Only add the trailing '.0' if the number is known to be integer. Otherwise accept the string as provided by JavaScript
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28 import org.apidesign.bck2brwsr.core.JavaScriptBody;
31 * The {@code Double} class wraps a value of the primitive type
32 * {@code double} in an object. An object of type
33 * {@code Double} contains a single field whose type is
36 * <p>In addition, this class provides several methods for converting a
37 * {@code double} to a {@code String} and a
38 * {@code String} to a {@code double}, as well as other
39 * constants and methods useful when dealing with a
43 * @author Arthur van Hoff
44 * @author Joseph D. Darcy
47 public final class Double extends Number implements Comparable<Double> {
49 * A constant holding the positive infinity of type
50 * {@code double}. It is equal to the value returned by
51 * {@code Double.longBitsToDouble(0x7ff0000000000000L)}.
53 public static final double POSITIVE_INFINITY = 1.0 / 0.0;
56 * A constant holding the negative infinity of type
57 * {@code double}. It is equal to the value returned by
58 * {@code Double.longBitsToDouble(0xfff0000000000000L)}.
60 public static final double NEGATIVE_INFINITY = -1.0 / 0.0;
63 * A constant holding a Not-a-Number (NaN) value of type
64 * {@code double}. It is equivalent to the value returned by
65 * {@code Double.longBitsToDouble(0x7ff8000000000000L)}.
67 public static final double NaN = 0.0d / 0.0;
70 * A constant holding the largest positive finite value of type
72 * (2-2<sup>-52</sup>)·2<sup>1023</sup>. It is equal to
73 * the hexadecimal floating-point literal
74 * {@code 0x1.fffffffffffffP+1023} and also equal to
75 * {@code Double.longBitsToDouble(0x7fefffffffffffffL)}.
77 public static final double MAX_VALUE = 0x1.fffffffffffffP+1023; // 1.7976931348623157e+308
80 * A constant holding the smallest positive normal value of type
81 * {@code double}, 2<sup>-1022</sup>. It is equal to the
82 * hexadecimal floating-point literal {@code 0x1.0p-1022} and also
83 * equal to {@code Double.longBitsToDouble(0x0010000000000000L)}.
87 public static final double MIN_NORMAL = 0x1.0p-1022; // 2.2250738585072014E-308
90 * A constant holding the smallest positive nonzero value of type
91 * {@code double}, 2<sup>-1074</sup>. It is equal to the
92 * hexadecimal floating-point literal
93 * {@code 0x0.0000000000001P-1022} and also equal to
94 * {@code Double.longBitsToDouble(0x1L)}.
96 public static final double MIN_VALUE = 0x0.0000000000001P-1022; // 4.9e-324
99 * Maximum exponent a finite {@code double} variable may have.
100 * It is equal to the value returned by
101 * {@code Math.getExponent(Double.MAX_VALUE)}.
105 public static final int MAX_EXPONENT = 1023;
108 * Minimum exponent a normalized {@code double} variable may
109 * have. It is equal to the value returned by
110 * {@code Math.getExponent(Double.MIN_NORMAL)}.
114 public static final int MIN_EXPONENT = -1022;
117 * The number of bits used to represent a {@code double} value.
121 public static final int SIZE = 64;
124 * The {@code Class} instance representing the primitive type
129 public static final Class<Double> TYPE = (Class<Double>) Class.getPrimitiveClass("double");
132 * Returns a string representation of the {@code double}
133 * argument. All characters mentioned below are ASCII characters.
135 * <li>If the argument is NaN, the result is the string
137 * <li>Otherwise, the result is a string that represents the sign and
138 * magnitude (absolute value) of the argument. If the sign is negative,
139 * the first character of the result is '{@code -}'
140 * (<code>'\u002D'</code>); if the sign is positive, no sign character
141 * appears in the result. As for the magnitude <i>m</i>:
143 * <li>If <i>m</i> is infinity, it is represented by the characters
144 * {@code "Infinity"}; thus, positive infinity produces the result
145 * {@code "Infinity"} and negative infinity produces the result
146 * {@code "-Infinity"}.
148 * <li>If <i>m</i> is zero, it is represented by the characters
149 * {@code "0.0"}; thus, negative zero produces the result
150 * {@code "-0.0"} and positive zero produces the result
153 * <li>If <i>m</i> is greater than or equal to 10<sup>-3</sup> but less
154 * than 10<sup>7</sup>, then it is represented as the integer part of
155 * <i>m</i>, in decimal form with no leading zeroes, followed by
156 * '{@code .}' (<code>'\u002E'</code>), followed by one or
157 * more decimal digits representing the fractional part of <i>m</i>.
159 * <li>If <i>m</i> is less than 10<sup>-3</sup> or greater than or
160 * equal to 10<sup>7</sup>, then it is represented in so-called
161 * "computerized scientific notation." Let <i>n</i> be the unique
162 * integer such that 10<sup><i>n</i></sup> ≤ <i>m</i> {@literal <}
163 * 10<sup><i>n</i>+1</sup>; then let <i>a</i> be the
164 * mathematically exact quotient of <i>m</i> and
165 * 10<sup><i>n</i></sup> so that 1 ≤ <i>a</i> {@literal <} 10. The
166 * magnitude is then represented as the integer part of <i>a</i>,
167 * as a single decimal digit, followed by '{@code .}'
168 * (<code>'\u002E'</code>), followed by decimal digits
169 * representing the fractional part of <i>a</i>, followed by the
170 * letter '{@code E}' (<code>'\u0045'</code>), followed
171 * by a representation of <i>n</i> as a decimal integer, as
172 * produced by the method {@link Integer#toString(int)}.
175 * How many digits must be printed for the fractional part of
176 * <i>m</i> or <i>a</i>? There must be at least one digit to represent
177 * the fractional part, and beyond that as many, but only as many, more
178 * digits as are needed to uniquely distinguish the argument value from
179 * adjacent values of type {@code double}. That is, suppose that
180 * <i>x</i> is the exact mathematical value represented by the decimal
181 * representation produced by this method for a finite nonzero argument
182 * <i>d</i>. Then <i>d</i> must be the {@code double} value nearest
183 * to <i>x</i>; or if two {@code double} values are equally close
184 * to <i>x</i>, then <i>d</i> must be one of them and the least
185 * significant bit of the significand of <i>d</i> must be {@code 0}.
187 * <p>To create localized string representations of a floating-point
188 * value, use subclasses of {@link java.text.NumberFormat}.
190 * @param d the {@code double} to be converted.
191 * @return a string representation of the argument.
193 @JavaScriptBody(args="d", body="var f = Math.floor(d);\n" +
194 "if (f === d && isFinite(d)) return d.toString() + '.0';\n" +
195 "else return d.toString();"
197 public static native String toString(double d);
200 * Returns a hexadecimal string representation of the
201 * {@code double} argument. All characters mentioned below
202 * are ASCII characters.
205 * <li>If the argument is NaN, the result is the string
207 * <li>Otherwise, the result is a string that represents the sign
208 * and magnitude of the argument. If the sign is negative, the
209 * first character of the result is '{@code -}'
210 * (<code>'\u002D'</code>); if the sign is positive, no sign
211 * character appears in the result. As for the magnitude <i>m</i>:
214 * <li>If <i>m</i> is infinity, it is represented by the string
215 * {@code "Infinity"}; thus, positive infinity produces the
216 * result {@code "Infinity"} and negative infinity produces
217 * the result {@code "-Infinity"}.
219 * <li>If <i>m</i> is zero, it is represented by the string
220 * {@code "0x0.0p0"}; thus, negative zero produces the result
221 * {@code "-0x0.0p0"} and positive zero produces the result
224 * <li>If <i>m</i> is a {@code double} value with a
225 * normalized representation, substrings are used to represent the
226 * significand and exponent fields. The significand is
227 * represented by the characters {@code "0x1."}
228 * followed by a lowercase hexadecimal representation of the rest
229 * of the significand as a fraction. Trailing zeros in the
230 * hexadecimal representation are removed unless all the digits
231 * are zero, in which case a single zero is used. Next, the
232 * exponent is represented by {@code "p"} followed
233 * by a decimal string of the unbiased exponent as if produced by
234 * a call to {@link Integer#toString(int) Integer.toString} on the
237 * <li>If <i>m</i> is a {@code double} value with a subnormal
238 * representation, the significand is represented by the
239 * characters {@code "0x0."} followed by a
240 * hexadecimal representation of the rest of the significand as a
241 * fraction. Trailing zeros in the hexadecimal representation are
242 * removed. Next, the exponent is represented by
243 * {@code "p-1022"}. Note that there must be at
244 * least one nonzero digit in a subnormal significand.
251 * <caption><h3>Examples</h3></caption>
252 * <tr><th>Floating-point Value</th><th>Hexadecimal String</th>
253 * <tr><td>{@code 1.0}</td> <td>{@code 0x1.0p0}</td>
254 * <tr><td>{@code -1.0}</td> <td>{@code -0x1.0p0}</td>
255 * <tr><td>{@code 2.0}</td> <td>{@code 0x1.0p1}</td>
256 * <tr><td>{@code 3.0}</td> <td>{@code 0x1.8p1}</td>
257 * <tr><td>{@code 0.5}</td> <td>{@code 0x1.0p-1}</td>
258 * <tr><td>{@code 0.25}</td> <td>{@code 0x1.0p-2}</td>
259 * <tr><td>{@code Double.MAX_VALUE}</td>
260 * <td>{@code 0x1.fffffffffffffp1023}</td>
261 * <tr><td>{@code Minimum Normal Value}</td>
262 * <td>{@code 0x1.0p-1022}</td>
263 * <tr><td>{@code Maximum Subnormal Value}</td>
264 * <td>{@code 0x0.fffffffffffffp-1022}</td>
265 * <tr><td>{@code Double.MIN_VALUE}</td>
266 * <td>{@code 0x0.0000000000001p-1022}</td>
268 * @param d the {@code double} to be converted.
269 * @return a hex string representation of the argument.
271 * @author Joseph D. Darcy
273 public static String toHexString(double d) {
274 throw new UnsupportedOperationException();
276 // * Modeled after the "a" conversion specifier in C99, section
277 // * 7.19.6.1; however, the output of this method is more
278 // * tightly specified.
280 // if (!FpUtils.isFinite(d) )
281 // // For infinity and NaN, use the decimal output.
282 // return Double.toString(d);
284 // // Initialized to maximum size of output.
285 // StringBuffer answer = new StringBuffer(24);
287 // if (FpUtils.rawCopySign(1.0, d) == -1.0) // value is negative,
288 // answer.append("-"); // so append sign info
290 // answer.append("0x");
295 // answer.append("0.0p0");
298 // boolean subnormal = (d < DoubleConsts.MIN_NORMAL);
300 // // Isolate significand bits and OR in a high-order bit
301 // // so that the string representation has a known
303 // long signifBits = (Double.doubleToLongBits(d)
304 // & DoubleConsts.SIGNIF_BIT_MASK) |
305 // 0x1000000000000000L;
307 // // Subnormal values have a 0 implicit bit; normal
308 // // values have a 1 implicit bit.
309 // answer.append(subnormal ? "0." : "1.");
311 // // Isolate the low-order 13 digits of the hex
312 // // representation. If all the digits are zero,
313 // // replace with a single 0; otherwise, remove all
314 // // trailing zeros.
315 // String signif = Long.toHexString(signifBits).substring(3,16);
316 // answer.append(signif.equals("0000000000000") ? // 13 zeros
318 // signif.replaceFirst("0{1,12}$", ""));
320 // // If the value is subnormal, use the E_min exponent
321 // // value for double; otherwise, extract and report d's
322 // // exponent (the representation of a subnormal uses
324 // answer.append("p" + (subnormal ?
325 // DoubleConsts.MIN_EXPONENT:
326 // FpUtils.getExponent(d) ));
328 // return answer.toString();
333 * Returns a {@code Double} object holding the
334 * {@code double} value represented by the argument string
337 * <p>If {@code s} is {@code null}, then a
338 * {@code NullPointerException} is thrown.
340 * <p>Leading and trailing whitespace characters in {@code s}
341 * are ignored. Whitespace is removed as if by the {@link
342 * String#trim} method; that is, both ASCII space and control
343 * characters are removed. The rest of {@code s} should
344 * constitute a <i>FloatValue</i> as described by the lexical
349 * <dt><i>FloatValue:</i>
350 * <dd><i>Sign<sub>opt</sub></i> {@code NaN}
351 * <dd><i>Sign<sub>opt</sub></i> {@code Infinity}
352 * <dd><i>Sign<sub>opt</sub> FloatingPointLiteral</i>
353 * <dd><i>Sign<sub>opt</sub> HexFloatingPointLiteral</i>
354 * <dd><i>SignedInteger</i>
360 * <dt><i>HexFloatingPointLiteral</i>:
361 * <dd> <i>HexSignificand BinaryExponent FloatTypeSuffix<sub>opt</sub></i>
367 * <dt><i>HexSignificand:</i>
368 * <dd><i>HexNumeral</i>
369 * <dd><i>HexNumeral</i> {@code .}
370 * <dd>{@code 0x} <i>HexDigits<sub>opt</sub>
371 * </i>{@code .}<i> HexDigits</i>
372 * <dd>{@code 0X}<i> HexDigits<sub>opt</sub>
373 * </i>{@code .} <i>HexDigits</i>
379 * <dt><i>BinaryExponent:</i>
380 * <dd><i>BinaryExponentIndicator SignedInteger</i>
386 * <dt><i>BinaryExponentIndicator:</i>
393 * where <i>Sign</i>, <i>FloatingPointLiteral</i>,
394 * <i>HexNumeral</i>, <i>HexDigits</i>, <i>SignedInteger</i> and
395 * <i>FloatTypeSuffix</i> are as defined in the lexical structure
397 * <cite>The Java™ Language Specification</cite>,
398 * except that underscores are not accepted between digits.
399 * If {@code s} does not have the form of
400 * a <i>FloatValue</i>, then a {@code NumberFormatException}
401 * is thrown. Otherwise, {@code s} is regarded as
402 * representing an exact decimal value in the usual
403 * "computerized scientific notation" or as an exact
404 * hexadecimal value; this exact numerical value is then
405 * conceptually converted to an "infinitely precise"
406 * binary value that is then rounded to type {@code double}
407 * by the usual round-to-nearest rule of IEEE 754 floating-point
408 * arithmetic, which includes preserving the sign of a zero
411 * Note that the round-to-nearest rule also implies overflow and
412 * underflow behaviour; if the exact value of {@code s} is large
413 * enough in magnitude (greater than or equal to ({@link
414 * #MAX_VALUE} + {@link Math#ulp(double) ulp(MAX_VALUE)}/2),
415 * rounding to {@code double} will result in an infinity and if the
416 * exact value of {@code s} is small enough in magnitude (less
417 * than or equal to {@link #MIN_VALUE}/2), rounding to float will
420 * Finally, after rounding a {@code Double} object representing
421 * this {@code double} value is returned.
423 * <p> To interpret localized string representations of a
424 * floating-point value, use subclasses of {@link
425 * java.text.NumberFormat}.
427 * <p>Note that trailing format specifiers, specifiers that
428 * determine the type of a floating-point literal
429 * ({@code 1.0f} is a {@code float} value;
430 * {@code 1.0d} is a {@code double} value), do
431 * <em>not</em> influence the results of this method. In other
432 * words, the numerical value of the input string is converted
433 * directly to the target floating-point type. The two-step
434 * sequence of conversions, string to {@code float} followed
435 * by {@code float} to {@code double}, is <em>not</em>
436 * equivalent to converting a string directly to
437 * {@code double}. For example, the {@code float}
438 * literal {@code 0.1f} is equal to the {@code double}
439 * value {@code 0.10000000149011612}; the {@code float}
440 * literal {@code 0.1f} represents a different numerical
441 * value than the {@code double} literal
442 * {@code 0.1}. (The numerical value 0.1 cannot be exactly
443 * represented in a binary floating-point number.)
445 * <p>To avoid calling this method on an invalid string and having
446 * a {@code NumberFormatException} be thrown, the regular
447 * expression below can be used to screen the input string:
451 * final String Digits = "(\\p{Digit}+)";
452 * final String HexDigits = "(\\p{XDigit}+)";
453 * // an exponent is 'e' or 'E' followed by an optionally
454 * // signed decimal integer.
455 * final String Exp = "[eE][+-]?"+Digits;
456 * final String fpRegex =
457 * ("[\\x00-\\x20]*"+ // Optional leading "whitespace"
458 * "[+-]?(" + // Optional sign character
459 * "NaN|" + // "NaN" string
460 * "Infinity|" + // "Infinity" string
462 * // A decimal floating-point string representing a finite positive
463 * // number without a leading sign has at most five basic pieces:
464 * // Digits . Digits ExponentPart FloatTypeSuffix
466 * // Since this method allows integer-only strings as input
467 * // in addition to strings of floating-point literals, the
468 * // two sub-patterns below are simplifications of the grammar
469 * // productions from section 3.10.2 of
470 * // <cite>The Java™ Language Specification</cite>.
472 * // Digits ._opt Digits_opt ExponentPart_opt FloatTypeSuffix_opt
473 * "((("+Digits+"(\\.)?("+Digits+"?)("+Exp+")?)|"+
475 * // . Digits ExponentPart_opt FloatTypeSuffix_opt
476 * "(\\.("+Digits+")("+Exp+")?)|"+
478 * // Hexadecimal strings
480 * // 0[xX] HexDigits ._opt BinaryExponent FloatTypeSuffix_opt
481 * "(0[xX]" + HexDigits + "(\\.)?)|" +
483 * // 0[xX] HexDigits_opt . HexDigits BinaryExponent FloatTypeSuffix_opt
484 * "(0[xX]" + HexDigits + "?(\\.)" + HexDigits + ")" +
486 * ")[pP][+-]?" + Digits + "))" +
488 * "[\\x00-\\x20]*");// Optional trailing "whitespace"
490 * if (Pattern.matches(fpRegex, myString))
491 * Double.valueOf(myString); // Will not throw NumberFormatException
493 * // Perform suitable alternative action
498 * @param s the string to be parsed.
499 * @return a {@code Double} object holding the value
500 * represented by the {@code String} argument.
501 * @throws NumberFormatException if the string does not contain a
504 @JavaScriptBody(args="s", body="return parseFloat(s);")
505 public static Double valueOf(String s) throws NumberFormatException {
506 throw new UnsupportedOperationException();
507 // return new Double(FloatingDecimal.readJavaFormatString(s).doubleValue());
511 * Returns a {@code Double} instance representing the specified
512 * {@code double} value.
513 * If a new {@code Double} instance is not required, this method
514 * should generally be used in preference to the constructor
515 * {@link #Double(double)}, as this method is likely to yield
516 * significantly better space and time performance by caching
517 * frequently requested values.
519 * @param d a double value.
520 * @return a {@code Double} instance representing {@code d}.
523 public static Double valueOf(double d) {
524 return new Double(d);
528 * Returns a new {@code double} initialized to the value
529 * represented by the specified {@code String}, as performed
530 * by the {@code valueOf} method of class
533 * @param s the string to be parsed.
534 * @return the {@code double} value represented by the string
536 * @throws NullPointerException if the string is null
537 * @throws NumberFormatException if the string does not contain
538 * a parsable {@code double}.
539 * @see java.lang.Double#valueOf(String)
542 @JavaScriptBody(args="s", body="return parseFloat(s);")
543 public static double parseDouble(String s) throws NumberFormatException {
544 throw new UnsupportedOperationException();
545 // return FloatingDecimal.readJavaFormatString(s).doubleValue();
549 * Returns {@code true} if the specified number is a
550 * Not-a-Number (NaN) value, {@code false} otherwise.
552 * @param v the value to be tested.
553 * @return {@code true} if the value of the argument is NaN;
554 * {@code false} otherwise.
556 static public boolean isNaN(double v) {
561 * Returns {@code true} if the specified number is infinitely
562 * large in magnitude, {@code false} otherwise.
564 * @param v the value to be tested.
565 * @return {@code true} if the value of the argument is positive
566 * infinity or negative infinity; {@code false} otherwise.
568 static public boolean isInfinite(double v) {
569 return (v == POSITIVE_INFINITY) || (v == NEGATIVE_INFINITY);
573 * The value of the Double.
577 private final double value;
580 * Constructs a newly allocated {@code Double} object that
581 * represents the primitive {@code double} argument.
583 * @param value the value to be represented by the {@code Double}.
585 public Double(double value) {
590 * Constructs a newly allocated {@code Double} object that
591 * represents the floating-point value of type {@code double}
592 * represented by the string. The string is converted to a
593 * {@code double} value as if by the {@code valueOf} method.
595 * @param s a string to be converted to a {@code Double}.
596 * @throws NumberFormatException if the string does not contain a
598 * @see java.lang.Double#valueOf(java.lang.String)
600 public Double(String s) throws NumberFormatException {
601 // REMIND: this is inefficient
602 this(valueOf(s).doubleValue());
606 * Returns {@code true} if this {@code Double} value is
607 * a Not-a-Number (NaN), {@code false} otherwise.
609 * @return {@code true} if the value represented by this object is
610 * NaN; {@code false} otherwise.
612 public boolean isNaN() {
617 * Returns {@code true} if this {@code Double} value is
618 * infinitely large in magnitude, {@code false} otherwise.
620 * @return {@code true} if the value represented by this object is
621 * positive infinity or negative infinity;
622 * {@code false} otherwise.
624 public boolean isInfinite() {
625 return isInfinite(value);
629 * Returns a string representation of this {@code Double} object.
630 * The primitive {@code double} value represented by this
631 * object is converted to a string exactly as if by the method
632 * {@code toString} of one argument.
634 * @return a {@code String} representation of this object.
635 * @see java.lang.Double#toString(double)
637 public String toString() {
638 return toString(value);
642 * Returns the value of this {@code Double} as a {@code byte} (by
643 * casting to a {@code byte}).
645 * @return the {@code double} value represented by this object
646 * converted to type {@code byte}
649 public byte byteValue() {
654 * Returns the value of this {@code Double} as a
655 * {@code short} (by casting to a {@code short}).
657 * @return the {@code double} value represented by this object
658 * converted to type {@code short}
661 public short shortValue() {
666 * Returns the value of this {@code Double} as an
667 * {@code int} (by casting to type {@code int}).
669 * @return the {@code double} value represented by this object
670 * converted to type {@code int}
672 public int intValue() {
677 * Returns the value of this {@code Double} as a
678 * {@code long} (by casting to type {@code long}).
680 * @return the {@code double} value represented by this object
681 * converted to type {@code long}
683 public long longValue() {
688 * Returns the {@code float} value of this
689 * {@code Double} object.
691 * @return the {@code double} value represented by this object
692 * converted to type {@code float}
695 public float floatValue() {
700 * Returns the {@code double} value of this
701 * {@code Double} object.
703 * @return the {@code double} value represented by this object
705 public double doubleValue() {
706 return (double)value;
710 * Returns a hash code for this {@code Double} object. The
711 * result is the exclusive OR of the two halves of the
712 * {@code long} integer bit representation, exactly as
713 * produced by the method {@link #doubleToLongBits(double)}, of
714 * the primitive {@code double} value represented by this
715 * {@code Double} object. That is, the hash code is the value
719 * {@code (int)(v^(v>>>32))}
722 * where {@code v} is defined by:
725 * {@code long v = Double.doubleToLongBits(this.doubleValue());}
728 * @return a {@code hash code} value for this object.
730 public int hashCode() {
731 long bits = doubleToLongBits(value);
732 return (int)(bits ^ (bits >>> 32));
736 * Compares this object against the specified object. The result
737 * is {@code true} if and only if the argument is not
738 * {@code null} and is a {@code Double} object that
739 * represents a {@code double} that has the same value as the
740 * {@code double} represented by this object. For this
741 * purpose, two {@code double} values are considered to be
742 * the same if and only if the method {@link
743 * #doubleToLongBits(double)} returns the identical
744 * {@code long} value when applied to each.
746 * <p>Note that in most cases, for two instances of class
747 * {@code Double}, {@code d1} and {@code d2}, the
748 * value of {@code d1.equals(d2)} is {@code true} if and
752 * {@code d1.doubleValue() == d2.doubleValue()}
755 * <p>also has the value {@code true}. However, there are two
758 * <li>If {@code d1} and {@code d2} both represent
759 * {@code Double.NaN}, then the {@code equals} method
760 * returns {@code true}, even though
761 * {@code Double.NaN==Double.NaN} has the value
763 * <li>If {@code d1} represents {@code +0.0} while
764 * {@code d2} represents {@code -0.0}, or vice versa,
765 * the {@code equal} test has the value {@code false},
766 * even though {@code +0.0==-0.0} has the value {@code true}.
768 * This definition allows hash tables to operate properly.
769 * @param obj the object to compare with.
770 * @return {@code true} if the objects are the same;
771 * {@code false} otherwise.
772 * @see java.lang.Double#doubleToLongBits(double)
774 public boolean equals(Object obj) {
775 return (obj instanceof Double)
776 && (((Double)obj).value) == value;
780 * Returns a representation of the specified floating-point value
781 * according to the IEEE 754 floating-point "double
782 * format" bit layout.
784 * <p>Bit 63 (the bit that is selected by the mask
785 * {@code 0x8000000000000000L}) represents the sign of the
786 * floating-point number. Bits
787 * 62-52 (the bits that are selected by the mask
788 * {@code 0x7ff0000000000000L}) represent the exponent. Bits 51-0
789 * (the bits that are selected by the mask
790 * {@code 0x000fffffffffffffL}) represent the significand
791 * (sometimes called the mantissa) of the floating-point number.
793 * <p>If the argument is positive infinity, the result is
794 * {@code 0x7ff0000000000000L}.
796 * <p>If the argument is negative infinity, the result is
797 * {@code 0xfff0000000000000L}.
799 * <p>If the argument is NaN, the result is
800 * {@code 0x7ff8000000000000L}.
802 * <p>In all cases, the result is a {@code long} integer that, when
803 * given to the {@link #longBitsToDouble(long)} method, will produce a
804 * floating-point value the same as the argument to
805 * {@code doubleToLongBits} (except all NaN values are
806 * collapsed to a single "canonical" NaN value).
808 * @param value a {@code double} precision floating-point number.
809 * @return the bits that represent the floating-point number.
811 public static long doubleToLongBits(double value) {
812 throw new UnsupportedOperationException();
813 // long result = doubleToRawLongBits(value);
814 // // Check for NaN based on values of bit fields, maximum
815 // // exponent and nonzero significand.
816 // if ( ((result & DoubleConsts.EXP_BIT_MASK) ==
817 // DoubleConsts.EXP_BIT_MASK) &&
818 // (result & DoubleConsts.SIGNIF_BIT_MASK) != 0L)
819 // result = 0x7ff8000000000000L;
824 * Returns a representation of the specified floating-point value
825 * according to the IEEE 754 floating-point "double
826 * format" bit layout, preserving Not-a-Number (NaN) values.
828 * <p>Bit 63 (the bit that is selected by the mask
829 * {@code 0x8000000000000000L}) represents the sign of the
830 * floating-point number. Bits
831 * 62-52 (the bits that are selected by the mask
832 * {@code 0x7ff0000000000000L}) represent the exponent. Bits 51-0
833 * (the bits that are selected by the mask
834 * {@code 0x000fffffffffffffL}) represent the significand
835 * (sometimes called the mantissa) of the floating-point number.
837 * <p>If the argument is positive infinity, the result is
838 * {@code 0x7ff0000000000000L}.
840 * <p>If the argument is negative infinity, the result is
841 * {@code 0xfff0000000000000L}.
843 * <p>If the argument is NaN, the result is the {@code long}
844 * integer representing the actual NaN value. Unlike the
845 * {@code doubleToLongBits} method,
846 * {@code doubleToRawLongBits} does not collapse all the bit
847 * patterns encoding a NaN to a single "canonical" NaN
850 * <p>In all cases, the result is a {@code long} integer that,
851 * when given to the {@link #longBitsToDouble(long)} method, will
852 * produce a floating-point value the same as the argument to
853 * {@code doubleToRawLongBits}.
855 * @param value a {@code double} precision floating-point number.
856 * @return the bits that represent the floating-point number.
859 public static native long doubleToRawLongBits(double value);
862 * Returns the {@code double} value corresponding to a given
863 * bit representation.
864 * The argument is considered to be a representation of a
865 * floating-point value according to the IEEE 754 floating-point
866 * "double format" bit layout.
868 * <p>If the argument is {@code 0x7ff0000000000000L}, the result
869 * is positive infinity.
871 * <p>If the argument is {@code 0xfff0000000000000L}, the result
872 * is negative infinity.
874 * <p>If the argument is any value in the range
875 * {@code 0x7ff0000000000001L} through
876 * {@code 0x7fffffffffffffffL} or in the range
877 * {@code 0xfff0000000000001L} through
878 * {@code 0xffffffffffffffffL}, the result is a NaN. No IEEE
879 * 754 floating-point operation provided by Java can distinguish
880 * between two NaN values of the same type with different bit
881 * patterns. Distinct values of NaN are only distinguishable by
882 * use of the {@code Double.doubleToRawLongBits} method.
884 * <p>In all other cases, let <i>s</i>, <i>e</i>, and <i>m</i> be three
885 * values that can be computed from the argument:
888 * int s = ((bits >> 63) == 0) ? 1 : -1;
889 * int e = (int)((bits >> 52) & 0x7ffL);
890 * long m = (e == 0) ?
891 * (bits & 0xfffffffffffffL) << 1 :
892 * (bits & 0xfffffffffffffL) | 0x10000000000000L;
893 * </pre></blockquote>
895 * Then the floating-point result equals the value of the mathematical
896 * expression <i>s</i>·<i>m</i>·2<sup><i>e</i>-1075</sup>.
898 * <p>Note that this method may not be able to return a
899 * {@code double} NaN with exactly same bit pattern as the
900 * {@code long} argument. IEEE 754 distinguishes between two
901 * kinds of NaNs, quiet NaNs and <i>signaling NaNs</i>. The
902 * differences between the two kinds of NaN are generally not
903 * visible in Java. Arithmetic operations on signaling NaNs turn
904 * them into quiet NaNs with a different, but often similar, bit
905 * pattern. However, on some processors merely copying a
906 * signaling NaN also performs that conversion. In particular,
907 * copying a signaling NaN to return it to the calling method
908 * may perform this conversion. So {@code longBitsToDouble}
909 * may not be able to return a {@code double} with a
910 * signaling NaN bit pattern. Consequently, for some
911 * {@code long} values,
912 * {@code doubleToRawLongBits(longBitsToDouble(start))} may
913 * <i>not</i> equal {@code start}. Moreover, which
914 * particular bit patterns represent signaling NaNs is platform
915 * dependent; although all NaN bit patterns, quiet or signaling,
916 * must be in the NaN range identified above.
918 * @param bits any {@code long} integer.
919 * @return the {@code double} floating-point value with the same
922 @JavaScriptBody(args={ "bits" },
924 "var hi = bits.high32();\n"
925 + "var s = (hi & 0x80000000) === 0 ? 1 : -1;\n"
926 + "var e = (hi >> 20) & 0x7ff;\n"
927 + "if (e === 0x7ff) {\n"
928 + " if ((bits == 0) && ((hi & 0xfffff) === 0)) {\n"
929 + " return (s > 0) ? Number.POSITIVE_INFINITY"
930 + " : Number.NEGATIVE_INFINITY;\n"
932 + " return Number.NaN;\n"
934 + "var m = (hi & 0xfffff).next32(bits);\n"
936 + " m = m.shl64(1);\n"
938 + " m.hi = m.high32() | 0x100000;\n"
940 + "return s * m.toFP() * Math.pow(2.0, e - 1075);\n"
942 public static native double longBitsToDouble(long bits);
945 * Compares two {@code Double} objects numerically. There
946 * are two ways in which comparisons performed by this method
947 * differ from those performed by the Java language numerical
948 * comparison operators ({@code <, <=, ==, >=, >})
949 * when applied to primitive {@code double} values:
951 * {@code Double.NaN} is considered by this method
952 * to be equal to itself and greater than all other
953 * {@code double} values (including
954 * {@code Double.POSITIVE_INFINITY}).
956 * {@code 0.0d} is considered by this method to be greater
957 * than {@code -0.0d}.
959 * This ensures that the <i>natural ordering</i> of
960 * {@code Double} objects imposed by this method is <i>consistent
963 * @param anotherDouble the {@code Double} to be compared.
964 * @return the value {@code 0} if {@code anotherDouble} is
965 * numerically equal to this {@code Double}; a value
966 * less than {@code 0} if this {@code Double}
967 * is numerically less than {@code anotherDouble};
968 * and a value greater than {@code 0} if this
969 * {@code Double} is numerically greater than
970 * {@code anotherDouble}.
974 public int compareTo(Double anotherDouble) {
975 return Double.compare(value, anotherDouble.value);
979 * Compares the two specified {@code double} values. The sign
980 * of the integer value returned is the same as that of the
981 * integer that would be returned by the call:
983 * new Double(d1).compareTo(new Double(d2))
986 * @param d1 the first {@code double} to compare
987 * @param d2 the second {@code double} to compare
988 * @return the value {@code 0} if {@code d1} is
989 * numerically equal to {@code d2}; a value less than
990 * {@code 0} if {@code d1} is numerically less than
991 * {@code d2}; and a value greater than {@code 0}
992 * if {@code d1} is numerically greater than
996 public static int compare(double d1, double d2) {
998 return -1; // Neither val is NaN, thisVal is smaller
1000 return 1; // Neither val is NaN, thisVal is larger
1002 // Cannot use doubleToRawLongBits because of possibility of NaNs.
1003 long thisBits = Double.doubleToLongBits(d1);
1004 long anotherBits = Double.doubleToLongBits(d2);
1006 return (thisBits == anotherBits ? 0 : // Values are equal
1007 (thisBits < anotherBits ? -1 : // (-0.0, 0.0) or (!NaN, NaN)
1008 1)); // (0.0, -0.0) or (NaN, !NaN)
1011 /** use serialVersionUID from JDK 1.0.2 for interoperability */
1012 private static final long serialVersionUID = -9172774392245257468L;