1 /*
2  * Copyright (C) 2015 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *   http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 /*
18  * The above license covers additions and changes by AOSP authors.
19  * The original code is licensed as follows:
20  */
21 
22 //
23 // Copyright (c) 1999, Silicon Graphics, Inc. -- ALL RIGHTS RESERVED
24 //
25 // Permission is granted free of charge to copy, modify, use and distribute
26 // this software  provided you include the entirety of this notice in all
27 // copies made.
28 //
29 // THIS SOFTWARE IS PROVIDED ON AN AS IS BASIS, WITHOUT WARRANTY OF ANY
30 // KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION,
31 // WARRANTIES THAT THE SUBJECT SOFTWARE IS FREE OF DEFECTS, MERCHANTABLE, FIT
32 // FOR A PARTICULAR PURPOSE OR NON-INFRINGING.   SGI ASSUMES NO RISK AS TO THE
33 // QUALITY AND PERFORMANCE OF THE SOFTWARE.   SHOULD THE SOFTWARE PROVE
34 // DEFECTIVE IN ANY RESPECT, SGI ASSUMES NO COST OR LIABILITY FOR ANY
35 // SERVICING, REPAIR OR CORRECTION.  THIS DISCLAIMER OF WARRANTY CONSTITUTES
36 // AN ESSENTIAL PART OF THIS LICENSE. NO USE OF ANY SUBJECT SOFTWARE IS
37 // AUTHORIZED HEREUNDER EXCEPT UNDER THIS DISCLAIMER.
38 //
39 // UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, WHETHER TORT (INCLUDING,
40 // WITHOUT LIMITATION, NEGLIGENCE OR STRICT LIABILITY), CONTRACT, OR
41 // OTHERWISE, SHALL SGI BE LIABLE FOR ANY DIRECT, INDIRECT, SPECIAL,
42 // INCIDENTAL, OR CONSEQUENTIAL DAMAGES OF ANY CHARACTER WITH RESPECT TO THE
43 // SOFTWARE INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF GOODWILL, WORK
44 // STOPPAGE, LOSS OF DATA, COMPUTER FAILURE OR MALFUNCTION, OR ANY AND ALL
45 // OTHER COMMERCIAL DAMAGES OR LOSSES, EVEN IF SGI SHALL HAVE BEEN INFORMED OF
46 // THE POSSIBILITY OF SUCH DAMAGES.  THIS LIMITATION OF LIABILITY SHALL NOT
47 // APPLY TO LIABILITY RESULTING FROM SGI's NEGLIGENCE TO THE EXTENT APPLICABLE
48 // LAW PROHIBITS SUCH LIMITATION.  SOME JURISDICTIONS DO NOT ALLOW THE
49 // EXCLUSION OR LIMITATION OF INCIDENTAL OR CONSEQUENTIAL DAMAGES, SO THAT
50 // EXCLUSION AND LIMITATION MAY NOT APPLY TO YOU.
51 //
52 // These license terms shall be governed by and construed in accordance with
53 // the laws of the United States and the State of California as applied to
54 // agreements entered into and to be performed entirely within California
55 // between California residents.  Any litigation relating to these license
56 // terms shall be subject to the exclusive jurisdiction of the Federal Courts
57 // of the Northern District of California (or, absent subject matter
58 // jurisdiction in such courts, the courts of the State of California), with
59 // venue lying exclusively in Santa Clara County, California.
60 
61 // Copyright (c) 2001-2004, Hewlett-Packard Development Company, L.P.
62 //
63 // Permission is granted free of charge to copy, modify, use and distribute
64 // this software  provided you include the entirety of this notice in all
65 // copies made.
66 //
67 // THIS SOFTWARE IS PROVIDED ON AN AS IS BASIS, WITHOUT WARRANTY OF ANY
68 // KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, WITHOUT LIMITATION,
69 // WARRANTIES THAT THE SUBJECT SOFTWARE IS FREE OF DEFECTS, MERCHANTABLE, FIT
70 // FOR A PARTICULAR PURPOSE OR NON-INFRINGING.   HEWLETT-PACKARD ASSUMES
71 // NO RISK AS TO THE QUALITY AND PERFORMANCE OF THE SOFTWARE.
72 // SHOULD THE SOFTWARE PROVE DEFECTIVE IN ANY RESPECT,
73 // HEWLETT-PACKARD ASSUMES NO COST OR LIABILITY FOR ANY
74 // SERVICING, REPAIR OR CORRECTION.  THIS DISCLAIMER OF WARRANTY CONSTITUTES
75 // AN ESSENTIAL PART OF THIS LICENSE. NO USE OF ANY SUBJECT SOFTWARE IS
76 // AUTHORIZED HEREUNDER EXCEPT UNDER THIS DISCLAIMER.
77 //
78 // UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, WHETHER TORT (INCLUDING,
79 // WITHOUT LIMITATION, NEGLIGENCE OR STRICT LIABILITY), CONTRACT, OR
80 // OTHERWISE, SHALL HEWLETT-PACKARD BE LIABLE FOR ANY DIRECT, INDIRECT, SPECIAL,
81 // INCIDENTAL, OR CONSEQUENTIAL DAMAGES OF ANY CHARACTER WITH RESPECT TO THE
82 // SOFTWARE INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF GOODWILL, WORK
83 // STOPPAGE, LOSS OF DATA, COMPUTER FAILURE OR MALFUNCTION, OR ANY AND ALL
84 // OTHER COMMERCIAL DAMAGES OR LOSSES, EVEN IF HEWLETT-PACKARD SHALL
85 // HAVE BEEN INFORMED OF THE POSSIBILITY OF SUCH DAMAGES.
86 // THIS LIMITATION OF LIABILITY SHALL NOT APPLY TO LIABILITY RESULTING
87 // FROM HEWLETT-PACKARD's NEGLIGENCE TO THE EXTENT APPLICABLE
88 // LAW PROHIBITS SUCH LIMITATION.  SOME JURISDICTIONS DO NOT ALLOW THE
89 // EXCLUSION OR LIMITATION OF INCIDENTAL OR CONSEQUENTIAL DAMAGES, SO THAT
90 // EXCLUSION AND LIMITATION MAY NOT APPLY TO YOU.
91 //
92 
93 // Added valueOf(string, radix), fixed some documentation comments.
94 //              Hans_Boehm@hp.com 1/12/2001
95 // Fixed a serious typo in inv_CR():  For negative arguments it produced
96 //              the wrong sign.  This affected the sign of divisions.
97 // Added byteValue and fixed some comments.  Hans.Boehm@hp.com 12/17/2002
98 // Added toStringFloatRep.      Hans.Boehm@hp.com 4/1/2004
99 // Added get_appr() synchronization to allow access from multiple threads
100 // hboehm@google.com 4/25/2014
101 // Changed cos() prescaling to avoid logarithmic depth tree.
102 // hboehm@google.com 6/30/2014
103 // Added explicit asin() implementation.  Remove one.  Add ZERO and ONE and
104 // make them public.  hboehm@google.com 5/21/2015
105 
106 package com.hp.creals;
107 
108 import java.math.BigInteger;
109 
110 /**
111 * Constructive real numbers, also known as recursive, or computable reals.
112 * Each recursive real number is represented as an object that provides an
113 * approximation function for the real number.
114 * The approximation function guarantees that the generated approximation
115 * is accurate to the specified precision.
116 * Arithmetic operations on constructive reals produce new such objects;
117 * they typically do not perform any real computation.
118 * In this sense, arithmetic computations are exact: They produce
119 * a description which describes the exact answer, and can be used to
120 * later approximate it to arbitrary precision.
121 * <P>
122 * When approximations are generated, <I>e.g.</i> for output, they are
123 * accurate to the requested precision; no cumulative rounding errors
124 * are visible.
125 * In order to achieve this precision, the approximation function will often
126 * need to approximate subexpressions to greater precision than was originally
127 * demanded.  Thus the approximation of a constructive real number
128 * generated through a complex sequence of operations may eventually require
129 * evaluation to very high precision.  This usually makes such computations
130 * prohibitively expensive for large numerical problems.
131 * But it is perfectly appropriate for use in a desk calculator,
132 * for small numerical problems, for the evaluation of expressions
133 * computated by a symbolic algebra system, for testing of accuracy claims
134 * for floating point code on small inputs, or the like.
135 * <P>
136 * We expect that the vast majority of uses will ignore the particular
137 * implementation, and the member functons <TT>approximate</tt>
138 * and <TT>get_appr</tt>.  Such applications will treat <TT>CR</tt> as
139 * a conventional numerical type, with an interface modelled on
140 * <TT>java.math.BigInteger</tt>.  No subclasses of <TT>CR</tt>
141 * will be explicitly mentioned by such a program.
142 * <P>
143 * All standard arithmetic operations, as well as a few algebraic
144 * and transcendal functions are provided.  Constructive reals are
145 * immutable; thus all of these operations return a new constructive real.
146 * <P>
147 * A few uses will require explicit construction of approximation functions.
148 * The requires the construction of a subclass of <TT>CR</tt> with
149 * an overridden <TT>approximate</tt> function.  Note that <TT>approximate</tt>
150 * should only be defined, but never called.  <TT>get_appr</tt>
151 * provides the same functionality, but adds the caching necessary to obtain
152 * reasonable performance.
153 * <P>
154 * Any operation may throw <TT>com.hp.creals.AbortedException</tt> if the thread in
155 * which it is executing is interrupted.  (<TT>InterruptedException</tt> cannot
156 * be used for this purpose, since CR inherits from <TT>Number</tt>.)
157 * <P>
158 * Any operation may also throw <TT>com.hp.creals.PrecisionOverflowException</tt>
159 * If the precision request generated during any subcalculation overflows
160 * a 28-bit integer.  (This should be extremely unlikely, except as an
161 * outcome of a division by zero, or other erroneous computation.)
162 *
163 */
164 public abstract class CR extends Number {
165     // CR is the basic representation of a number.
166     // Abstractly this is a function for computing an approximation
167     // plus the current best approximation.
168     // We could do without the latter, but that would
169     // be atrociously slow.
170 
171 /**
172  * Indicates a constructive real operation was interrupted.
173  * Most constructive real operations may throw such an exception.
174  * This is unchecked, since Number methods may not raise checked
175  * exceptions.
176 */
177 public static class AbortedException extends RuntimeException {
AbortedException()178     public AbortedException() { super(); }
AbortedException(String s)179     public AbortedException(String s) { super(s); }
180 }
181 
182 /**
183  * Indicates that the number of bits of precision requested by
184  * a computation on constructive reals required more than 28 bits,
185  * and was thus in danger of overflowing an int.
186  * This is likely to be a symptom of a diverging computation,
187  * <I>e.g.</i> division by zero.
188 */
189 public static class PrecisionOverflowException extends RuntimeException {
PrecisionOverflowException()190     public PrecisionOverflowException() { super(); }
PrecisionOverflowException(String s)191     public PrecisionOverflowException(String s) { super(s); }
192 }
193 
194     // First some frequently used constants, so we don't have to
195     // recompute these all over the place.
196       static final BigInteger big0 = BigInteger.ZERO;
197       static final BigInteger big1 = BigInteger.ONE;
198       static final BigInteger bigm1 = BigInteger.valueOf(-1);
199       static final BigInteger big2 = BigInteger.valueOf(2);
200       static final BigInteger big3 = BigInteger.valueOf(3);
201       static final BigInteger big6 = BigInteger.valueOf(6);
202       static final BigInteger big8 = BigInteger.valueOf(8);
203       static final BigInteger big10 = BigInteger.TEN;
204       static final BigInteger big750 = BigInteger.valueOf(750);
205       static final BigInteger bigm750 = BigInteger.valueOf(-750);
206 
207 /**
208 * Setting this to true requests that  all computations be aborted by
209 * throwing AbortedException.  Must be rest to false before any further
210 * computation.  Ideally Thread.interrupt() should be used instead, but
211 * that doesn't appear to be consistently supported by browser VMs.
212 */
213 public volatile static boolean please_stop = false;
214 
215 /**
216 * Must be defined in subclasses of <TT>CR</tt>.
217 * Most users can ignore the existence of this method, and will
218 * not ever need to define a <TT>CR</tt> subclass.
219 * Returns value / 2 ** precision rounded to an integer.
220 * The error in the result is strictly < 1.
221 * Informally, approximate(n) gives a scaled approximation
222 * accurate to 2**n.
223 * Implementations may safely assume that precision is
224 * at least a factor of 8 away from overflow.
225 * Called only with the lock on the <TT>CR</tt> object
226 * already held.
227 */
approximate(int precision)228       protected abstract BigInteger approximate(int precision);
229       transient int min_prec;
230         // The smallest precision value with which the above
231         // has been called.
232       transient BigInteger max_appr;
233         // The scaled approximation corresponding to min_prec.
234       transient boolean appr_valid = false;
235         // min_prec and max_val are valid.
236 
237     // Helper functions
bound_log2(int n)238       static int bound_log2(int n) {
239         int abs_n = Math.abs(n);
240         return (int)Math.ceil(Math.log((double)(abs_n + 1))/Math.log(2.0));
241       }
242       // Check that a precision is at least a factor of 8 away from
243       // overflowng the integer used to hold a precision spec.
244       // We generally perform this check early on, and then convince
245       // ourselves that none of the operations performed on precisions
246       // inside a function can generate an overflow.
check_prec(int n)247       static void check_prec(int n) {
248         int high = n >> 28;
249         // if n is not in danger of overflowing, then the 4 high order
250         // bits should be identical.  Thus high is either 0 or -1.
251         // The rest of this is to test for either of those in a way
252         // that should be as cheap as possible.
253         int high_shifted = n >> 29;
254         if (0 != (high ^ high_shifted)) {
255             throw new PrecisionOverflowException();
256         }
257       }
258 
259 /**
260 * The constructive real number corresponding to a
261 * <TT>BigInteger</tt>.
262 */
valueOf(BigInteger n)263       public static CR valueOf(BigInteger n) {
264         return new int_CR(n);
265       }
266 
267 /**
268 * The constructive real number corresponding to a
269 * Java <TT>int</tt>.
270 */
valueOf(int n)271       public static CR valueOf(int n) {
272         return valueOf(BigInteger.valueOf(n));
273       }
274 
275 /**
276 * The constructive real number corresponding to a
277 * Java <TT>long</tt>.
278 */
valueOf(long n)279       public static CR valueOf(long n) {
280         return valueOf(BigInteger.valueOf(n));
281       }
282 
283 /**
284 * The constructive real number corresponding to a
285 * Java <TT>double</tt>.
286 * The result is undefined if argument is infinite or NaN.
287 */
valueOf(double n)288       public static CR valueOf(double n) {
289         if (Double.isNaN(n)) throw new ArithmeticException("Nan argument");
290         if (Double.isInfinite(n)) throw new ArithmeticException("Infinite argument");
291         boolean negative = (n < 0.0);
292         long bits = Double.doubleToLongBits(Math.abs(n));
293         long mantissa = (bits & 0xfffffffffffffL);
294         int biased_exp = (int)(bits >> 52);
295         int exp = biased_exp - 1075;
296         if (biased_exp != 0) {
297             mantissa += (1L << 52);
298         } else {
299             mantissa <<= 1;
300         }
301         CR result = valueOf(mantissa).shiftLeft(exp);
302         if (negative) result = result.negate();
303         return result;
304       }
305 
306 /**
307 * The constructive real number corresponding to a
308 * Java <TT>float</tt>.
309 * The result is undefined if argument is infinite or NaN.
310 */
valueOf(float n)311       public static CR valueOf(float n) {
312         return valueOf((double) n);
313       }
314 
315       public static CR ZERO = valueOf(0);
316       public static CR ONE = valueOf(1);
317 
318     // Multiply k by 2**n.
shift(BigInteger k, int n)319       static BigInteger shift(BigInteger k, int n) {
320         if (n == 0) return k;
321         if (n < 0) return k.shiftRight(-n);
322         return k.shiftLeft(n);
323       }
324 
325     // Multiply by 2**n, rounding result
scale(BigInteger k, int n)326       static BigInteger scale(BigInteger k, int n) {
327         if (n >= 0) {
328             return k.shiftLeft(n);
329         } else {
330             BigInteger adj_k = shift(k, n+1).add(big1);
331             return adj_k.shiftRight(1);
332         }
333       }
334 
335     // Identical to approximate(), but maintain and update cache.
336 /**
337 * Returns value / 2 ** prec rounded to an integer.
338 * The error in the result is strictly < 1.
339 * Produces the same answer as <TT>approximate</tt>, but uses and
340 * maintains a cached approximation.
341 * Normally not overridden, and called only from <TT>approximate</tt>
342 * methods in subclasses.  Not needed if the provided operations
343 * on constructive reals suffice.
344 */
get_appr(int precision)345       public synchronized BigInteger get_appr(int precision) {
346         check_prec(precision);
347         if (appr_valid && precision >= min_prec) {
348             return scale(max_appr, min_prec - precision);
349         } else {
350             BigInteger result = approximate(precision);
351             min_prec = precision;
352             max_appr = result;
353             appr_valid = true;
354             return result;
355         }
356       }
357 
358     // Return the position of the msd.
359     // If x.msd() == n then
360     // 2**(n-1) < abs(x) < 2**(n+1)
361     // This initial version assumes that max_appr is valid
362     // and sufficiently removed from zero
363     // that the msd is determined.
known_msd()364       int known_msd() {
365         int first_digit;
366         int length;
367         if (max_appr.signum() >= 0) {
368             length = max_appr.bitLength();
369         } else {
370             length = max_appr.negate().bitLength();
371         }
372         first_digit = min_prec + length - 1;
373         return first_digit;
374       }
375 
376     // This version may return Integer.MIN_VALUE if the correct
377     // answer is < n.
msd(int n)378       int msd(int n) {
379         if (!appr_valid ||
380                 max_appr.compareTo(big1) <= 0
381                 && max_appr.compareTo(bigm1) >= 0) {
382             get_appr(n - 1);
383             if (max_appr.abs().compareTo(big1) <= 0) {
384                 // msd could still be arbitrarily far to the right.
385                 return Integer.MIN_VALUE;
386             }
387         }
388         return known_msd();
389       }
390 
391 
392     // Functionally equivalent, but iteratively evaluates to higher
393     // precision.
iter_msd(int n)394       int iter_msd(int n)
395       {
396         int prec = 0;
397 
398         for (;prec > n + 30; prec = (prec * 3)/2 - 16) {
399             int msd = msd(prec);
400             if (msd != Integer.MIN_VALUE) return msd;
401             check_prec(prec);
402             if (Thread.interrupted() || please_stop) throw new AbortedException();
403         }
404         return msd(n);
405       }
406 
407     // This version returns a correct answer eventually, except
408     // that it loops forever (or throws an exception when the
409     // requested precision overflows) if this constructive real is zero.
msd()410       int msd() {
411           return iter_msd(Integer.MIN_VALUE);
412       }
413 
414     // A helper function for toString.
415     // Generate a String containing n zeroes.
zeroes(int n)416       private static String zeroes(int n) {
417         char[] a = new char[n];
418         for (int i = 0; i < n; ++i) {
419             a[i] = '0';
420         }
421         return new String(a);
422       }
423 
424     // Natural log of 2.  Needed for some prescaling below.
425     // ln(2) = 7ln(10/9) - 2ln(25/24) + 3ln(81/80)
simple_ln()426         CR simple_ln() {
427             return new prescaled_ln_CR(this.subtract(ONE));
428         }
429         static CR ten_ninths = valueOf(10).divide(valueOf(9));
430         static CR twentyfive_twentyfourths = valueOf(25).divide(valueOf(24));
431         static CR eightyone_eightyeths = valueOf(81).divide(valueOf(80));
432         static CR ln2_1 = valueOf(7).multiply(ten_ninths.simple_ln());
433         static CR ln2_2 =
434                 valueOf(2).multiply(twentyfive_twentyfourths.simple_ln());
435         static CR ln2_3 = valueOf(3).multiply(eightyone_eightyeths.simple_ln());
436         static CR ln2 = ln2_1.subtract(ln2_2).add(ln2_3);
437 
438     // Atan of integer reciprocal.  Used for PI.  Could perhaps
439     // be made public.
atan_reciprocal(int n)440         static CR atan_reciprocal(int n) {
441             return new integral_atan_CR(n);
442         }
443     // Other constants used for PI computation.
444         static CR four = valueOf(4);
445 
446   // Public operations.
447 /**
448 * Return 0 if x = y to within the indicated tolerance,
449 * -1 if x < y, and +1 if x > y.  If x and y are indeed
450 * equal, it is guaranteed that 0 will be returned.  If
451 * they differ by less than the tolerance, anything
452 * may happen.  The tolerance allowed is
453 * the maximum of (abs(this)+abs(x))*(2**r) and 2**a
454 *       @param x        The other constructive real
455 *       @param r        Relative tolerance in bits
456 *       @param a        Absolute tolerance in bits
457 */
compareTo(CR x, int r, int a)458       public int compareTo(CR x, int r, int a) {
459         int this_msd = iter_msd(a);
460         int x_msd = x.iter_msd(this_msd > a? this_msd : a);
461         int max_msd = (x_msd > this_msd? x_msd : this_msd);
462         int rel = max_msd + r;
463             // This can't approach overflow, since r and a are
464             // effectively divided by 2, and msds are checked.
465         int abs_prec = (rel > a? rel : a);
466         return compareTo(x, abs_prec);
467       }
468 
469 /**
470 * Approximate comparison with only an absolute tolerance.
471 * Identical to the three argument version, but without a relative
472 * tolerance.
473 * Result is 0 if both constructive reals are equal, indeterminate
474 * if they differ by less than 2**a.
475 *
476 *       @param x        The other constructive real
477 *       @param a        Absolute tolerance in bits
478 */
compareTo(CR x, int a)479       public int compareTo(CR x, int a) {
480         int needed_prec = a - 1;
481         BigInteger this_appr = get_appr(needed_prec);
482         BigInteger x_appr = x.get_appr(needed_prec);
483         int comp1 = this_appr.compareTo(x_appr.add(big1));
484         if (comp1 > 0) return 1;
485         int comp2 = this_appr.compareTo(x_appr.subtract(big1));
486         if (comp2 < 0) return -1;
487         return 0;
488       }
489 
490 /**
491 * Return -1 if <TT>this &lt; x</tt>, or +1 if <TT>this &gt; x</tt>.
492 * Should be called only if <TT>this != x</tt>.
493 * If <TT>this == x</tt>, this will not terminate correctly; typically it
494 * will run until it exhausts memory.
495 * If the two constructive reals may be equal, the two or 3 argument
496 * version of compareTo should be used.
497 */
compareTo(CR x)498       public int compareTo(CR x) {
499         for (int a = -20; ; a *= 2) {
500             check_prec(a);
501             int result = compareTo(x, a);
502             if (0 != result) return result;
503         }
504       }
505 
506 /**
507 * Equivalent to <TT>compareTo(CR.valueOf(0), a)</tt>
508 */
signum(int a)509       public int signum(int a) {
510         if (appr_valid) {
511             int quick_try = max_appr.signum();
512             if (0 != quick_try) return quick_try;
513         }
514         int needed_prec = a - 1;
515         BigInteger this_appr = get_appr(needed_prec);
516         return this_appr.signum();
517       }
518 
519 /**
520 * Return -1 if negative, +1 if positive.
521 * Should be called only if <TT>this != 0</tt>.
522 * In the 0 case, this will not terminate correctly; typically it
523 * will run until it exhausts memory.
524 * If the two constructive reals may be equal, the one or two argument
525 * version of signum should be used.
526 */
signum()527       public int signum() {
528         for (int a = -20; ; a *= 2) {
529             check_prec(a);
530             int result = signum(a);
531             if (0 != result) return result;
532         }
533       }
534 
535 /**
536 * Return the constructive real number corresponding to the given
537 * textual representation and radix.
538 *
539 *       @param s        [-] digit* [. digit*]
540 *       @param radix
541 */
542 
valueOf(String s, int radix)543       public static CR valueOf(String s, int radix)
544              throws NumberFormatException {
545           int len = s.length();
546           int start_pos = 0, point_pos;
547           String fraction;
548           while (s.charAt(start_pos) == ' ') ++start_pos;
549           while (s.charAt(len - 1) == ' ') --len;
550           point_pos = s.indexOf('.', start_pos);
551           if (point_pos == -1) {
552               point_pos = len;
553               fraction = "0";
554           } else {
555               fraction = s.substring(point_pos + 1, len);
556           }
557           String whole = s.substring(start_pos, point_pos);
558           BigInteger scaled_result = new BigInteger(whole + fraction, radix);
559           BigInteger divisor = BigInteger.valueOf(radix).pow(fraction.length());
560           return CR.valueOf(scaled_result).divide(CR.valueOf(divisor));
561       }
562 
563 /**
564 * Return a textual representation accurate to <TT>n</tt> places
565 * to the right of the decimal point.  <TT>n</tt> must be nonnegative.
566 *
567 *       @param  n       Number of digits (>= 0) included to the right of decimal point
568 *       @param  radix   Base ( >= 2, <= 16) for the resulting representation.
569 */
toString(int n, int radix)570       public String toString(int n, int radix) {
571           CR scaled_CR;
572           if (16 == radix) {
573             scaled_CR = shiftLeft(4*n);
574           } else {
575             BigInteger scale_factor = BigInteger.valueOf(radix).pow(n);
576             scaled_CR = multiply(new int_CR(scale_factor));
577           }
578           BigInteger scaled_int = scaled_CR.get_appr(0);
579           String scaled_string = scaled_int.abs().toString(radix);
580           String result;
581           if (0 == n) {
582               result = scaled_string;
583           } else {
584               int len = scaled_string.length();
585               if (len <= n) {
586                 // Add sufficient leading zeroes
587                   String z = zeroes(n + 1 - len);
588                   scaled_string = z + scaled_string;
589                   len = n + 1;
590               }
591               String whole = scaled_string.substring(0, len - n);
592               String fraction = scaled_string.substring(len - n);
593               result = whole + "." + fraction;
594           }
595           if (scaled_int.signum() < 0) {
596               result = "-" + result;
597           }
598           return result;
599       }
600 
601 
602 /**
603 * Equivalent to <TT>toString(n,10)</tt>
604 *
605 *       @param  n       Number of digits included to the right of decimal point
606 */
toString(int n)607     public String toString(int n) {
608         return toString(n, 10);
609     }
610 
611 /**
612 * Equivalent to <TT>toString(10, 10)</tt>
613 */
toString()614     public String toString() {
615         return toString(10);
616     }
617 
618     static double doubleLog2 = Math.log(2.0);
619 /**
620 * Return a textual scientific notation representation accurate
621 * to <TT>n</tt> places to the right of the decimal point.
622 * <TT>n</tt> must be nonnegative.  A value smaller than
623 * <TT>radix</tt>**-<TT>m</tt> may be displayed as 0.
624 * The <TT>mantissa</tt> component of the result is either "0"
625 * or exactly <TT>n</tt> digits long.  The <TT>sign</tt>
626 * component is zero exactly when the mantissa is "0".
627 *
628 *       @param  n       Number of digits (&gt; 0) included to the right of decimal point.
629 *       @param  radix   Base ( &ge; 2, &le; 16) for the resulting representation.
630 *       @param  m       Precision used to distinguish number from zero.
631 *                       Expressed as a power of m.
632 */
toStringFloatRep(int n, int radix, int m)633     public StringFloatRep toStringFloatRep(int n, int radix, int m) {
634         if (n <= 0) throw new ArithmeticException("Bad precision argument");
635         double log2_radix = Math.log((double)radix)/doubleLog2;
636         BigInteger big_radix = BigInteger.valueOf(radix);
637         long long_msd_prec = (long)(log2_radix * (double)m);
638         if (long_msd_prec > (long)Integer.MAX_VALUE
639             || long_msd_prec < (long)Integer.MIN_VALUE)
640             throw new PrecisionOverflowException();
641         int msd_prec = (int)long_msd_prec;
642         check_prec(msd_prec);
643         int msd = iter_msd(msd_prec - 2);
644         if (msd == Integer.MIN_VALUE)
645             return new StringFloatRep(0, "0", radix, 0);
646         int exponent = (int)Math.ceil((double)msd / log2_radix);
647                 // Guess for the exponent.  Try to get it usually right.
648         int scale_exp = exponent - n;
649         CR scale;
650         if (scale_exp > 0) {
651             scale = CR.valueOf(big_radix.pow(scale_exp)).inverse();
652         } else {
653             scale = CR.valueOf(big_radix.pow(-scale_exp));
654         }
655         CR scaled_res = multiply(scale);
656         BigInteger scaled_int = scaled_res.get_appr(0);
657         int sign = scaled_int.signum();
658         String scaled_string = scaled_int.abs().toString(radix);
659         while (scaled_string.length() < n) {
660             // exponent was too large.  Adjust.
661             scaled_res = scaled_res.multiply(CR.valueOf(big_radix));
662             exponent -= 1;
663             scaled_int = scaled_res.get_appr(0);
664             sign = scaled_int.signum();
665             scaled_string = scaled_int.abs().toString(radix);
666         }
667         if (scaled_string.length() > n) {
668             // exponent was too small.  Adjust by truncating.
669             exponent += (scaled_string.length() - n);
670             scaled_string = scaled_string.substring(0, n);
671         }
672         return new StringFloatRep(sign, scaled_string, radix, exponent);
673     }
674 
675 /**
676 * Return a BigInteger which differs by less than one from the
677 * constructive real.
678 */
BigIntegerValue()679     public BigInteger BigIntegerValue() {
680         return get_appr(0);
681     }
682 
683 /**
684 * Return an int which differs by less than one from the
685 * constructive real.  Behavior on overflow is undefined.
686 */
intValue()687     public int intValue() {
688         return BigIntegerValue().intValue();
689     }
690 
691 /**
692 * Return an int which differs by less than one from the
693 * constructive real.  Behavior on overflow is undefined.
694 */
byteValue()695     public byte byteValue() {
696         return BigIntegerValue().byteValue();
697     }
698 
699 /**
700 * Return a long which differs by less than one from the
701 * constructive real.  Behavior on overflow is undefined.
702 */
longValue()703     public long longValue() {
704         return BigIntegerValue().longValue();
705     }
706 
707 /**
708 * Return a double which differs by less than one in the least
709 * represented bit from the constructive real.
710 */
doubleValue()711     public double doubleValue() {
712         int my_msd = iter_msd(-1080 /* slightly > exp. range */);
713         if (Integer.MIN_VALUE == my_msd) return 0.0;
714         int needed_prec = my_msd - 60;
715         double scaled_int = get_appr(needed_prec).doubleValue();
716         boolean may_underflow = (needed_prec < -1000);
717         long scaled_int_rep = Double.doubleToLongBits(scaled_int);
718         long exp_adj = may_underflow? needed_prec + 96 : needed_prec;
719         long orig_exp = (scaled_int_rep >> 52) & 0x7ff;
720         if (((orig_exp + exp_adj) & ~0x7ff) != 0) {
721             // overflow
722             if (scaled_int < 0.0) {
723                 return Double.NEGATIVE_INFINITY;
724             } else {
725                 return Double.POSITIVE_INFINITY;
726             }
727         }
728         scaled_int_rep += exp_adj << 52;
729         double result = Double.longBitsToDouble(scaled_int_rep);
730         if (may_underflow) {
731             double two48 = (double)(1 << 48);
732             return result/two48/two48;
733         } else {
734             return result;
735         }
736     }
737 
738 /**
739 * Return a float which differs by less than one in the least
740 * represented bit from the constructive real.
741 */
floatValue()742     public float floatValue() {
743         return (float)doubleValue();
744     }
745 
746 /**
747 * Add two constructive reals.
748 */
add(CR x)749     public CR add(CR x) {
750         return new add_CR(this, x);
751     }
752 
753 /**
754 * Multiply a constructive real by 2**n.
755 * @param n      shift count, may be negative
756 */
shiftLeft(int n)757     public CR shiftLeft(int n) {
758         check_prec(n);
759         return new shifted_CR(this, n);
760     }
761 
762 /**
763 * Multiply a constructive real by 2**(-n).
764 * @param n      shift count, may be negative
765 */
shiftRight(int n)766     public CR shiftRight(int n) {
767         check_prec(n);
768         return new shifted_CR(this, -n);
769     }
770 
771 /**
772 * Produce a constructive real equivalent to the original, assuming
773 * the original was an integer.  Undefined results if the original
774 * was not an integer.  Prevents evaluation of digits to the right
775 * of the decimal point, and may thus improve performance.
776 */
assumeInt()777     public CR assumeInt() {
778         return new assumed_int_CR(this);
779     }
780 
781 /**
782 * The additive inverse of a constructive real
783 */
negate()784     public CR negate() {
785         return new neg_CR(this);
786     }
787 
788 /**
789 * The difference between two constructive reals
790 */
subtract(CR x)791     public CR subtract(CR x) {
792         return new add_CR(this, x.negate());
793     }
794 
795 /**
796 * The product of two constructive reals
797 */
multiply(CR x)798     public CR multiply(CR x) {
799         return new mult_CR(this, x);
800     }
801 
802 /**
803 * The multiplicative inverse of a constructive real.
804 * <TT>x.inverse()</tt> is equivalent to <TT>CR.valueOf(1).divide(x)</tt>.
805 */
inverse()806     public CR inverse() {
807         return new inv_CR(this);
808     }
809 
810 /**
811 * The quotient of two constructive reals.
812 */
divide(CR x)813     public CR divide(CR x) {
814         return new mult_CR(this, x.inverse());
815     }
816 
817 /**
818 * The real number <TT>x</tt> if <TT>this</tt> < 0, or <TT>y</tt> otherwise.
819 * Requires <TT>x</tt> = <TT>y</tt> if <TT>this</tt> = 0.
820 * Since comparisons may diverge, this is often
821 * a useful alternative to conditionals.
822 */
select(CR x, CR y)823     public CR select(CR x, CR y) {
824         return new select_CR(this, x, y);
825     }
826 
827 /**
828 * The maximum of two constructive reals.
829 */
max(CR x)830     public CR max(CR x) {
831         return subtract(x).select(x, this);
832     }
833 
834 /**
835 * The minimum of two constructive reals.
836 */
min(CR x)837     public CR min(CR x) {
838         return subtract(x).select(this, x);
839     }
840 
841 /**
842 * The absolute value of a constructive reals.
843 * Note that this cannot be written as a conditional.
844 */
abs()845     public CR abs() {
846         return select(negate(), this);
847     }
848 
849 /**
850 * The exponential function, that is e**<TT>this</tt>.
851 */
exp()852     public CR exp() {
853         final int low_prec = -10;
854         BigInteger rough_appr = get_appr(low_prec);
855         if (rough_appr.signum() < 0) return negate().exp().inverse();
856         if (rough_appr.compareTo(big2) > 0) {
857             CR square_root = shiftRight(1).exp();
858             return square_root.multiply(square_root);
859         } else {
860             return new prescaled_exp_CR(this);
861         }
862     }
863 
864     static CR two = valueOf(2);
865 
866 /**
867 * The ratio of a circle's circumference to its diameter.
868 */
869     public static CR PI = four.multiply(four.multiply(atan_reciprocal(5))
870                                             .subtract(atan_reciprocal(239)));
871         // pi/4 = 4*atan(1/5) - atan(1/239)
872     static CR half_pi = PI.shiftRight(1);
873 
874 /**
875 * The trigonometric cosine function.
876 */
cos()877     public CR cos() {
878         BigInteger halfpi_multiples = divide(PI).get_appr(-1);
879         BigInteger abs_halfpi_multiples = halfpi_multiples.abs();
880         if (abs_halfpi_multiples.compareTo(big2) >= 0) {
881             // Subtract multiples of PI
882             BigInteger pi_multiples = scale(halfpi_multiples, -1);
883             CR adjustment = PI.multiply(CR.valueOf(pi_multiples));
884             if (pi_multiples.and(big1).signum() != 0) {
885                 return subtract(adjustment).cos().negate();
886             } else {
887                 return subtract(adjustment).cos();
888             }
889         } else if (get_appr(-1).abs().compareTo(big2) >= 0) {
890             // Scale further with double angle formula
891             CR cos_half = shiftRight(1).cos();
892             return cos_half.multiply(cos_half).shiftLeft(1).subtract(ONE);
893         } else {
894             return new prescaled_cos_CR(this);
895         }
896     }
897 
898 /**
899 * The trigonometric sine function.
900 */
sin()901     public CR sin() {
902         return half_pi.subtract(this).cos();
903     }
904 
905 /**
906 * The trignonometric arc (inverse) sine function.
907 */
asin()908     public CR asin() {
909         BigInteger rough_appr = get_appr(-10);
910         if (rough_appr.compareTo(big750) /* 1/sqrt(2) + a bit */ > 0){
911             CR new_arg = ONE.subtract(multiply(this)).sqrt();
912             return new_arg.acos();
913         } else if (rough_appr.compareTo(bigm750) < 0) {
914             return negate().asin().negate();
915         } else {
916             return new prescaled_asin_CR(this);
917         }
918     }
919 
920 /**
921 * The trignonometric arc (inverse) cosine function.
922 */
acos()923     public CR acos() {
924         return half_pi.subtract(asin());
925     }
926 
927     static final BigInteger low_ln_limit = big8; /* sixteenths, i.e. 1/2 */
928     static final BigInteger high_ln_limit =
929                         BigInteger.valueOf(16 + 8 /* 1.5 */);
930     static final BigInteger scaled_4 =
931                         BigInteger.valueOf(4*16);
932 
933 /**
934 * The natural (base e) logarithm.
935 */
ln()936     public CR ln() {
937         final int low_prec = -4;
938         BigInteger rough_appr = get_appr(low_prec); /* In sixteenths */
939         if (rough_appr.compareTo(big0) < 0) {
940             throw new ArithmeticException("ln(negative)");
941         }
942         if (rough_appr.compareTo(low_ln_limit) <= 0) {
943             return inverse().ln().negate();
944         }
945         if (rough_appr.compareTo(high_ln_limit) >= 0) {
946             if (rough_appr.compareTo(scaled_4) <= 0) {
947                 CR quarter = sqrt().sqrt().ln();
948                 return quarter.shiftLeft(2);
949             } else {
950                 int extra_bits = rough_appr.bitLength() - 3;
951                 CR scaled_result = shiftRight(extra_bits).ln();
952                 return scaled_result.add(CR.valueOf(extra_bits).multiply(ln2));
953             }
954         }
955         return simple_ln();
956     }
957 
958 /**
959 * The square root of a constructive real.
960 */
sqrt()961     public CR sqrt() {
962         return new sqrt_CR(this);
963     }
964 
965 }  // end of CR
966 
967 
968 //
969 // A specialization of CR for cases in which approximate() calls
970 // to increase evaluation precision are somewhat expensive.
971 // If we need to (re)evaluate, we speculatively evaluate to slightly
972 // higher precision, miminimizing reevaluations.
973 // Note that this requires any arguments to be evaluated to higher
974 // precision than absolutely necessary.  It can thus potentially
975 // result in lots of wasted effort, and should be used judiciously.
976 // This assumes that the order of magnitude of the number is roughly one.
977 //
978 abstract class slow_CR extends CR {
979     static int max_prec = -64;
980     static int prec_incr = 32;
get_appr(int precision)981     public synchronized BigInteger get_appr(int precision) {
982         check_prec(precision);
983         if (appr_valid && precision >= min_prec) {
984             return scale(max_appr, min_prec - precision);
985         } else {
986             int eval_prec = (precision >= max_prec? max_prec :
987                              (precision - prec_incr + 1) & ~(prec_incr - 1));
988             BigInteger result = approximate(eval_prec);
989             min_prec = eval_prec;
990             max_appr = result;
991             appr_valid = true;
992             return scale(result, eval_prec - precision);
993         }
994     }
995 }
996 
997 
998 // Representation of an integer constant.  Private.
999 class int_CR extends CR {
1000     BigInteger value;
int_CR(BigInteger n)1001     int_CR(BigInteger n) {
1002         value = n;
1003     }
approximate(int p)1004     protected BigInteger approximate(int p) {
1005         return scale(value, -p) ;
1006     }
1007 }
1008 
1009 // Representation of a number that may not have been completely
1010 // evaluated, but is assumed to be an integer.  Hence we never
1011 // evaluate beyond the decimal point.
1012 class assumed_int_CR extends CR {
1013     CR value;
assumed_int_CR(CR x)1014     assumed_int_CR(CR x) {
1015         value = x;
1016     }
approximate(int p)1017     protected BigInteger approximate(int p) {
1018         if (p >= 0) {
1019             return value.get_appr(p);
1020         } else {
1021             return scale(value.get_appr(0), -p) ;
1022         }
1023     }
1024 }
1025 
1026 // Representation of the sum of 2 constructive reals.  Private.
1027 class add_CR extends CR {
1028     CR op1;
1029     CR op2;
add_CR(CR x, CR y)1030     add_CR(CR x, CR y) {
1031         op1 = x;
1032         op2 = y;
1033     }
approximate(int p)1034     protected BigInteger approximate(int p) {
1035         // Args need to be evaluated so that each error is < 1/4 ulp.
1036         // Rounding error from the cale call is <= 1/2 ulp, so that
1037         // final error is < 1 ulp.
1038         return scale(op1.get_appr(p-2).add(op2.get_appr(p-2)), -2);
1039     }
1040 }
1041 
1042 // Representation of a CR multiplied by 2**n
1043 class shifted_CR extends CR {
1044     CR op;
1045     int count;
shifted_CR(CR x, int n)1046     shifted_CR(CR x, int n) {
1047         op = x;
1048         count = n;
1049     }
approximate(int p)1050     protected BigInteger approximate(int p) {
1051         return op.get_appr(p - count);
1052     }
1053 }
1054 
1055 // Representation of the negation of a constructive real.  Private.
1056 class neg_CR extends CR {
1057     CR op;
neg_CR(CR x)1058     neg_CR(CR x) {
1059         op = x;
1060     }
approximate(int p)1061     protected BigInteger approximate(int p) {
1062         return op.get_appr(p).negate();
1063     }
1064 }
1065 
1066 // Representation of:
1067 //      op1     if selector < 0
1068 //      op2     if selector >= 0
1069 // Assumes x = y if s = 0
1070 class select_CR extends CR {
1071     CR selector;
1072     int selector_sign;
1073     CR op1;
1074     CR op2;
select_CR(CR s, CR x, CR y)1075     select_CR(CR s, CR x, CR y) {
1076         selector = s;
1077         int selector_sign = selector.get_appr(-20).signum();
1078         op1 = x;
1079         op2 = y;
1080     }
approximate(int p)1081     protected BigInteger approximate(int p) {
1082         if (selector_sign < 0) return op1.get_appr(p);
1083         if (selector_sign > 0) return op2.get_appr(p);
1084         BigInteger op1_appr = op1.get_appr(p-1);
1085         BigInteger op2_appr = op2.get_appr(p-1);
1086         BigInteger diff = op1_appr.subtract(op2_appr).abs();
1087         if (diff.compareTo(big1) <= 0) {
1088             // close enough; use either
1089             return scale(op1_appr, -1);
1090         }
1091         // op1 and op2 are different; selector != 0;
1092         // safe to get sign of selector.
1093         if (selector.signum() < 0) {
1094             selector_sign = -1;
1095             return scale(op1_appr, -1);
1096         } else {
1097             selector_sign = 1;
1098             return scale(op2_appr, -1);
1099         }
1100     }
1101 }
1102 
1103 // Representation of the product of 2 constructive reals. Private.
1104 class mult_CR extends CR {
1105     CR op1;
1106     CR op2;
mult_CR(CR x, CR y)1107     mult_CR(CR x, CR y) {
1108         op1 = x;
1109         op2 = y;
1110     }
approximate(int p)1111     protected BigInteger approximate(int p) {
1112         int half_prec = (p >> 1) - 1;
1113         int msd_op1 = op1.msd(half_prec);
1114         int msd_op2;
1115 
1116         if (msd_op1 == Integer.MIN_VALUE) {
1117             msd_op2 = op2.msd(half_prec);
1118             if (msd_op2 == Integer.MIN_VALUE) {
1119                 // Product is small enough that zero will do as an
1120                 // approximation.
1121                 return big0;
1122             } else {
1123                 // Swap them, so the larger operand (in absolute value)
1124                 // is first.
1125                 CR tmp;
1126                 tmp = op1;
1127                 op1 = op2;
1128                 op2 = tmp;
1129                 msd_op1 = msd_op2;
1130             }
1131         }
1132         // msd_op1 is valid at this point.
1133         int prec2 = p - msd_op1 - 3;    // Precision needed for op2.
1134                 // The appr. error is multiplied by at most
1135                 // 2 ** (msd_op1 + 1)
1136                 // Thus each approximation contributes 1/4 ulp
1137                 // to the rounding error, and the final rounding adds
1138                 // another 1/2 ulp.
1139         BigInteger appr2 = op2.get_appr(prec2);
1140         if (appr2.signum() == 0) return big0;
1141         msd_op2 = op2.known_msd();
1142         int prec1 = p - msd_op2 - 3;    // Precision needed for op1.
1143         BigInteger appr1 = op1.get_appr(prec1);
1144         int scale_digits =  prec1 + prec2 - p;
1145         return scale(appr1.multiply(appr2), scale_digits);
1146     }
1147 }
1148 
1149 // Representation of the multiplicative inverse of a constructive
1150 // real.  Private.  Should use Newton iteration to refine estimates.
1151 class inv_CR extends CR {
1152     CR op;
inv_CR(CR x)1153     inv_CR(CR x) { op = x; }
approximate(int p)1154     protected BigInteger approximate(int p) {
1155         int msd = op.msd();
1156         int inv_msd = 1 - msd;
1157         int digits_needed = inv_msd - p + 3;
1158                                 // Number of SIGNIFICANT digits needed for
1159                                 // argument, excl. msd position, which may
1160                                 // be fictitious, since msd routine can be
1161                                 // off by 1.  Roughly 1 extra digit is
1162                                 // needed since the relative error is the
1163                                 // same in the argument and result, but
1164                                 // this isn't quite the same as the number
1165                                 // of significant digits.  Another digit
1166                                 // is needed to compensate for slop in the
1167                                 // calculation.
1168                                 // One further bit is required, since the
1169                                 // final rounding introduces a 0.5 ulp
1170                                 // error.
1171         int prec_needed = msd - digits_needed;
1172         int log_scale_factor = -p - prec_needed;
1173         if (log_scale_factor < 0) return big0;
1174         BigInteger dividend = big1.shiftLeft(log_scale_factor);
1175         BigInteger scaled_divisor = op.get_appr(prec_needed);
1176         BigInteger abs_scaled_divisor = scaled_divisor.abs();
1177         BigInteger adj_dividend = dividend.add(
1178                                         abs_scaled_divisor.shiftRight(1));
1179                 // Adjustment so that final result is rounded.
1180         BigInteger result = adj_dividend.divide(abs_scaled_divisor);
1181         if (scaled_divisor.signum() < 0) {
1182           return result.negate();
1183         } else {
1184           return result;
1185         }
1186     }
1187 }
1188 
1189 
1190 // Representation of the exponential of a constructive real.  Private.
1191 // Uses a Taylor series expansion.  Assumes x < 1/2.
1192 // Note: this is known to be a bad algorithm for
1193 // floating point.  Unfortunately, other alternatives
1194 // appear to require precomputed information.
1195 class prescaled_exp_CR extends CR {
1196     CR op;
prescaled_exp_CR(CR x)1197     prescaled_exp_CR(CR x) { op = x; }
approximate(int p)1198     protected BigInteger approximate(int p) {
1199         if (p >= 1) return big0;
1200         int iterations_needed = -p/2 + 2;  // conservative estimate > 0.
1201           //  Claim: each intermediate term is accurate
1202           //  to 2*2^calc_precision.
1203           //  Total rounding error in series computation is
1204           //  2*iterations_needed*2^calc_precision,
1205           //  exclusive of error in op.
1206         int calc_precision = p - bound_log2(2*iterations_needed)
1207                                - 4; // for error in op, truncation.
1208         int op_prec = p - 3;
1209         BigInteger op_appr = op.get_appr(op_prec);
1210           // Error in argument results in error of < 3/8 ulp.
1211           // Sum of term eval. rounding error is < 1/16 ulp.
1212           // Series truncation error < 1/16 ulp.
1213           // Final rounding error is <= 1/2 ulp.
1214           // Thus final error is < 1 ulp.
1215         BigInteger scaled_1 = big1.shiftLeft(-calc_precision);
1216         BigInteger current_term = scaled_1;
1217         BigInteger current_sum = scaled_1;
1218         int n = 0;
1219         BigInteger max_trunc_error =
1220                 big1.shiftLeft(p - 4 - calc_precision);
1221         while (current_term.abs().compareTo(max_trunc_error) >= 0) {
1222           if (Thread.interrupted() || please_stop) throw new AbortedException();
1223           n += 1;
1224           /* current_term = current_term * op / n */
1225           current_term = scale(current_term.multiply(op_appr), op_prec);
1226           current_term = current_term.divide(BigInteger.valueOf(n));
1227           current_sum = current_sum.add(current_term);
1228         }
1229         return scale(current_sum, calc_precision - p);
1230     }
1231 }
1232 
1233 // Representation of the cosine of a constructive real.  Private.
1234 // Uses a Taylor series expansion.  Assumes |x| < 1.
1235 class prescaled_cos_CR extends slow_CR {
1236     CR op;
prescaled_cos_CR(CR x)1237     prescaled_cos_CR(CR x) {
1238         op = x;
1239     }
approximate(int p)1240     protected BigInteger approximate(int p) {
1241         if (p >= 1) return big0;
1242         int iterations_needed = -p/2 + 4;  // conservative estimate > 0.
1243           //  Claim: each intermediate term is accurate
1244           //  to 2*2^calc_precision.
1245           //  Total rounding error in series computation is
1246           //  2*iterations_needed*2^calc_precision,
1247           //  exclusive of error in op.
1248         int calc_precision = p - bound_log2(2*iterations_needed)
1249                                - 4; // for error in op, truncation.
1250         int op_prec = p - 2;
1251         BigInteger op_appr = op.get_appr(op_prec);
1252           // Error in argument results in error of < 1/4 ulp.
1253           // Cumulative arithmetic rounding error is < 1/16 ulp.
1254           // Series truncation error < 1/16 ulp.
1255           // Final rounding error is <= 1/2 ulp.
1256           // Thus final error is < 1 ulp.
1257         BigInteger current_term;
1258         int n;
1259         BigInteger max_trunc_error =
1260                 big1.shiftLeft(p - 4 - calc_precision);
1261         n = 0;
1262         current_term = big1.shiftLeft(-calc_precision);
1263         BigInteger current_sum = current_term;
1264         while (current_term.abs().compareTo(max_trunc_error) >= 0) {
1265           if (Thread.interrupted() || please_stop) throw new AbortedException();
1266           n += 2;
1267           /* current_term = - current_term * op * op / n * (n - 1)   */
1268           current_term = scale(current_term.multiply(op_appr), op_prec);
1269           current_term = scale(current_term.multiply(op_appr), op_prec);
1270           BigInteger divisor = BigInteger.valueOf(-n)
1271                                   .multiply(BigInteger.valueOf(n-1));
1272           current_term = current_term.divide(divisor);
1273           current_sum = current_sum.add(current_term);
1274         }
1275         return scale(current_sum, calc_precision - p);
1276     }
1277 }
1278 
1279 // The constructive real atan(1/n), where n is a small integer
1280 // > base.
1281 // This gives a simple and moderately fast way to compute PI.
1282 class integral_atan_CR extends slow_CR {
1283     int op;
integral_atan_CR(int x)1284     integral_atan_CR(int x) { op = x; }
approximate(int p)1285     protected BigInteger approximate(int p) {
1286         if (p >= 1) return big0;
1287         int iterations_needed = -p/2 + 2;  // conservative estimate > 0.
1288           //  Claim: each intermediate term is accurate
1289           //  to 2*base^calc_precision.
1290           //  Total rounding error in series computation is
1291           //  2*iterations_needed*base^calc_precision,
1292           //  exclusive of error in op.
1293         int calc_precision = p - bound_log2(2*iterations_needed)
1294                                - 2; // for error in op, truncation.
1295           // Error in argument results in error of < 3/8 ulp.
1296           // Cumulative arithmetic rounding error is < 1/4 ulp.
1297           // Series truncation error < 1/4 ulp.
1298           // Final rounding error is <= 1/2 ulp.
1299           // Thus final error is < 1 ulp.
1300         BigInteger scaled_1 = big1.shiftLeft(-calc_precision);
1301         BigInteger big_op = BigInteger.valueOf(op);
1302         BigInteger big_op_squared = BigInteger.valueOf(op*op);
1303         BigInteger op_inverse = scaled_1.divide(big_op);
1304         BigInteger current_power = op_inverse;
1305         BigInteger current_term = op_inverse;
1306         BigInteger current_sum = op_inverse;
1307         int current_sign = 1;
1308         int n = 1;
1309         BigInteger max_trunc_error =
1310                 big1.shiftLeft(p - 2 - calc_precision);
1311         while (current_term.abs().compareTo(max_trunc_error) >= 0) {
1312           if (Thread.interrupted() || please_stop) throw new AbortedException();
1313           n += 2;
1314           current_power = current_power.divide(big_op_squared);
1315           current_sign = -current_sign;
1316           current_term =
1317             current_power.divide(BigInteger.valueOf(current_sign*n));
1318           current_sum = current_sum.add(current_term);
1319         }
1320         return scale(current_sum, calc_precision - p);
1321     }
1322 }
1323 
1324 // Representation for ln(1 + op)
1325 class prescaled_ln_CR extends slow_CR {
1326     CR op;
prescaled_ln_CR(CR x)1327     prescaled_ln_CR(CR x) { op = x; }
1328     // Compute an approximation of ln(1+x) to precision
1329     // prec. This assumes |x| < 1/2.
1330     // It uses a Taylor series expansion.
1331     // Unfortunately there appears to be no way to take
1332     // advantage of old information.
1333     // Note: this is known to be a bad algorithm for
1334     // floating point.  Unfortunately, other alternatives
1335     // appear to require precomputed tabular information.
approximate(int p)1336     protected BigInteger approximate(int p) {
1337         if (p >= 0) return big0;
1338         int iterations_needed = -p;  // conservative estimate > 0.
1339           //  Claim: each intermediate term is accurate
1340           //  to 2*2^calc_precision.  Total error is
1341           //  2*iterations_needed*2^calc_precision
1342           //  exclusive of error in op.
1343         int calc_precision = p - bound_log2(2*iterations_needed)
1344                                - 4; // for error in op, truncation.
1345         int op_prec = p - 3;
1346         BigInteger op_appr = op.get_appr(op_prec);
1347           // Error analysis as for exponential.
1348         BigInteger scaled_1 = big1.shiftLeft(-calc_precision);
1349         BigInteger x_nth = scale(op_appr, op_prec - calc_precision);
1350         BigInteger current_term = x_nth;  // x**n
1351         BigInteger current_sum = current_term;
1352         int n = 1;
1353         int current_sign = 1;   // (-1)^(n-1)
1354         BigInteger max_trunc_error =
1355                 big1.shiftLeft(p - 4 - calc_precision);
1356         while (current_term.abs().compareTo(max_trunc_error) >= 0) {
1357           if (Thread.interrupted() || please_stop) throw new AbortedException();
1358           n += 1;
1359           current_sign = -current_sign;
1360           x_nth = scale(x_nth.multiply(op_appr), op_prec);
1361           current_term = x_nth.divide(BigInteger.valueOf(n * current_sign));
1362                                 // x**n / (n * (-1)**(n-1))
1363           current_sum = current_sum.add(current_term);
1364         }
1365         return scale(current_sum, calc_precision - p);
1366     }
1367 }
1368 
1369 // Representation of the arcsine of a constructive real.  Private.
1370 // Uses a Taylor series expansion.  Assumes |x| < (1/2)^(1/3).
1371 class prescaled_asin_CR extends slow_CR {
1372     CR op;
prescaled_asin_CR(CR x)1373     prescaled_asin_CR(CR x) {
1374         op = x;
1375     }
approximate(int p)1376     protected BigInteger approximate(int p) {
1377         // The Taylor series is the sum of x^(2n+1) * (2n)!/(4^n n!^2 (2n+1))
1378         // Note that (2n)!/(4^n n!^2) is always less than one.
1379         // (The denominator is effectively 2n*2n*(2n-2)*(2n-2)*...*2*2
1380         // which is clearly > (2n)!)
1381         // Thus all terms are bounded by x^(2n+1).
1382         // Unfortunately, there's no easy way to prescale the argument
1383         // to less than 1/sqrt(2), and we can only approximate that.
1384         // Thus the worst case iteration count is fairly high.
1385         // But it doesn't make much difference.
1386         if (p >= 2) return big0;  // Never bigger than 4.
1387         int iterations_needed = -3 * p / 2 + 4;
1388                                 // conservative estimate > 0.
1389                                 // Follows from assumed bound on x and
1390                                 // the fact that only every other Taylor
1391                                 // Series term is present.
1392           //  Claim: each intermediate term is accurate
1393           //  to 2*2^calc_precision.
1394           //  Total rounding error in series computation is
1395           //  2*iterations_needed*2^calc_precision,
1396           //  exclusive of error in op.
1397         int calc_precision = p - bound_log2(2*iterations_needed)
1398                                - 4; // for error in op, truncation.
1399         int op_prec = p - 3;  // always <= -2
1400         BigInteger op_appr = op.get_appr(op_prec);
1401           // Error in argument results in error of < 1/4 ulp.
1402           // (Derivative is bounded by 2 in the specified range and we use
1403           // 3 extra digits.)
1404           // Ignoring the argument error, each term has an error of
1405           // < 3ulps relative to calc_precision, which is more precise than p.
1406           // Cumulative arithmetic rounding error is < 3/16 ulp (relative to p).
1407           // Series truncation error < 2/16 ulp.  (Each computed term
1408           // is at most 2/3 of last one, so some of remaining series <
1409           // 3/2 * current term.)
1410           // Final rounding error is <= 1/2 ulp.
1411           // Thus final error is < 1 ulp (relative to p).
1412         BigInteger max_last_term =
1413                 big1.shiftLeft(p - 4 - calc_precision);
1414         int exp = 1; // Current exponent, = 2n+1 in above expression
1415         BigInteger current_term = op_appr.shiftLeft(op_prec - calc_precision);
1416         BigInteger current_sum = current_term;
1417         BigInteger current_factor = current_term;
1418                                     // Current scaled Taylor series term
1419                                     // before division by the exponent.
1420                                     // Accurate to 3 ulp at calc_precision.
1421         while (current_term.abs().compareTo(max_last_term) >= 0) {
1422           if (Thread.interrupted() || please_stop) throw new AbortedException();
1423           exp += 2;
1424           // current_factor = current_factor * op * op * (exp-1) * (exp-2) /
1425           // (exp-1) * (exp-1), with the two exp-1 factors cancelling,
1426           // giving
1427           // current_factor = current_factor * op * op * (exp-2) / (exp-1)
1428           // Thus the error any in the previous term is multiplied by
1429           // op^2, adding an error of < (1/2)^(2/3) < 2/3 the original
1430           // error.
1431           current_factor = current_factor.multiply(BigInteger.valueOf(exp - 2));
1432           current_factor = scale(current_factor.multiply(op_appr), op_prec + 2);
1433                 // Carry 2 extra bits of precision forward; thus
1434                 // this effectively introduces 1/8 ulp error.
1435           current_factor = current_factor.multiply(op_appr);
1436           BigInteger divisor = BigInteger.valueOf(exp - 1);
1437           current_factor = current_factor.divide(divisor);
1438                 // Another 1/4 ulp error here.
1439           current_factor = scale(current_factor, op_prec - 2);
1440                 // Remove extra 2 bits.  1/2 ulp rounding error.
1441           // Current_factor has original 3 ulp rounding error, which we
1442           // reduced by 1, plus < 1 ulp new rounding error.
1443           current_term = current_factor.divide(BigInteger.valueOf(exp));
1444                 // Contributes 1 ulp error to sum plus at most 3 ulp
1445                 // from current_factor.
1446           current_sum = current_sum.add(current_term);
1447         }
1448         return scale(current_sum, calc_precision - p);
1449       }
1450   }
1451 
1452 
1453 class sqrt_CR extends CR {
1454     CR op;
sqrt_CR(CR x)1455     sqrt_CR(CR x) { op = x; }
1456     final int fp_prec = 50;     // Conservative estimate of number of
1457                                 // significant bits in double precision
1458                                 // computation.
1459     final int fp_op_prec = 60;
approximate(int p)1460     protected BigInteger approximate(int p) {
1461         int max_prec_needed = 2*p - 1;
1462         int msd = op.msd(max_prec_needed);
1463         if (msd <= max_prec_needed) return big0;
1464         int result_msd = msd/2;                 // +- 1
1465         int result_digits = result_msd - p;     // +- 2
1466         if (result_digits > fp_prec) {
1467           // Compute less precise approximation and use a Newton iter.
1468             int appr_digits = result_digits/2 + 6;
1469                 // This should be conservative.  Is fewer enough?
1470             int appr_prec = result_msd - appr_digits;
1471             BigInteger last_appr = get_appr(appr_prec);
1472             int prod_prec = 2*appr_prec;
1473             BigInteger op_appr = op.get_appr(prod_prec);
1474                 // Slightly fewer might be enough;
1475             // Compute (last_appr * last_appr + op_appr)/(last_appr/2)
1476             // while adjusting the scaling to make everything work
1477             BigInteger prod_prec_scaled_numerator =
1478                 last_appr.multiply(last_appr).add(op_appr);
1479             BigInteger scaled_numerator =
1480                 scale(prod_prec_scaled_numerator, appr_prec - p);
1481             BigInteger shifted_result = scaled_numerator.divide(last_appr);
1482             return shifted_result.add(big1).shiftRight(1);
1483         } else {
1484           // Use a double precision floating point approximation.
1485             // Make sure all precisions are even
1486             int op_prec = (msd - fp_op_prec) & ~1;
1487             int working_prec = op_prec - fp_op_prec;
1488             BigInteger scaled_bi_appr = op.get_appr(op_prec)
1489                                         .shiftLeft(fp_op_prec);
1490             double scaled_appr = scaled_bi_appr.doubleValue();
1491             if (scaled_appr < 0.0)
1492                 throw new ArithmeticException("sqrt(negative)");
1493             double scaled_fp_sqrt = Math.sqrt(scaled_appr);
1494             BigInteger scaled_sqrt = BigInteger.valueOf((long)scaled_fp_sqrt);
1495             int shift_count = working_prec/2 - p;
1496             return shift(scaled_sqrt, shift_count);
1497         }
1498     }
1499 }
1500