(since="9", forRemoval = true) public Float(String s) throws NumberFormatException { value = parseFloat(s); } /** * Returns {@code true} if this {@code Float} value is a * Not-a-Number (NaN), {@code false} otherwise. * * @return {@code true} if the value represented by this object is * NaN; {@code false} otherwise. */ public boolean isNaN() { return isNaN(value); } /** * Returns {@code true} if this {@code Float} value is * infinitely large in magnitude, {@code false} otherwise. * * @return {@code true} if the value represented by this object is * positive infinity or negative infinity; * {@code false} otherwise. */ public boolean isInfinite() { return isInfinite(value); } /** * Returns a string representation of this {@code Float} object. * The primitive {@code float} value represented by this object * is converted to a {@code String} exactly as if by the method * {@code toString} of one argument. * * @return a {@code String} representation of this object. * @see java.lang.Float#toString(float) */ public String toString() { return Float.toString(value); } /** * Returns the value of this {@code Float} as a {@code byte} after * a narrowing primitive conversion. * * @return the {@code float} value represented by this object * converted to type {@code byte} * @jls 5.1.3 Narrowing Primitive Conversion */ public byte byteValue() { return (byte)value; } /** * Returns the value of this {@code Float} as a {@code short} * after a narrowing primitive conversion. * * @return the {@code float} value represented by this object * converted to type {@code short} * @jls 5.1.3 Narrowing Primitive Conversion * @since 1.1 */ public short shortValue() { return (short)value; } /** * Returns the value of this {@code Float} as an {@code int} after * a narrowing primitive conversion. * * @return the {@code float} value represented by this object * converted to type {@code int} * @jls 5.1.3 Narrowing Primitive Conversion */ public int intValue() { return (int)value; } /** * Returns value of this {@code Float} as a {@code long} after a * narrowing primitive conversion. * * @return the {@code float} value represented by this object * converted to type {@code long} * @jls 5.1.3 Narrowing Primitive Conversion */ public long longValue() { return (long)value; } /** * Returns the {@code float} value of this {@code Float} object. * * @return the {@code float} value represented by this object */ @IntrinsicCandidate public float floatValue() { return value; } /** * Returns the value of this {@code Float} as a {@code double} * after a widening primitive conversion. * * @return the {@code float} value represented by this * object converted to type {@code double} * @jls 5.1.2 Widening Primitive Conversion */ public double doubleValue() { return (double)value; } /** * Returns a hash code for this {@code Float} object. The * result is the integer bit representation, exactly as produced * by the method {@link #floatToIntBits(float)}, of the primitive * {@code float} value represented by this {@code Float} * object. * * @return a hash code value for this object. */ @Override public int hashCode() { return Float.hashCode(value); } /** * Returns a hash code for a {@code float} value; compatible with * {@code Float.hashCode()}. * * @param value the value to hash * @return a hash code value for a {@code float} value. * @since 1.8 */ public static int hashCode(float value) { return floatToIntBits(value); } /** * Compares this object against the specified object. The result * is {@code true} if and only if the argument is not * {@code null} and is a {@code Float} object that * represents a {@code float} with the same value as the * {@code float} represented by this object. For this * purpose, two {@code float} values are considered to be the * same if and only if the method {@link #floatToIntBits(float)} * returns the identical {@code int} value when applied to * each. * * @apiNote * This method is defined in terms of {@link * #floatToIntBits(float)} rather than the {@code ==} operator on * {@code float} values since the {@code ==} operator does * <em>not</em> define an equivalence relation and to satisfy the * {@linkplain Object#equals equals contract} an equivalence * relation must be implemented; see <a * href="Double.html#equivalenceRelation">this discussion</a> for * details of floating-point equality and equivalence. * * @param obj the object to be compared * @return {@code true} if the objects are the same; * {@code false} otherwise. * @see java.lang.Float#floatToIntBits(float) * @jls 15.21.1 Numerical Equality Operators == and != */ public boolean equals(Object obj) { return (obj instanceof Float) && (floatToIntBits(((Float)obj).value) == floatToIntBits(value)); } /** * Returns a representation of the specified floating-point value * according to the IEEE 754 floating-point "single format" bit * layout. * * <p>Bit 31 (the bit that is selected by the mask * {@code 0x80000000}) represents the sign of the floating-point * number. * Bits 30-23 (the bits that are selected by the mask * {@code 0x7f800000}) represent the exponent. * Bits 22-0 (the bits that are selected by the mask * {@code 0x007fffff}) represent the significand (sometimes called * the mantissa) of the floating-point number. * * <p>If the argument is positive infinity, the result is * {@code 0x7f800000}. * * <p>If the argument is negative infinity, the result is * {@code 0xff800000}. * * <p>If the argument is NaN, the result is {@code 0x7fc00000}. * * <p>In all cases, the result is an integer that, when given to the * {@link #intBitsToFloat(int)} method, will produce a floating-point * value the same as the argument to {@code floatToIntBits} * (except all NaN values are collapsed to a single * "canonical" NaN value). * * @param value a floating-point number. * @return the bits that represent the floating-point number. */ @IntrinsicCandidate public static int floatToIntBits(float value) { if (!isNaN(value)) { return floatToRawIntBits(value); } return 0x7fc00000; } /** * Returns a representation of the specified floating-point value * according to the IEEE 754 floating-point "single format" bit * layout, preserving Not-a-Number (NaN) values. * * <p>Bit 31 (the bit that is selected by the mask * {@code 0x80000000}) represents the sign of the floating-point * number. * Bits 30-23 (the bits that are selected by the mask * {@code 0x7f800000}) represent the exponent. * Bits 22-0 (the bits that are selected by the mask * {@code 0x007fffff}) represent the significand (sometimes called * the mantissa) of the floating-point number. * * <p>If the argument is positive infinity, the result is * {@code 0x7f800000}. * * <p>If the argument is negative infinity, the result is * {@code 0xff800000}. * * <p>If the argument is NaN, the result is the integer representing * the actual NaN value. Unlike the {@code floatToIntBits} * method, {@code floatToRawIntBits} does not collapse all the * bit patterns encoding a NaN to a single "canonical" * NaN value. * * <p>In all cases, the result is an integer that, when given to the * {@link #intBitsToFloat(int)} method, will produce a * floating-point value the same as the argument to * {@code floatToRawIntBits}. * * @param value a floating-point number. * @return the bits that represent the floating-point number. * @since 1.3 */ @IntrinsicCandidate public static native int floatToRawIntBits(float value); /** * Returns the {@code float} value corresponding to a given * bit representation. * The argument is considered to be a representation of a * floating-point value according to the IEEE 754 floating-point * "single format" bit layout. * * <p>If the argument is {@code 0x7f800000}, the result is positive * infinity. * * <p>If the argument is {@code 0xff800000}, the result is negative * infinity. * * <p>If the argument is any value in the range * {@code 0x7f800001} through {@code 0x7fffffff} or in * the range {@code 0xff800001} through * {@code 0xffffffff}, the result is a NaN. No IEEE 754 * floating-point operation provided by Java can distinguish * between two NaN values of the same type with different bit * patterns. Distinct values of NaN are only distinguishable by * use of the {@code Float.floatToRawIntBits} method. * * <p>In all other cases, let <i>s</i>, <i>e</i>, and <i>m</i> be three * values that can be computed from the argument: * * <blockquote><pre>{@code * int s = ((bits >> 31) == 0) ? 1 : -1; * int e = ((bits >> 23) & 0xff); * int m = (e == 0) ? * (bits & 0x7fffff) << 1 : * (bits & 0x7fffff) | 0x800000; * }</pre></blockquote> * * Then the floating-point result equals the value of the mathematical * expression <i>s</i>·<i>m</i>·2<sup><i>e</i>-150</sup>. * * <p>Note that this method may not be able to return a * {@code float} NaN with exactly same bit pattern as the * {@code int} argument. IEEE 754 distinguishes between two * kinds of NaNs, quiet NaNs and <i>signaling NaNs</i>. The * differences between the two kinds of NaN are generally not * visible in Java. Arithmetic operations on signaling NaNs turn * them into quiet NaNs with a different, but often similar, bit * pattern. However, on some processors merely copying a * signaling NaN also performs that conversion. In particular, * copying a signaling NaN to return it to the calling method may * perform this conversion. So {@code intBitsToFloat} may * not be able to return a {@code float} with a signaling NaN * bit pattern. Consequently, for some {@code int} values, * {@code floatToRawIntBits(intBitsToFloat(start))} may * <i>not</i> equal {@code start}. Moreover, which * particular bit patterns represent signaling NaNs is platform * dependent; although all NaN bit patterns, quiet or signaling, * must be in the NaN range identified above. * * @param bits an integer. * @return the {@code float} floating-point value with the same bit * pattern. */ @IntrinsicCandidate public static native float intBitsToFloat(int bits); /** * Compares two {@code Float} objects numerically. * * This method imposes a total order on {@code Float} objects * with two differences compared to the incomplete order defined by * the Java language numerical comparison operators ({@code <, <=, * ==, >=, >}) on {@code float} values. * * <ul><li> A NaN is <em>unordered</em> with respect to other * values and unequal to itself under the comparison * operators. This method chooses to define {@code * Float.NaN} to be equal to itself and greater than all * other {@code double} values (including {@code * Float.POSITIVE_INFINITY}). * * <li> Positive zero and negative zero compare equal * numerically, but are distinct and distinguishable values. * This method chooses to define positive zero ({@code +0.0f}), * to be greater than negative zero ({@code -0.0f}). * </ul> * * This ensures that the <i>natural ordering</i> of {@code Float} * objects imposed by this method is <i>consistent with * equals</i>; see <a href="Double.html#equivalenceRelation">this * discussion</a> for details of floating-point comparison and * ordering. * * * @param anotherFloat the {@code Float} to be compared. * @return the value {@code 0} if {@code anotherFloat} is * numerically equal to this {@code Float}; a value * less than {@code 0} if this {@code Float} * is numerically less than {@code anotherFloat}; * and a value greater than {@code 0} if this * {@code Float} is numerically greater than * {@code anotherFloat}. * * @jls 15.20.1 Numerical Comparison Operators {@code <}, {@code <=}, {@code >}, and {@code >=} * @since 1.2 */ public int compareTo(Float anotherFloat) { return Float.compare(value, anotherFloat.value); } /** * Compares the two specified {@code float} values. The sign * of the integer value returned is the same as that of the * integer that would be returned by the call: * <pre> * new Float(f1).compareTo(new Float(f2)) * </pre> * * @param f1 the first {@code float} to compare. * @param f2 the second {@code float} to compare. * @return the value {@code 0} if {@code f1} is * numerically equal to {@code f2}; a value less than * {@code 0} if {@code f1} is numerically less than * {@code f2}; and a value greater than {@code 0} * if {@code f1} is numerically greater than * {@code f2}. * @since 1.4 */ public static int compare(float f1, float f2) { if (f1 < f2) return -1; // Neither val is NaN, thisVal is smaller if (f1 > f2) return 1; // Neither val is NaN, thisVal is larger // Cannot use floatToRawIntBits because of possibility of NaNs. int thisBits = Float.floatToIntBits(f1); int anotherBits = Float.floatToIntBits(f2); return (thisBits == anotherBits ? 0 : // Values are equal (thisBits < anotherBits ? -1 : // (-0.0, 0.0) or (!NaN, NaN) 1)); // (0.0, -0.0) or (NaN, !NaN) } /** * Adds two {@code float} values together as per the + operator. * * @param a the first operand * @param b the second operand * @return the sum of {@code a} and {@code b} * @jls 4.2.4 Floating-Point Operations * @see java.util.function.BinaryOperator * @since 1.8 */ public static float sum(float a, float b) { return a + b; } /** * Returns the greater of two {@code float} values * as if by calling {@link Math#max(float, float) Math.max}. * * @param a the first operand * @param b the second operand * @return the greater of {@code a} and {@code b} * @see java.util.function.BinaryOperator * @since 1.8 */ public static float max(float a, float b) { return Math.max(a, b); } /** * Returns the smaller of two {@code float} values * as if by calling {@link Math#min(float, float) Math.min}. * * @param a the first operand * @param b the second operand * @return the smaller of {@code a} and {@code b} * @see java.util.function.BinaryOperator * @since 1.8 */ public static float min(float a, float b) { return Math.min(a, b); } /** * Returns an {@link Optional} containing the nominal descriptor for this * instance, which is the instance itself. * * @return an {@link Optional} describing the {@linkplain Float} instance * @since 12 */ @Override public Optional<Float> describeConstable() { return Optional.of(this); } /** * Resolves this instance as a {@link ConstantDesc}, the result of which is * the instance itself. * * @param lookup ignored * @return the {@linkplain Float} instance * @since 12 */ @Override public Float resolveConstantDesc(MethodHandles.Lookup lookup) { return this; } /** use serialVersionUID from JDK 1.0.2 for interoperability */ @java.io.Serial private static final long serialVersionUID = -2671257302660747028L; }
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