| blob | 420a045321d1bb8d57209e005d561896256ecab6 |
1 /* real.c - software floating point emulation.
2 Copyright (C) 1993, 1994, 1995, 1996, 1997, 1998, 1999,
3 2000, 2002, 2003, 2004, 2005 Free Software Foundation, Inc.
4 Contributed by Stephen L. Moshier (moshier@world.std.com).
5 Re-written by Richard Henderson <rth@redhat.com>
7 This file is part of GCC.
9 GCC is free software; you can redistribute it and/or modify it under
10 the terms of the GNU General Public License as published by the Free
11 Software Foundation; either version 2, or (at your option) any later
12 version.
14 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
15 WARRANTY; without even the implied warranty of MERCHANTABILITY or
16 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
17 for more details.
19 You should have received a copy of the GNU General Public License
20 along with GCC; see the file COPYING. If not, write to the Free
21 Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
22 02110-1301, USA. */
34 /* The floating point model used internally is not exactly IEEE 754
35 compliant, and close to the description in the ISO C99 standard,
36 section 5.2.4.2.2 Characteristics of floating types.
38 Specifically
40 x = s * b^e * \sum_{k=1}^p f_k * b^{-k}
42 where
43 s = sign (+- 1)
44 b = base or radix, here always 2
45 e = exponent
46 p = precision (the number of base-b digits in the significand)
47 f_k = the digits of the significand.
49 We differ from typical IEEE 754 encodings in that the entire
50 significand is fractional. Normalized significands are in the
51 range [0.5, 1.0).
53 A requirement of the model is that P be larger than the largest
54 supported target floating-point type by at least 2 bits. This gives
55 us proper rounding when we truncate to the target type. In addition,
56 E must be large enough to hold the smallest supported denormal number
57 in a normalized form.
59 Both of these requirements are easily satisfied. The largest target
60 significand is 113 bits; we store at least 160. The smallest
61 denormal number fits in 17 exponent bits; we store 27.
63 Note that the decimal string conversion routines are sensitive to
64 rounding errors. Since the raw arithmetic routines do not themselves
65 have guard digits or rounding, the computation of 10**exp can
66 accumulate more than a few digits of error. The previous incarnation
67 of real.c successfully used a 144-bit fraction; given the current
68 layout of REAL_VALUE_TYPE we're forced to expand to at least 160 bits.
70 Target floating point models that use base 16 instead of base 2
71 (i.e. IBM 370), are handled during round_for_format, in which we
72 canonicalize the exponent to be a multiple of 4 (log2(16)), and
73 adjust the significand to match. */
76 /* Used to classify two numbers simultaneously. */
77 #define CLASS2(A, B) ((A) << 2 | (B))
79 #if HOST_BITS_PER_LONG != 64 && HOST_BITS_PER_LONG != 32
81 #endif
126 \f
127 /* Initialize R with a positive zero. */
131 {
134 }
136 /* Initialize R with the canonical quiet NaN. */
140 {
145 }
149 {
155 }
159 {
163 }
165 \f
166 /* Right-shift the significand of A by N bits; put the result in the
167 significand of R. If any one bits are shifted out, return true. */
169 static bool
172 {
177 {
181 }
184 {
187 {
192 }
193 }
194 else
195 {
200 }
203 }
205 /* Right-shift the significand of A by N bits; put the result in the
206 significand of R. */
208 static void
211 {
216 {
218 {
223 }
224 }
225 else
226 {
231 }
232 }
234 /* Left-shift the significand of A by N bits; put the result in the
235 significand of R. */
237 static void
240 {
245 {
250 }
251 else
253 {
258 }
259 }
261 /* Likewise, but N is specialized to 1. */
265 {
271 }
273 /* Add the significands of A and B, placing the result in R. Return
274 true if there was carry out of the most significant word. */
279 {
284 {
289 {
292 }
293 else
297 }
300 }
302 /* Subtract the significands of A and B, placing the result in R. CARRY is
303 true if there's a borrow incoming to the least significant word.
304 Return true if there was borrow out of the most significant word. */
309 {
313 {
318 {
321 }
322 else
326 }
329 }
331 /* Negate the significand A, placing the result in R. */
335 {
340 {
344 {
346 {
349 }
350 else
352 }
353 else
357 }
358 }
360 /* Compare significands. Return tri-state vs zero. */
364 {
368 {
376 }
379 }
381 /* Return true if A is nonzero. */
385 {
393 }
395 /* Set bit N of the significand of R. */
399 {
402 }
404 /* Clear bit N of the significand of R. */
408 {
411 }
413 /* Test bit N of the significand of R. */
417 {
418 /* ??? Compiler bug here if we return this expression directly.
419 The conversion to bool strips the "&1" and we wind up testing
420 e.g. 2 != 0 -> true. Seen in gcc version 3.2 20020520. */
423 }
425 /* Clear bits 0..N-1 of the significand of R. */
427 static void
429 {
436 }
438 /* Divide the significands of A and B, placing the result in R. Return
439 true if the division was inexact. */
444 {
445 REAL_VALUE_TYPE u;
454 do
455 {
458 start:
460 {
463 }
464 }
471 }
473 /* Adjust the exponent and significand of R such that the most
474 significant bit is set. We underflow to zero and overflow to
475 infinity here, without denormals. (The intermediate representation
476 exponent is large enough to handle target denormals normalized.) */
478 static void
480 {
487 /* Find the first word that is nonzero. */
491 else
494 /* Zero significand flushes to zero. */
496 {
500 }
502 /* Find the first bit that is nonzero. */
509 {
515 else
516 {
519 }
520 }
521 }
522 \f
523 /* Calculate R = A + (SUBTRACT_P ? -B : B). Return true if the
524 result may be inexact due to a loss of precision. */
526 static bool
529 {
531 REAL_VALUE_TYPE t;
534 /* Determine if we need to add or subtract. */
539 {
541 /* -0 + -0 = -0, -0 - +0 = -0; all other cases yield +0. */
548 /* 0 + ANY = ANY. */
552 /* ANY + NaN = NaN. */
554 /* R + Inf = Inf. */
562 /* ANY + 0 = ANY. */
565 /* NaN + ANY = NaN. */
567 /* Inf + R = Inf. */
573 /* Inf - Inf = NaN. */
575 else
576 /* Inf + Inf = Inf. */
585 }
587 /* Swap the arguments such that A has the larger exponent. */
590 {
595 }
598 /* If the exponents are not identical, we need to shift the
599 significand of B down. */
601 {
602 /* If the exponents are too far apart, the significands
603 do not overlap, which makes the subtraction a noop. */
605 {
609 }
613 }
616 {
618 {
619 /* We got a borrow out of the subtraction. That means that
620 A and B had the same exponent, and B had the larger
621 significand. We need to swap the sign and negate the
622 significand. */
625 }
626 }
627 else
628 {
630 {
631 /* We got carry out of the addition. This means we need to
632 shift the significand back down one bit and increase the
633 exponent. */
637 {
640 }
641 }
642 }
647 /* Zero out the remaining fields. */
652 /* Re-normalize the result. */
655 /* Special case: if the subtraction results in zero, the result
656 is positive. */
659 else
663 }
665 /* Calculate R = A * B. Return true if the result may be inexact. */
667 static bool
670 {
677 {
681 /* +-0 * ANY = 0 with appropriate sign. */
689 /* ANY * NaN = NaN. */
697 /* NaN * ANY = NaN. */
704 /* 0 * Inf = NaN */
711 /* Inf * Inf = Inf, R * Inf = Inf */
720 }
724 else
728 /* Collect all the partial products. Since we don't have sure access
729 to a widening multiply, we split each long into two half-words.
731 Consider the long-hand form of a four half-word multiplication:
733 A B C D
734 * E F G H
735 --------------
736 DE DF DG DH
737 CE CF CG CH
738 BE BF BG BH
739 AE AF AG AH
741 We construct partial products of the widened half-word products
742 that are known to not overlap, e.g. DF+DH. Each such partial
743 product is given its proper exponent, which allows us to sum them
744 and obtain the finished product. */
747 {
751 else
758 {
763 {
766 }
768 {
769 /* Would underflow to zero, which we shouldn't bother adding. */
772 }
779 {
783 else
787 }
791 }
792 }
799 }
801 /* Calculate R = A / B. Return true if the result may be inexact. */
803 static bool
806 {
812 {
814 /* 0 / 0 = NaN. */
816 /* Inf / Inf = NaN. */
822 /* 0 / ANY = 0. */
824 /* R / Inf = 0. */
829 /* R / 0 = Inf. */
831 /* Inf / 0 = Inf. */
839 /* ANY / NaN = NaN. */
847 /* NaN / ANY = NaN. */
853 /* Inf / R = Inf. */
862 }
866 else
869 /* Make sure all fields in the result are initialized. */
876 {
879 }
881 {
884 }
889 /* Re-normalize the result. */
897 }
899 /* Return a tri-state comparison of A vs B. Return NAN_RESULT if
900 one of the two operands is a NaN. */
902 static int
905 {
909 {
911 /* Sign of zero doesn't matter for compares. */
941 }
953 else
957 }
959 /* Return A truncated to an integral value toward zero. */
961 static void
963 {
967 {
975 {
978 }
987 }
988 }
990 /* Perform the binary or unary operation described by CODE.
991 For a unary operation, leave OP1 NULL. This function returns
992 true if the result may be inexact due to loss of precision. */
994 bool
997 {
1004 {
1022 else
1031 else
1051 }
1053 }
1055 /* Legacy. Similar, but return the result directly. */
1057 REAL_VALUE_TYPE
1060 {
1061 REAL_VALUE_TYPE r;
1064 }
1066 bool
1069 {
1073 {
1105 }
1106 }
1108 /* Return floor log2(R). */
1110 int
1112 {
1114 {
1124 }
1125 }
1127 /* R = OP0 * 2**EXP. */
1129 void
1131 {
1134 {
1146 else
1152 }
1153 }
1155 /* Determine whether a floating-point value X is infinite. */
1157 bool
1159 {
1161 }
1163 /* Determine whether a floating-point value X is a NaN. */
1165 bool
1167 {
1169 }
1171 /* Determine whether a floating-point value X is negative. */
1173 bool
1175 {
1177 }
1179 /* Determine whether a floating-point value X is minus zero. */
1181 bool
1183 {
1185 }
1187 /* Compare two floating-point objects for bitwise identity. */
1189 bool
1191 {
1200 {
1215 /* The significand is ignored for canonical NaNs. */
1222 }
1229 }
1231 /* Try to change R into its exact multiplicative inverse in machine
1232 mode MODE. Return true if successful. */
1234 bool
1236 {
1238 REAL_VALUE_TYPE u;
1244 /* Check for a power of two: all significand bits zero except the MSB. */
1251 /* Find the inverse and truncate to the required mode. */
1255 /* The rounding may have overflowed. */
1266 }
1267 \f
1268 /* Render R as an integer. */
1270 HOST_WIDE_INT
1272 {
1276 {
1278 underflow:
1283 overflow:
1286 i--;
1295 /* Only force overflow for unsigned overflow. Signed overflow is
1296 undefined, so it doesn't matter what we return, and some callers
1297 expect to be able to use this routine for both signed and
1298 unsigned conversions. */
1304 else
1305 {
1310 }
1320 }
1321 }
1323 /* Likewise, but to an integer pair, HI+LOW. */
1325 void
1328 {
1329 REAL_VALUE_TYPE t;
1334 {
1336 underflow:
1342 overflow:
1346 else
1347 {
1348 high--;
1350 }
1355 {
1358 }
1363 /* Only force overflow for unsigned overflow. Signed overflow is
1364 undefined, so it doesn't matter what we return, and some callers
1365 expect to be able to use this routine for both signed and
1366 unsigned conversions. */
1372 {
1375 }
1376 else
1377 {
1386 }
1389 {
1392 else
1394 }
1399 }
1403 }
1405 /* A subroutine of real_to_decimal. Compute the quotient and remainder
1406 of NUM / DEN. Return the quotient and place the remainder in NUM.
1407 It is expected that NUM / DEN are close enough that the quotient is
1408 small. */
1410 static unsigned long
1412 {
1421 do
1422 {
1426 start:
1428 {
1431 }
1432 }
1439 }
1441 /* Render R as a decimal floating point constant. Emit DIGITS significant
1442 digits in the result, bounded by BUF_SIZE. If DIGITS is 0, choose the
1443 maximum for the representation. If CROP_TRAILING_ZEROS, strip trailing
1444 zeros. */
1446 #define M_LOG10_2 0.30102999566398119521
1448 void
1451 {
1461 {
1471 /* ??? Print the significand as well, if not canonical? */
1476 }
1479 {
1482 }
1484 /* Bound the number of digits printed by the size of the representation. */
1489 /* Estimate the decimal exponent, and compute the length of the string it
1490 will print as. Be conservative and add one to account for possible
1491 overflow or rounding error. */
1496 /* Bound the number of digits printed by the size of the output buffer. */
1513 {
1516 /* Number is greater than one. Convert significand to an integer
1517 and strip trailing decimal zeros. */
1522 /* Largest M, such that 10**2**M fits within SIGNIFICAND_BITS. */
1525 /* Iterate over the bits of the possible powers of 10 that might
1526 be present in U and eliminate them. That is, if we find that
1527 10**2**M divides U evenly, keep the division and increase
1528 DEC_EXP by 2**M. */
1529 do
1530 {
1531 REAL_VALUE_TYPE t;
1536 {
1539 }
1540 }
1543 /* Revert the scaling to integer that we performed earlier. */
1548 /* Find power of 10. Do this by dividing out 10**2**M when
1549 this is larger than the current remainder. Fill PTEN with
1550 the power of 10 that we compute. */
1552 {
1554 do
1555 {
1558 {
1562 }
1563 }
1565 }
1566 else
1567 /* We managed to divide off enough tens in the above reduction
1568 loop that we've now got a negative exponent. Fall into the
1569 less-than-one code to compute the proper value for PTEN. */
1571 }
1573 {
1576 /* Number is less than one. Pad significand with leading
1577 decimal zeros. */
1581 {
1582 /* Stop if we'd shift bits off the bottom. */
1588 /* Stop if we're now >= 1. */
1594 }
1597 /* Find power of 10. Do this by multiplying in P=10**2**M when
1598 the current remainder is smaller than 1/P. Fill PTEN with the
1599 power of 10 that we compute. */
1601 do
1602 {
1607 {
1611 }
1612 }
1615 /* Invert the positive power of 10 that we've collected so far. */
1617 }
1624 /* At this point, PTEN should contain the nearest power of 10 smaller
1625 than R, such that this division produces the first digit.
1627 Using a divide-step primitive that returns the complete integral
1628 remainder avoids the rounding error that would be produced if
1629 we were to use do_divide here and then simply multiply by 10 for
1630 each subsequent digit. */
1634 /* Be prepared for error in that division via underflow ... */
1636 {
1637 /* Multiply by 10 and try again. */
1642 }
1644 /* ... or overflow. */
1646 {
1651 }
1652 else
1653 {
1656 }
1658 /* Generate subsequent digits. */
1660 {
1664 }
1667 /* Generate one more digit with which to do rounding. */
1671 /* Round the result. */
1673 {
1674 /* Round to nearest. If R is nonzero there are additional
1675 nonzero digits to be extracted. */
1677 digit++;
1678 /* Round to even. */
1680 digit++;
1681 }
1683 {
1685 {
1689 else
1690 {
1693 }
1694 }
1696 /* Carry out of the first digit. This means we had all 9's and
1697 now have all 0's. "Prepend" a 1 by overwriting the first 0. */
1699 {
1701 dec_exp++;
1702 }
1703 }
1705 /* Insert the decimal point. */
1709 /* If requested, drop trailing zeros. Never crop past "1.0". */
1712 last--;
1714 /* Append the exponent. */
1716 }
1718 /* Render R as a hexadecimal floating point constant. Emit DIGITS
1719 significant digits in the result, bounded by BUF_SIZE. If DIGITS is 0,
1720 choose the maximum for the representation. If CROP_TRAILING_ZEROS,
1721 strip trailing zeros. */
1723 void
1726 {
1733 {
1743 /* ??? Print the significand as well, if not canonical? */
1748 }
1751 {
1752 /* Hexadecimal format for decimal floats is not interesting. */
1755 }
1760 /* Bound the number of digits printed by the size of the output buffer. */
1779 {
1783 }
1785 out:
1788 p--;
1791 }
1793 /* Initialize R from a decimal or hexadecimal string. The string is
1794 assumed to have been syntax checked already. */
1796 void
1798 {
1805 {
1807 str++;
1808 }
1810 str++;
1813 {
1814 /* Hexadecimal floating point. */
1820 str++;
1822 {
1827 {
1831 }
1833 /* Ensure correct rounding by setting last bit if there is
1834 a subsequent nonzero digit. */
1837 str++;
1838 }
1840 {
1841 str++;
1843 {
1846 }
1848 {
1853 {
1857 }
1859 /* Ensure correct rounding by setting last bit if there is
1860 a subsequent nonzero digit. */
1862 str++;
1863 }
1864 }
1866 /* If the mantissa is zero, ignore the exponent. */
1871 {
1874 str++;
1876 {
1878 str++;
1879 }
1881 str++;
1885 {
1889 {
1890 /* Overflowed the exponent. */
1893 else
1895 }
1896 str++;
1897 }
1902 }
1908 }
1909 else
1910 {
1911 /* Decimal floating point. */
1916 str++;
1918 {
1923 }
1925 {
1926 str++;
1928 {
1931 }
1933 {
1938 exp--;
1939 }
1940 }
1942 /* If the mantissa is zero, ignore the exponent. */
1947 {
1950 str++;
1952 {
1954 str++;
1955 }
1957 str++;
1961 {
1965 {
1966 /* Overflowed the exponent. */
1969 else
1971 }
1972 str++;
1973 }
1977 }
1981 }
1986 underflow:
1990 overflow:
1993 }
1995 /* Legacy. Similar, but return the result directly. */
1997 REAL_VALUE_TYPE
1999 {
2000 REAL_VALUE_TYPE r;
2007 }
2009 /* Initialize R from string S and desired MODE. */
2011 void
2013 {
2016 else
2021 }
2023 /* Initialize R from the integer pair HIGH+LOW. */
2025 void
2029 {
2032 else
2033 {
2040 {
2044 else
2046 }
2049 {
2052 }
2053 else
2054 {
2060 }
2063 }
2067 }
2069 /* Returns 10**2**N. */
2073 {
2080 {
2082 {
2090 }
2091 else
2092 {
2095 }
2096 }
2099 }
2101 /* Returns 10**(-2**N). */
2105 {
2115 }
2117 /* Returns N. */
2121 {
2131 }
2133 /* Multiply R by 10**EXP. */
2135 static void
2137 {
2143 {
2147 }
2148 else
2157 }
2159 /* Fills R with +Inf. */
2161 void
2163 {
2165 }
2167 /* Fills R with a NaN whose significand is described by STR. If QUIET,
2168 we force a QNaN, else we force an SNaN. The string, if not empty,
2169 is parsed as a number and placed in the significand. Return true
2170 if the string was successfully parsed. */
2172 bool
2175 {
2182 {
2185 else
2187 }
2188 else
2189 {
2195 /* Parse akin to strtol into the significand of R. */
2198 str++;
2200 str++;
2202 str++;
2204 {
2205 str++;
2207 {
2209 str++;
2210 }
2211 else
2213 }
2216 {
2217 REAL_VALUE_TYPE u;
2220 {
2234 }
2240 str++;
2241 }
2243 /* Must have consumed the entire string for success. */
2247 /* Shift the significand into place such that the bits
2248 are in the most significant bits for the format. */
2251 /* Our MSB is always unset for NaNs. */
2254 /* Force quiet or signalling NaN. */
2256 }
2259 }
2261 /* Fills R with the largest finite value representable in mode MODE.
2262 If SIGN is nonzero, R is set to the most negative finite value. */
2264 void
2266 {
2276 else
2277 {
2287 /* This is an IBM extended double format made up of two IEEE
2288 doubles. The value of the long double is the sum of the
2289 values of the two parts. The most significant part is
2290 required to be the value of the long double rounded to the
2291 nearest double. Rounding means we need a slightly smaller
2292 value for LDBL_MAX. */
2294 }
2295 }
2297 /* Fills R with 2**N. */
2299 void
2301 {
2304 n++;
2308 ;
2309 else
2310 {
2314 }
2315 }
2317 \f
2318 static void
2320 {
2327 {
2329 {
2332 }
2333 /* FIXME. We can come here via fp_easy_constant
2334 (e.g. -O0 on '_Decimal32 x = 1.0 + 2.0dd'), but have not
2335 investigated whether this convert needs to be here, or
2336 something else is missing. */
2338 }
2346 {
2347 underflow:
2354 overflow:
2368 }
2370 /* If we're not base2, normalize the exponent to a multiple of
2371 the true base. */
2373 {
2379 {
2383 }
2384 }
2386 /* Check the range of the exponent. If we're out of range,
2387 either underflow or overflow. */
2391 {
2395 {
2396 /* Don't underflow completely until we've had a chance to round. */
2399 }
2400 else
2401 {
2406 /* De-normalize the significand. */
2409 }
2410 }
2412 /* There are P2 true significand bits, followed by one guard bit,
2413 followed by one sticky bit, followed by stuff. Fold nonzero
2414 stuff into the sticky bit. */
2419 sticky |=
2425 /* Round to even. */
2427 {
2428 REAL_VALUE_TYPE u;
2433 {
2434 /* Overflow. Means the significand had been all ones, and
2435 is now all zeros. Need to increase the exponent, and
2436 possibly re-normalize it. */
2443 {
2446 {
2452 }
2453 }
2454 }
2455 }
2457 /* Catch underflow that we deferred until after rounding. */
2461 /* Clear out trailing garbage. */
2463 }
2465 /* Extend or truncate to a new mode. */
2467 void
2470 {
2483 /* round_for_format de-normalizes denormals. Undo just that part. */
2486 }
2488 /* Legacy. Likewise, except return the struct directly. */
2490 REAL_VALUE_TYPE
2492 {
2493 REAL_VALUE_TYPE r;
2496 }
2498 /* Return true if truncating to MODE is exact. */
2500 bool
2502 {
2504 REAL_VALUE_TYPE t;
2510 /* Don't allow conversion to denormals. */
2515 /* After conversion to the new mode, the value must be identical. */
2518 }
2520 /* Write R to the given target format. Place the words of the result
2521 in target word order in BUF. There are always 32 bits in each
2522 long, no matter the size of the host long.
2524 Legacy: return word 0 for implementing REAL_VALUE_TO_TARGET_SINGLE. */
2526 long
2529 {
2530 REAL_VALUE_TYPE r;
2541 }
2543 /* Similar, but look up the format from MODE. */
2545 long
2547 {
2554 }
2556 /* Read R from the given target format. Read the words of the result
2557 in target word order in BUF. There are always 32 bits in each
2558 long, no matter the size of the host long. */
2560 void
2563 {
2565 }
2567 /* Similar, but look up the format from MODE. */
2569 void
2571 {
2578 }
2580 /* Return the number of bits of the largest binary value that the
2581 significand of MODE will hold. */
2582 /* ??? Legacy. Should get access to real_format directly. */
2584 int
2586 {
2594 {
2595 /* Return the size in bits of the largest binary value that can be
2596 held by the decimal coefficient for this mode. This is one more
2597 than the number of bits required to hold the largest coefficient
2598 of this mode. */
2601 }
2603 }
2605 /* Return a hash value for the given real value. */
2606 /* ??? The "unsigned int" return value is intended to be hashval_t,
2607 but I didn't want to pull hashtab.h into real.h. */
2609 unsigned int
2611 {
2617 {
2635 }
2639 {
2642 }
2643 else
2648 }
2649 \f
2650 /* IEEE single-precision format. */
2657 static void
2660 {
2669 {
2676 else
2682 {
2687 else
2689 /* We overload qnan_msb_set here: it's only clear for
2690 mips_ieee_single, which wants all mantissa bits but the
2691 quiet/signalling one set in canonical NaNs (at least
2692 Quiet ones). */
2700 }
2701 else
2706 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
2707 whereas the intermediate representation is 0.F x 2**exp.
2708 Which means we're off by one. */
2711 else
2719 }
2722 }
2724 static void
2727 {
2737 {
2739 {
2745 }
2748 }
2750 {
2752 {
2758 }
2759 else
2760 {
2763 }
2764 }
2765 else
2766 {
2771 }
2772 }
2775 {
2776 encode_ieee_single,
2777 decode_ieee_single,
2790 true
2791 };
2794 {
2795 encode_ieee_single,
2796 decode_ieee_single,
2809 false
2810 };
2812 \f
2813 /* IEEE double-precision format. */
2820 static void
2823 {
2831 {
2835 }
2836 else
2837 {
2842 }
2845 {
2852 else
2853 {
2856 }
2861 {
2866 else
2868 /* We overload qnan_msb_set here: it's only clear for
2869 mips_ieee_single, which wants all mantissa bits but the
2870 quiet/signalling one set in canonical NaNs (at least
2871 Quiet ones). */
2873 {
2876 }
2883 }
2884 else
2885 {
2888 }
2892 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
2893 whereas the intermediate representation is 0.F x 2**exp.
2894 Which means we're off by one. */
2897 else
2906 }
2910 else
2912 }
2914 static void
2917 {
2924 else
2940 {
2942 {
2947 {
2952 }
2953 else
2954 {
2957 }
2959 }
2962 }
2964 {
2966 {
2971 {
2974 }
2975 else
2977 }
2978 else
2979 {
2982 }
2983 }
2984 else
2985 {
2990 {
2993 }
2994 else
2996 }
2997 }
3000 {
3001 encode_ieee_double,
3002 decode_ieee_double,
3015 true
3016 };
3019 {
3020 encode_ieee_double,
3021 decode_ieee_double,
3034 false
3035 };
3037 \f
3038 /* IEEE extended real format. This comes in three flavors: Intel's as
3039 a 12 byte image, Intel's as a 16 byte image, and Motorola's. Intel
3040 12- and 16-byte images may be big- or little endian; Motorola's is
3041 always big endian. */
3043 /* Helper subroutine which converts from the internal format to the
3044 12-byte little-endian Intel format. Functions below adjust this
3045 for the other possible formats. */
3046 static void
3049 {
3057 {
3063 {
3066 /* Intel requires the explicit integer bit to be set, otherwise
3067 it considers the value a "pseudo-infinity". Motorola docs
3068 say it doesn't care. */
3070 }
3071 else
3072 {
3075 }
3080 {
3083 {
3086 }
3087 else
3088 {
3092 }
3095 else
3100 /* Intel requires the explicit integer bit to be set, otherwise
3101 it considers the value a "pseudo-nan". Motorola docs say it
3102 doesn't care. */
3104 }
3105 else
3106 {
3109 }
3113 {
3116 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
3117 whereas the intermediate representation is 0.F x 2**exp.
3118 Which means we're off by one.
3120 Except for Motorola, which consider exp=0 and explicit
3121 integer bit set to continue to be normalized. In theory
3122 this discrepancy has been taken care of by the difference
3123 in fmt->emin in round_for_format. */
3127 else
3128 {
3131 }
3135 {
3138 }
3139 else
3140 {
3144 }
3145 }
3150 }
3153 }
3155 /* Convert from the internal format to the 12-byte Motorola format
3156 for an IEEE extended real. */
3157 static void
3160 {
3164 /* Motorola chips are assumed always to be big-endian. Also, the
3165 padding in a Motorola extended real goes between the exponent and
3166 the mantissa. At this point the mantissa is entirely within
3167 elements 0 and 1 of intermed, and the exponent entirely within
3168 element 2, so all we have to do is swap the order around, and
3169 shift element 2 left 16 bits. */
3173 }
3175 /* Convert from the internal format to the 12-byte Intel format for
3176 an IEEE extended real. */
3177 static void
3180 {
3182 {
3183 /* All the padding in an Intel-format extended real goes at the high
3184 end, which in this case is after the mantissa, not the exponent.
3185 Therefore we must shift everything down 16 bits. */
3191 }
3192 else
3193 /* encode_ieee_extended produces what we want directly. */
3195 }
3197 /* Convert from the internal format to the 16-byte Intel format for
3198 an IEEE extended real. */
3199 static void
3202 {
3203 /* All the padding in an Intel-format extended real goes at the high end. */
3206 }
3208 /* As above, we have a helper function which converts from 12-byte
3209 little-endian Intel format to internal format. Functions below
3210 adjust for the other possible formats. */
3211 static void
3214 {
3230 {
3232 {
3236 /* When the IEEE format contains a hidden bit, we know that
3237 it's zero at this point, and so shift up the significand
3238 and decrease the exponent to match. In this case, Motorola
3239 defines the explicit integer bit to be valid, so we don't
3240 know whether the msb is set or not. */
3243 {
3246 }
3247 else
3251 }
3254 }
3256 {
3257 /* See above re "pseudo-infinities" and "pseudo-nans".
3258 Short summary is that the MSB will likely always be
3259 set, and that we don't care about it. */
3263 {
3268 {
3271 }
3272 else
3274 }
3275 else
3276 {
3279 }
3280 }
3281 else
3282 {
3287 {
3290 }
3291 else
3293 }
3294 }
3296 /* Convert from the internal format to the 12-byte Motorola format
3297 for an IEEE extended real. */
3298 static void
3301 {
3304 /* Motorola chips are assumed always to be big-endian. Also, the
3305 padding in a Motorola extended real goes between the exponent and
3306 the mantissa; remove it. */
3312 }
3314 /* Convert from the internal format to the 12-byte Intel format for
3315 an IEEE extended real. */
3316 static void
3319 {
3321 {
3322 /* All the padding in an Intel-format extended real goes at the high
3323 end, which in this case is after the mantissa, not the exponent.
3324 Therefore we must shift everything up 16 bits. */
3332 }
3333 else
3334 /* decode_ieee_extended produces what we want directly. */
3336 }
3338 /* Convert from the internal format to the 16-byte Intel format for
3339 an IEEE extended real. */
3340 static void
3343 {
3344 /* All the padding in an Intel-format extended real goes at the high end. */
3346 }
3349 {
3350 encode_ieee_extended_motorola,
3351 decode_ieee_extended_motorola,
3364 true
3365 };
3368 {
3369 encode_ieee_extended_intel_96,
3370 decode_ieee_extended_intel_96,
3383 true
3384 };
3387 {
3388 encode_ieee_extended_intel_128,
3389 decode_ieee_extended_intel_128,
3402 true
3403 };
3405 /* The following caters to i386 systems that set the rounding precision
3406 to 53 bits instead of 64, e.g. FreeBSD. */
3408 {
3409 encode_ieee_extended_intel_96,
3410 decode_ieee_extended_intel_96,
3423 true
3424 };
3425 \f
3426 /* IBM 128-bit extended precision format: a pair of IEEE double precision
3427 numbers whose sum is equal to the extended precision value. The number
3428 with greater magnitude is first. This format has the same magnitude
3429 range as an IEEE double precision value, but effectively 106 bits of
3430 significand precision. Infinity and NaN are represented by their IEEE
3431 double precision value stored in the first number, the second number is
3432 +0.0 or -0.0 for Infinity and don't-care for NaN. */
3439 static void
3442 {
3448 /* Renormlize R before doing any arithmetic on it. */
3453 /* u = IEEE double precision portion of significand. */
3459 {
3461 /* Call round_for_format since we might need to denormalize. */
3464 }
3465 else
3466 {
3467 /* Inf, NaN, 0 are all representable as doubles, so the
3468 least-significant part can be 0.0. */
3471 }
3472 }
3474 static void
3477 {
3485 {
3488 }
3489 else
3491 }
3494 {
3495 encode_ibm_extended,
3496 decode_ibm_extended,
3509 true
3510 };
3513 {
3514 encode_ibm_extended,
3515 decode_ibm_extended,
3528 false
3529 };
3531 \f
3532 /* IEEE quad precision format. */
3539 static void
3542 {
3545 REAL_VALUE_TYPE u;
3555 {
3562 else
3563 {
3568 }
3573 {
3577 {
3578 /* Don't use bits from the significand. The
3579 initialization above is right. */
3580 }
3582 {
3587 }
3588 else
3589 {
3596 }
3599 else
3601 /* We overload qnan_msb_set here: it's only clear for
3602 mips_ieee_single, which wants all mantissa bits but the
3603 quiet/signalling one set in canonical NaNs (at least
3604 Quiet ones). */
3606 {
3609 }
3612 }
3613 else
3614 {
3619 }
3623 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
3624 whereas the intermediate representation is 0.F x 2**exp.
3625 Which means we're off by one. */
3628 else
3633 {
3638 }
3639 else
3640 {
3647 }
3652 }
3655 {
3660 }
3661 else
3662 {
3667 }
3668 }
3670 static void
3673 {
3679 {
3684 }
3685 else
3686 {
3691 }
3703 {
3705 {
3711 {
3716 }
3717 else
3718 {
3721 }
3724 }
3727 }
3729 {
3731 {
3737 {
3742 }
3743 else
3744 {
3747 }
3749 }
3750 else
3751 {
3754 }
3755 }
3756 else
3757 {
3763 {
3768 }
3769 else
3770 {
3773 }
3776 }
3777 }
3780 {
3781 encode_ieee_quad,
3782 decode_ieee_quad,
3795 true
3796 };
3799 {
3800 encode_ieee_quad,
3801 decode_ieee_quad,
3814 false
3815 };
3816 \f
3817 /* Descriptions of VAX floating point formats can be found beginning at
3819 http://h71000.www7.hp.com/doc/73FINAL/4515/4515pro_013.html#f_floating_point_format
3821 The thing to remember is that they're almost IEEE, except for word
3822 order, exponent bias, and the lack of infinities, nans, and denormals.
3824 We don't implement the H_floating format here, simply because neither
3825 the VAX or Alpha ports use it. */
3840 static void
3843 {
3849 {
3871 }
3874 }
3876 static void
3879 {
3886 {
3893 }
3894 }
3896 static void
3899 {
3903 {
3915 /* Extract the significand into straight hi:lo. */
3917 {
3921 }
3922 else
3923 {
3928 }
3930 /* Rearrange the half-words of the significand to match the
3931 external format. */
3935 /* Add the sign and exponent. */
3942 }
3946 else
3948 }
3950 static void
3953 {
3959 else
3969 {
3974 /* Rearrange the half-words of the external format into
3975 proper ascending order. */
3980 {
3985 }
3986 else
3987 {
3992 }
3993 }
3994 }
3996 static void
3999 {
4003 {
4015 /* Extract the significand into straight hi:lo. */
4017 {
4021 }
4022 else
4023 {
4028 }
4030 /* Rearrange the half-words of the significand to match the
4031 external format. */
4035 /* Add the sign and exponent. */
4042 }
4046 else
4048 }
4050 static void
4053 {
4059 else
4069 {
4074 /* Rearrange the half-words of the external format into
4075 proper ascending order. */
4080 {
4085 }
4086 else
4087 {
4092 }
4093 }
4094 }
4097 {
4098 encode_vax_f,
4099 decode_vax_f,
4112 false
4113 };
4116 {
4117 encode_vax_d,
4118 decode_vax_d,
4131 false
4132 };
4135 {
4136 encode_vax_g,
4137 decode_vax_g,
4150 false
4151 };
4152 \f
4153 /* A good reference for these can be found in chapter 9 of
4154 "ESA/390 Principles of Operation", IBM document number SA22-7201-01.
4155 An on-line version can be found here:
4157 http://publibz.boulder.ibm.com/cgi-bin/bookmgr_OS390/BOOKS/DZ9AR001/9.1?DT=19930923083613
4158 */
4169 static void
4172 {
4178 {
4196 }
4199 }
4201 static void
4204 {
4215 {
4221 }
4222 }
4224 static void
4227 {
4233 {
4246 {
4250 }
4251 else
4252 {
4257 }
4265 }
4269 else
4271 }
4273 static void
4276 {
4282 else
4293 {
4299 {
4302 }
4303 else
4307 }
4308 }
4311 {
4312 encode_i370_single,
4313 decode_i370_single,
4326 false
4327 };
4330 {
4331 encode_i370_double,
4332 decode_i370_double,
4345 false
4346 };
4347 \f
4348 /* Encode real R into a single precision DFP value in BUF. */
4349 static void
4353 {
4355 }
4357 /* Decode a single precision DFP value in BUF into a real R. */
4358 static void
4362 {
4364 }
4366 /* Encode real R into a double precision DFP value in BUF. */
4367 static void
4371 {
4373 }
4375 /* Decode a double precision DFP value in BUF into a real R. */
4376 static void
4380 {
4382 }
4384 /* Encode real R into a quad precision DFP value in BUF. */
4385 static void
4389 {
4391 }
4393 /* Decode a quad precision DFP value in BUF into a real R. */
4394 static void
4398 {
4400 }
4402 /* Single precision decimal floating point (IEEE 754R). */
4404 {
4405 encode_decimal_single,
4406 decode_decimal_single,
4419 true
4420 };
4422 /* Double precision decimal floating point (IEEE 754R). */
4424 {
4425 encode_decimal_double,
4426 decode_decimal_double,
4439 true
4440 };
4442 /* Quad precision decimal floating point (IEEE 754R). */
4444 {
4445 encode_decimal_quad,
4446 decode_decimal_quad,
4459 true
4460 };
4461 \f
4462 /* The "twos-complement" c4x format is officially defined as
4464 x = s(~s).f * 2**e
4466 This is rather misleading. One must remember that F is signed.
4467 A better description would be
4469 x = -1**s * ((s + 1 + .f) * 2**e
4471 So if we have a (4 bit) fraction of .1000 with a sign bit of 1,
4472 that's -1 * (1+1+(-.5)) == -1.5. I think.
4474 The constructions here are taken from Tables 5-1 and 5-2 of the
4475 TMS320C4x User's Guide wherein step-by-step instructions for
4476 conversion from IEEE are presented. That's close enough to our
4477 internal representation so as to make things easy.
4479 See http://www-s.ti.com/sc/psheets/spru063c/spru063c.pdf */
4490 static void
4493 {
4497 {
4513 {
4516 else
4517 exp--;
4519 }
4524 }
4528 }
4530 static void
4533 {
4544 {
4549 {
4553 else
4554 exp++;
4555 }
4560 }
4561 }
4563 static void
4566 {
4570 {
4591 {
4594 else
4595 exp--;
4597 }
4602 }
4609 else
4611 }
4613 static void
4616 {
4622 else
4631 {
4636 {
4640 else
4641 exp++;
4642 }
4649 }
4650 }
4653 {
4654 encode_c4x_single,
4655 decode_c4x_single,
4668 false
4669 };
4672 {
4673 encode_c4x_extended,
4674 decode_c4x_extended,
4687 false
4688 };
4690 \f
4691 /* A synthetic "format" for internal arithmetic. It's the size of the
4692 internal significand minus the two bits needed for proper rounding.
4693 The encode and decode routines exist only to satisfy our paranoia
4694 harness. */
4701 static void
4704 {
4706 }
4708 static void
4711 {
4713 }
4716 {
4717 encode_internal,
4718 decode_internal,
4724 MAX_EXP,
4731 true
4732 };
4733 \f
4734 /* Calculate the square root of X in mode MODE, and store the result
4735 in R. Return TRUE if the operation does not raise an exception.
4736 For details see "High Precision Division and Square Root",
4737 Alan H. Karp and Peter Markstein, HP Lab Report 93-93-42, June
4738 1993. http://www.hpl.hp.com/techreports/93/HPL-93-42.pdf. */
4740 bool
4743 {
4749 /* sqrt(-0.0) is -0.0. */
4751 {
4754 }
4756 /* Negative arguments return NaN. */
4758 {
4761 }
4763 /* Infinity and NaN return themselves. */
4765 {
4768 }
4771 {
4774 }
4776 /* Initial guess for reciprocal sqrt, i. */
4780 /* Newton's iteration for reciprocal sqrt, i. */
4782 {
4783 /* i(n+1) = i(n) * (1.5 - 0.5*i(n)*i(n)*x). */
4790 /* Check for early convergence. */
4794 /* ??? Unroll loop to avoid copying. */
4796 }
4798 /* Final iteration: r = i*x + 0.5*i*x*(1.0 - i*(i*x)). */
4806 /* ??? We need a Tuckerman test to get the last bit. */
4810 }
4812 /* Calculate X raised to the integer exponent N in mode MODE and store
4813 the result in R. Return true if the result may be inexact due to
4814 loss of precision. The algorithm is the classic "left-to-right binary
4815 method" described in section 4.6.3 of Donald Knuth's "Seminumerical
4816 Algorithms", "The Art of Computer Programming", Volume 2. */
4818 bool
4821 {
4823 REAL_VALUE_TYPE t;
4830 {
4833 }
4835 {
4836 /* Don't worry about overflow, from now on n is unsigned. */
4839 }
4840 else
4846 {
4848 {
4852 }
4856 }
4863 }
4865 /* Round X to the nearest integer not larger in absolute value, i.e.
4866 towards zero, placing the result in R in mode MODE. */
4868 void
4871 {
4875 }
4877 /* Round X to the largest integer not greater in value, i.e. round
4878 down, placing the result in R in mode MODE. */
4880 void
4883 {
4884 REAL_VALUE_TYPE t;
4891 else
4893 }
4895 /* Round X to the smallest integer not less then argument, i.e. round
4896 up, placing the result in R in mode MODE. */
4898 void
4901 {
4902 REAL_VALUE_TYPE t;
4909 else
4911 }
4913 /* Round X to the nearest integer, but round halfway cases away from
4914 zero. */
4916 void
4919 {
4924 }
4926 /* Set the sign of R to the sign of X. */
4928 void
4930 {
4932 }