| blob | f4c493bd041296c32b5e44ffd83586974e182430 |
1 /* real.c - software floating point emulation.
2 Copyright (C) 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2002,
3 2003, 2004, 2005, 2007, 2008, 2009 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 3, 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 COPYING3. If not see
21 <http://www.gnu.org/licenses/>. */
33 /* The floating point model used internally is not exactly IEEE 754
34 compliant, and close to the description in the ISO C99 standard,
35 section 5.2.4.2.2 Characteristics of floating types.
37 Specifically
39 x = s * b^e * \sum_{k=1}^p f_k * b^{-k}
41 where
42 s = sign (+- 1)
43 b = base or radix, here always 2
44 e = exponent
45 p = precision (the number of base-b digits in the significand)
46 f_k = the digits of the significand.
48 We differ from typical IEEE 754 encodings in that the entire
49 significand is fractional. Normalized significands are in the
50 range [0.5, 1.0).
52 A requirement of the model is that P be larger than the largest
53 supported target floating-point type by at least 2 bits. This gives
54 us proper rounding when we truncate to the target type. In addition,
55 E must be large enough to hold the smallest supported denormal number
56 in a normalized form.
58 Both of these requirements are easily satisfied. The largest target
59 significand is 113 bits; we store at least 160. The smallest
60 denormal number fits in 17 exponent bits; we store 27.
62 Note that the decimal string conversion routines are sensitive to
63 rounding errors. Since the raw arithmetic routines do not themselves
64 have guard digits or rounding, the computation of 10**exp can
65 accumulate more than a few digits of error. The previous incarnation
66 of real.c successfully used a 144-bit fraction; given the current
67 layout of REAL_VALUE_TYPE we're forced to expand to at least 160 bits. */
70 /* Used to classify two numbers simultaneously. */
71 #define CLASS2(A, B) ((A) << 2 | (B))
73 #if HOST_BITS_PER_LONG != 64 && HOST_BITS_PER_LONG != 32
75 #endif
120 \f
121 /* Initialize R with a positive zero. */
125 {
128 }
130 /* Initialize R with the canonical quiet NaN. */
134 {
139 }
143 {
149 }
153 {
157 }
159 \f
160 /* Right-shift the significand of A by N bits; put the result in the
161 significand of R. If any one bits are shifted out, return true. */
163 static bool
166 {
171 {
175 }
178 {
181 {
186 }
187 }
188 else
189 {
194 }
197 }
199 /* Right-shift the significand of A by N bits; put the result in the
200 significand of R. */
202 static void
205 {
210 {
212 {
217 }
218 }
219 else
220 {
225 }
226 }
228 /* Left-shift the significand of A by N bits; put the result in the
229 significand of R. */
231 static void
234 {
239 {
244 }
245 else
247 {
252 }
253 }
255 /* Likewise, but N is specialized to 1. */
259 {
265 }
267 /* Add the significands of A and B, placing the result in R. Return
268 true if there was carry out of the most significant word. */
273 {
278 {
283 {
286 }
287 else
291 }
294 }
296 /* Subtract the significands of A and B, placing the result in R. CARRY is
297 true if there's a borrow incoming to the least significant word.
298 Return true if there was borrow out of the most significant word. */
303 {
307 {
312 {
315 }
316 else
320 }
323 }
325 /* Negate the significand A, placing the result in R. */
329 {
334 {
338 {
340 {
343 }
344 else
346 }
347 else
351 }
352 }
354 /* Compare significands. Return tri-state vs zero. */
358 {
362 {
370 }
373 }
375 /* Return true if A is nonzero. */
379 {
387 }
389 /* Set bit N of the significand of R. */
393 {
396 }
398 /* Clear bit N of the significand of R. */
402 {
405 }
407 /* Test bit N of the significand of R. */
411 {
412 /* ??? Compiler bug here if we return this expression directly.
413 The conversion to bool strips the "&1" and we wind up testing
414 e.g. 2 != 0 -> true. Seen in gcc version 3.2 20020520. */
417 }
419 /* Clear bits 0..N-1 of the significand of R. */
421 static void
423 {
430 }
432 /* Divide the significands of A and B, placing the result in R. Return
433 true if the division was inexact. */
438 {
439 REAL_VALUE_TYPE u;
448 do
449 {
452 start:
454 {
457 }
458 }
465 }
467 /* Adjust the exponent and significand of R such that the most
468 significant bit is set. We underflow to zero and overflow to
469 infinity here, without denormals. (The intermediate representation
470 exponent is large enough to handle target denormals normalized.) */
472 static void
474 {
481 /* Find the first word that is nonzero. */
485 else
488 /* Zero significand flushes to zero. */
490 {
494 }
496 /* Find the first bit that is nonzero. */
503 {
509 else
510 {
513 }
514 }
515 }
516 \f
517 /* Calculate R = A + (SUBTRACT_P ? -B : B). Return true if the
518 result may be inexact due to a loss of precision. */
520 static bool
523 {
525 REAL_VALUE_TYPE t;
528 /* Determine if we need to add or subtract. */
533 {
535 /* -0 + -0 = -0, -0 - +0 = -0; all other cases yield +0. */
542 /* 0 + ANY = ANY. */
546 /* ANY + NaN = NaN. */
548 /* R + Inf = Inf. */
556 /* ANY + 0 = ANY. */
559 /* NaN + ANY = NaN. */
561 /* Inf + R = Inf. */
567 /* Inf - Inf = NaN. */
569 else
570 /* Inf + Inf = Inf. */
579 }
581 /* Swap the arguments such that A has the larger exponent. */
584 {
589 }
592 /* If the exponents are not identical, we need to shift the
593 significand of B down. */
595 {
596 /* If the exponents are too far apart, the significands
597 do not overlap, which makes the subtraction a noop. */
599 {
603 }
607 }
610 {
612 {
613 /* We got a borrow out of the subtraction. That means that
614 A and B had the same exponent, and B had the larger
615 significand. We need to swap the sign and negate the
616 significand. */
619 }
620 }
621 else
622 {
624 {
625 /* We got carry out of the addition. This means we need to
626 shift the significand back down one bit and increase the
627 exponent. */
631 {
634 }
635 }
636 }
641 /* Zero out the remaining fields. */
646 /* Re-normalize the result. */
649 /* Special case: if the subtraction results in zero, the result
650 is positive. */
653 else
657 }
659 /* Calculate R = A * B. Return true if the result may be inexact. */
661 static bool
664 {
671 {
675 /* +-0 * ANY = 0 with appropriate sign. */
683 /* ANY * NaN = NaN. */
691 /* NaN * ANY = NaN. */
698 /* 0 * Inf = NaN */
705 /* Inf * Inf = Inf, R * Inf = Inf */
714 }
718 else
722 /* Collect all the partial products. Since we don't have sure access
723 to a widening multiply, we split each long into two half-words.
725 Consider the long-hand form of a four half-word multiplication:
727 A B C D
728 * E F G H
729 --------------
730 DE DF DG DH
731 CE CF CG CH
732 BE BF BG BH
733 AE AF AG AH
735 We construct partial products of the widened half-word products
736 that are known to not overlap, e.g. DF+DH. Each such partial
737 product is given its proper exponent, which allows us to sum them
738 and obtain the finished product. */
741 {
745 else
752 {
757 {
760 }
762 {
763 /* Would underflow to zero, which we shouldn't bother adding. */
766 }
773 {
777 else
781 }
785 }
786 }
793 }
795 /* Calculate R = A / B. Return true if the result may be inexact. */
797 static bool
800 {
806 {
808 /* 0 / 0 = NaN. */
810 /* Inf / Inf = NaN. */
816 /* 0 / ANY = 0. */
818 /* R / Inf = 0. */
823 /* R / 0 = Inf. */
825 /* Inf / 0 = Inf. */
833 /* ANY / NaN = NaN. */
841 /* NaN / ANY = NaN. */
847 /* Inf / R = Inf. */
856 }
860 else
863 /* Make sure all fields in the result are initialized. */
870 {
873 }
875 {
878 }
883 /* Re-normalize the result. */
891 }
893 /* Return a tri-state comparison of A vs B. Return NAN_RESULT if
894 one of the two operands is a NaN. */
896 static int
899 {
903 {
905 /* Sign of zero doesn't matter for compares. */
909 /* Decimal float zero is special and uses rvc_normal, not rvc_zero. */
912 /* Fall through. */
921 /* Decimal float zero is special and uses rvc_normal, not rvc_zero. */
924 /* Fall through. */
943 }
955 else
959 }
961 /* Return A truncated to an integral value toward zero. */
963 static void
965 {
969 {
977 {
980 }
989 }
990 }
992 /* Perform the binary or unary operation described by CODE.
993 For a unary operation, leave OP1 NULL. This function returns
994 true if the result may be inexact due to loss of precision. */
996 bool
999 {
1006 {
1024 else
1033 else
1053 }
1055 }
1057 /* Legacy. Similar, but return the result directly. */
1059 REAL_VALUE_TYPE
1062 {
1063 REAL_VALUE_TYPE r;
1066 }
1068 bool
1071 {
1075 {
1107 }
1108 }
1110 /* Return floor log2(R). */
1112 int
1114 {
1116 {
1126 }
1127 }
1129 /* R = OP0 * 2**EXP. */
1131 void
1133 {
1136 {
1148 else
1154 }
1155 }
1157 /* Determine whether a floating-point value X is infinite. */
1159 bool
1161 {
1163 }
1165 /* Determine whether a floating-point value X is a NaN. */
1167 bool
1169 {
1171 }
1173 /* Determine whether a floating-point value X is finite. */
1175 bool
1177 {
1179 }
1181 /* Determine whether a floating-point value X is negative. */
1183 bool
1185 {
1187 }
1189 /* Determine whether a floating-point value X is minus zero. */
1191 bool
1193 {
1195 }
1197 /* Compare two floating-point objects for bitwise identity. */
1199 bool
1201 {
1210 {
1225 /* The significand is ignored for canonical NaNs. */
1232 }
1239 }
1241 /* Try to change R into its exact multiplicative inverse in machine
1242 mode MODE. Return true if successful. */
1244 bool
1246 {
1248 REAL_VALUE_TYPE u;
1254 /* Check for a power of two: all significand bits zero except the MSB. */
1261 /* Find the inverse and truncate to the required mode. */
1265 /* The rounding may have overflowed. */
1276 }
1278 /* Return true if arithmetic on values in IMODE that were promoted
1279 from values in TMODE is equivalent to direct arithmetic on values
1280 in TMODE. */
1282 bool
1284 {
1288 /* These conditions are conservative rather than trying to catch the
1289 exact boundary conditions; the main case to allow is IEEE float
1290 and double. */
1305 }
1306 \f
1307 /* Render R as an integer. */
1309 HOST_WIDE_INT
1311 {
1315 {
1317 underflow:
1322 overflow:
1325 i--;
1334 /* Only force overflow for unsigned overflow. Signed overflow is
1335 undefined, so it doesn't matter what we return, and some callers
1336 expect to be able to use this routine for both signed and
1337 unsigned conversions. */
1343 else
1344 {
1349 }
1359 }
1360 }
1362 /* Likewise, but to an integer pair, HI+LOW. */
1364 void
1367 {
1368 REAL_VALUE_TYPE t;
1373 {
1375 underflow:
1381 overflow:
1385 else
1386 {
1387 high--;
1389 }
1394 {
1397 }
1402 /* Only force overflow for unsigned overflow. Signed overflow is
1403 undefined, so it doesn't matter what we return, and some callers
1404 expect to be able to use this routine for both signed and
1405 unsigned conversions. */
1411 {
1414 }
1415 else
1416 {
1425 }
1428 {
1431 else
1433 }
1438 }
1442 }
1444 /* A subroutine of real_to_decimal. Compute the quotient and remainder
1445 of NUM / DEN. Return the quotient and place the remainder in NUM.
1446 It is expected that NUM / DEN are close enough that the quotient is
1447 small. */
1449 static unsigned long
1451 {
1460 do
1461 {
1465 start:
1467 {
1470 }
1471 }
1478 }
1480 /* Render R as a decimal floating point constant. Emit DIGITS significant
1481 digits in the result, bounded by BUF_SIZE. If DIGITS is 0, choose the
1482 maximum for the representation. If CROP_TRAILING_ZEROS, strip trailing
1483 zeros. If MODE is VOIDmode, round to nearest value. Otherwise, round
1484 to a string that, when parsed back in mode MODE, yields the same value. */
1486 #define M_LOG10_2 0.30102999566398119521
1488 void
1492 {
1503 {
1506 }
1510 {
1520 /* ??? Print the significand as well, if not canonical? */
1526 }
1529 {
1532 }
1534 /* Bound the number of digits printed by the size of the representation. */
1539 /* Estimate the decimal exponent, and compute the length of the string it
1540 will print as. Be conservative and add one to account for possible
1541 overflow or rounding error. */
1546 /* Bound the number of digits printed by the size of the output buffer. */
1563 {
1566 /* Number is greater than one. Convert significand to an integer
1567 and strip trailing decimal zeros. */
1572 /* Largest M, such that 10**2**M fits within SIGNIFICAND_BITS. */
1575 /* Iterate over the bits of the possible powers of 10 that might
1576 be present in U and eliminate them. That is, if we find that
1577 10**2**M divides U evenly, keep the division and increase
1578 DEC_EXP by 2**M. */
1579 do
1580 {
1581 REAL_VALUE_TYPE t;
1586 {
1589 }
1590 }
1593 /* Revert the scaling to integer that we performed earlier. */
1598 /* Find power of 10. Do this by dividing out 10**2**M when
1599 this is larger than the current remainder. Fill PTEN with
1600 the power of 10 that we compute. */
1602 {
1604 do
1605 {
1608 {
1612 }
1613 }
1615 }
1616 else
1617 /* We managed to divide off enough tens in the above reduction
1618 loop that we've now got a negative exponent. Fall into the
1619 less-than-one code to compute the proper value for PTEN. */
1621 }
1623 {
1626 /* Number is less than one. Pad significand with leading
1627 decimal zeros. */
1631 {
1632 /* Stop if we'd shift bits off the bottom. */
1638 /* Stop if we're now >= 1. */
1644 }
1647 /* Find power of 10. Do this by multiplying in P=10**2**M when
1648 the current remainder is smaller than 1/P. Fill PTEN with the
1649 power of 10 that we compute. */
1651 do
1652 {
1657 {
1661 }
1662 }
1665 /* Invert the positive power of 10 that we've collected so far. */
1667 }
1674 /* At this point, PTEN should contain the nearest power of 10 smaller
1675 than R, such that this division produces the first digit.
1677 Using a divide-step primitive that returns the complete integral
1678 remainder avoids the rounding error that would be produced if
1679 we were to use do_divide here and then simply multiply by 10 for
1680 each subsequent digit. */
1684 /* Be prepared for error in that division via underflow ... */
1686 {
1687 /* Multiply by 10 and try again. */
1692 }
1694 /* ... or overflow. */
1696 {
1701 }
1702 else
1703 {
1706 }
1708 /* Generate subsequent digits. */
1710 {
1714 }
1717 /* Generate one more digit with which to do rounding. */
1721 /* Round the result. */
1723 {
1724 /* If the format uses round towards zero when parsing the string
1725 back in, we need to always round away from zero here. */
1727 digit++;
1729 }
1730 else
1731 {
1733 {
1734 /* Round to nearest. If R is nonzero there are additional
1735 nonzero digits to be extracted. */
1737 digit++;
1738 /* Round to even. */
1740 digit++;
1741 }
1744 }
1747 {
1749 {
1753 else
1754 {
1757 }
1758 }
1760 /* Carry out of the first digit. This means we had all 9's and
1761 now have all 0's. "Prepend" a 1 by overwriting the first 0. */
1763 {
1765 dec_exp++;
1766 }
1767 }
1769 /* Insert the decimal point. */
1773 /* If requested, drop trailing zeros. Never crop past "1.0". */
1776 last--;
1778 /* Append the exponent. */
1781 #ifdef ENABLE_CHECKING
1782 /* Verify that we can read the original value back in. */
1784 {
1788 }
1789 #endif
1790 }
1792 /* Likewise, except always uses round-to-nearest. */
1794 void
1797 {
1800 }
1802 /* Render R as a hexadecimal floating point constant. Emit DIGITS
1803 significant digits in the result, bounded by BUF_SIZE. If DIGITS is 0,
1804 choose the maximum for the representation. If CROP_TRAILING_ZEROS,
1805 strip trailing zeros. */
1807 void
1810 {
1817 {
1827 /* ??? Print the significand as well, if not canonical? */
1833 }
1836 {
1837 /* Hexadecimal format for decimal floats is not interesting. */
1840 }
1845 /* Bound the number of digits printed by the size of the output buffer. */
1864 {
1868 }
1870 out:
1873 p--;
1876 }
1878 /* Initialize R from a decimal or hexadecimal string. The string is
1879 assumed to have been syntax checked already. Return -1 if the
1880 value underflows, +1 if overflows, and 0 otherwise. */
1882 int
1884 {
1891 {
1893 str++;
1894 }
1896 str++;
1899 {
1902 }
1904 {
1907 }
1909 {
1912 }
1915 {
1916 /* Hexadecimal floating point. */
1922 str++;
1924 {
1929 {
1933 }
1935 /* Ensure correct rounding by setting last bit if there is
1936 a subsequent nonzero digit. */
1939 str++;
1940 }
1942 {
1943 str++;
1945 {
1948 }
1950 {
1955 {
1959 }
1961 /* Ensure correct rounding by setting last bit if there is
1962 a subsequent nonzero digit. */
1964 str++;
1965 }
1966 }
1968 /* If the mantissa is zero, ignore the exponent. */
1973 {
1976 str++;
1978 {
1980 str++;
1981 }
1983 str++;
1987 {
1991 {
1992 /* Overflowed the exponent. */
1995 else
1997 }
1998 str++;
1999 }
2004 }
2010 }
2011 else
2012 {
2013 /* Decimal floating point. */
2018 str++;
2020 {
2025 }
2027 {
2028 str++;
2030 {
2033 }
2035 {
2040 exp--;
2041 }
2042 }
2044 /* If the mantissa is zero, ignore the exponent. */
2049 {
2052 str++;
2054 {
2056 str++;
2057 }
2059 str++;
2063 {
2067 {
2068 /* Overflowed the exponent. */
2071 else
2073 }
2074 str++;
2075 }
2079 }
2083 }
2088 is_a_zero:
2092 underflow:
2096 overflow:
2099 }
2101 /* Legacy. Similar, but return the result directly. */
2103 REAL_VALUE_TYPE
2105 {
2106 REAL_VALUE_TYPE r;
2113 }
2115 /* Initialize R from string S and desired MODE. */
2117 void
2119 {
2122 else
2127 }
2129 /* Initialize R from the integer pair HIGH+LOW. */
2131 void
2135 {
2138 else
2139 {
2146 {
2150 else
2152 }
2155 {
2158 }
2159 else
2160 {
2166 }
2169 }
2173 }
2175 /* Returns 10**2**N. */
2179 {
2186 {
2188 {
2196 }
2197 else
2198 {
2201 }
2202 }
2205 }
2207 /* Returns 10**(-2**N). */
2211 {
2221 }
2223 /* Returns N. */
2227 {
2237 }
2239 /* Multiply R by 10**EXP. */
2241 static void
2243 {
2249 {
2253 }
2254 else
2263 }
2265 /* Returns the special REAL_VALUE_TYPE corresponding to 'e'. */
2269 {
2272 /* Initialize mathematical constants for constant folding builtins.
2273 These constants need to be given to at least 160 bits precision. */
2275 {
2276 mpfr_t m;
2283 }
2285 }
2287 /* Returns the special REAL_VALUE_TYPE corresponding to 1/3. */
2291 {
2294 /* Initialize mathematical constants for constant folding builtins.
2295 These constants need to be given to at least 160 bits precision. */
2297 {
2299 }
2301 }
2303 /* Returns the special REAL_VALUE_TYPE corresponding to sqrt(2). */
2307 {
2310 /* Initialize mathematical constants for constant folding builtins.
2311 These constants need to be given to at least 160 bits precision. */
2313 {
2314 mpfr_t m;
2319 }
2321 }
2323 /* Fills R with +Inf. */
2325 void
2327 {
2329 }
2331 /* Fills R with a NaN whose significand is described by STR. If QUIET,
2332 we force a QNaN, else we force an SNaN. The string, if not empty,
2333 is parsed as a number and placed in the significand. Return true
2334 if the string was successfully parsed. */
2336 bool
2339 {
2346 {
2349 else
2351 }
2352 else
2353 {
2359 /* Parse akin to strtol into the significand of R. */
2362 str++;
2364 str++;
2366 str++;
2368 {
2369 str++;
2371 {
2373 str++;
2374 }
2375 else
2377 }
2380 {
2381 REAL_VALUE_TYPE u;
2384 {
2398 }
2404 str++;
2405 }
2407 /* Must have consumed the entire string for success. */
2411 /* Shift the significand into place such that the bits
2412 are in the most significant bits for the format. */
2415 /* Our MSB is always unset for NaNs. */
2418 /* Force quiet or signalling NaN. */
2420 }
2423 }
2425 /* Fills R with the largest finite value representable in mode MODE.
2426 If SIGN is nonzero, R is set to the most negative finite value. */
2428 void
2430 {
2440 else
2441 {
2451 /* This is an IBM extended double format made up of two IEEE
2452 doubles. The value of the long double is the sum of the
2453 values of the two parts. The most significant part is
2454 required to be the value of the long double rounded to the
2455 nearest double. Rounding means we need a slightly smaller
2456 value for LDBL_MAX. */
2458 }
2459 }
2461 /* Fills R with 2**N. */
2463 void
2465 {
2468 n++;
2472 ;
2473 else
2474 {
2478 }
2481 }
2483 \f
2484 static void
2486 {
2492 {
2494 {
2497 }
2498 /* FIXME. We can come here via fp_easy_constant
2499 (e.g. -O0 on '_Decimal32 x = 1.0 + 2.0dd'), but have not
2500 investigated whether this convert needs to be here, or
2501 something else is missing. */
2503 }
2511 {
2512 underflow:
2519 overflow:
2533 }
2535 /* Check the range of the exponent. If we're out of range,
2536 either underflow or overflow. */
2540 {
2544 {
2545 /* Don't underflow completely until we've had a chance to round. */
2548 }
2549 else
2550 {
2555 /* De-normalize the significand. */
2558 }
2559 }
2562 {
2563 /* There are P2 true significand bits, followed by one guard bit,
2564 followed by one sticky bit, followed by stuff. Fold nonzero
2565 stuff into the sticky bit. */
2578 /* Round to even. */
2580 }
2583 {
2584 REAL_VALUE_TYPE u;
2589 {
2590 /* Overflow. Means the significand had been all ones, and
2591 is now all zeros. Need to increase the exponent, and
2592 possibly re-normalize it. */
2597 }
2598 }
2600 /* Catch underflow that we deferred until after rounding. */
2604 /* Clear out trailing garbage. */
2606 }
2608 /* Extend or truncate to a new mode. */
2610 void
2613 {
2626 /* round_for_format de-normalizes denormals. Undo just that part. */
2629 }
2631 /* Legacy. Likewise, except return the struct directly. */
2633 REAL_VALUE_TYPE
2635 {
2636 REAL_VALUE_TYPE r;
2639 }
2641 /* Return true if truncating to MODE is exact. */
2643 bool
2645 {
2647 REAL_VALUE_TYPE t;
2653 /* Don't allow conversion to denormals. */
2658 /* After conversion to the new mode, the value must be identical. */
2661 }
2663 /* Write R to the given target format. Place the words of the result
2664 in target word order in BUF. There are always 32 bits in each
2665 long, no matter the size of the host long.
2667 Legacy: return word 0 for implementing REAL_VALUE_TO_TARGET_SINGLE. */
2669 long
2672 {
2673 REAL_VALUE_TYPE r;
2684 }
2686 /* Similar, but look up the format from MODE. */
2688 long
2690 {
2697 }
2699 /* Read R from the given target format. Read the words of the result
2700 in target word order in BUF. There are always 32 bits in each
2701 long, no matter the size of the host long. */
2703 void
2706 {
2708 }
2710 /* Similar, but look up the format from MODE. */
2712 void
2714 {
2721 }
2723 /* Return the number of bits of the largest binary value that the
2724 significand of MODE will hold. */
2725 /* ??? Legacy. Should get access to real_format directly. */
2727 int
2729 {
2737 {
2738 /* Return the size in bits of the largest binary value that can be
2739 held by the decimal coefficient for this mode. This is one more
2740 than the number of bits required to hold the largest coefficient
2741 of this mode. */
2744 }
2746 }
2748 /* Return a hash value for the given real value. */
2749 /* ??? The "unsigned int" return value is intended to be hashval_t,
2750 but I didn't want to pull hashtab.h into real.h. */
2752 unsigned int
2754 {
2760 {
2778 }
2782 {
2785 }
2786 else
2791 }
2792 \f
2793 /* IEEE single-precision format. */
2800 static void
2803 {
2812 {
2819 else
2825 {
2830 else
2837 }
2838 else
2843 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
2844 whereas the intermediate representation is 0.F x 2**exp.
2845 Which means we're off by one. */
2848 else
2856 }
2859 }
2861 static void
2864 {
2874 {
2876 {
2882 }
2885 }
2887 {
2889 {
2895 }
2896 else
2897 {
2900 }
2901 }
2902 else
2903 {
2908 }
2909 }
2912 {
2913 encode_ieee_single,
2914 decode_ieee_single,
2929 false
2930 };
2933 {
2934 encode_ieee_single,
2935 decode_ieee_single,
2950 true
2951 };
2954 {
2955 encode_ieee_single,
2956 decode_ieee_single,
2971 true
2972 };
2974 /* SPU Single Precision (Extended-Range Mode) format is the same as IEEE
2975 single precision with the following differences:
2976 - Infinities are not supported. Instead MAX_FLOAT or MIN_FLOAT
2977 are generated.
2978 - NaNs are not supported.
2979 - The range of non-zero numbers in binary is
2980 (001)[1.]000...000 to (255)[1.]111...111.
2981 - Denormals can be represented, but are treated as +0.0 when
2982 used as an operand and are never generated as a result.
2983 - -0.0 can be represented, but a zero result is always +0.0.
2984 - the only supported rounding mode is trunction (towards zero). */
2986 {
2987 encode_ieee_single,
2988 decode_ieee_single,
3003 false
3004 };
3005 \f
3006 /* IEEE double-precision format. */
3013 static void
3016 {
3024 {
3028 }
3029 else
3030 {
3035 }
3038 {
3045 else
3046 {
3049 }
3054 {
3056 {
3058 {
3061 }
3062 else
3063 {
3066 }
3067 }
3070 else
3078 }
3079 else
3080 {
3083 }
3087 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
3088 whereas the intermediate representation is 0.F x 2**exp.
3089 Which means we're off by one. */
3092 else
3101 }
3105 else
3107 }
3109 static void
3112 {
3119 else
3135 {
3137 {
3142 {
3147 }
3148 else
3149 {
3152 }
3154 }
3157 }
3159 {
3161 {
3166 {
3169 }
3170 else
3172 }
3173 else
3174 {
3177 }
3178 }
3179 else
3180 {
3185 {
3188 }
3189 else
3191 }
3192 }
3195 {
3196 encode_ieee_double,
3197 decode_ieee_double,
3212 false
3213 };
3216 {
3217 encode_ieee_double,
3218 decode_ieee_double,
3233 true
3234 };
3237 {
3238 encode_ieee_double,
3239 decode_ieee_double,
3254 true
3255 };
3256 \f
3257 /* IEEE extended real format. This comes in three flavors: Intel's as
3258 a 12 byte image, Intel's as a 16 byte image, and Motorola's. Intel
3259 12- and 16-byte images may be big- or little endian; Motorola's is
3260 always big endian. */
3262 /* Helper subroutine which converts from the internal format to the
3263 12-byte little-endian Intel format. Functions below adjust this
3264 for the other possible formats. */
3265 static void
3268 {
3276 {
3282 {
3285 /* Intel requires the explicit integer bit to be set, otherwise
3286 it considers the value a "pseudo-infinity". Motorola docs
3287 say it doesn't care. */
3289 }
3290 else
3291 {
3294 }
3299 {
3302 {
3304 {
3307 }
3308 }
3310 {
3313 }
3314 else
3315 {
3319 }
3322 else
3327 /* Intel requires the explicit integer bit to be set, otherwise
3328 it considers the value a "pseudo-nan". Motorola docs say it
3329 doesn't care. */
3331 }
3332 else
3333 {
3336 }
3340 {
3343 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
3344 whereas the intermediate representation is 0.F x 2**exp.
3345 Which means we're off by one.
3347 Except for Motorola, which consider exp=0 and explicit
3348 integer bit set to continue to be normalized. In theory
3349 this discrepancy has been taken care of by the difference
3350 in fmt->emin in round_for_format. */
3354 else
3355 {
3358 }
3362 {
3365 }
3366 else
3367 {
3371 }
3372 }
3377 }
3380 }
3382 /* Convert from the internal format to the 12-byte Motorola format
3383 for an IEEE extended real. */
3384 static void
3387 {
3391 /* Motorola chips are assumed always to be big-endian. Also, the
3392 padding in a Motorola extended real goes between the exponent and
3393 the mantissa. At this point the mantissa is entirely within
3394 elements 0 and 1 of intermed, and the exponent entirely within
3395 element 2, so all we have to do is swap the order around, and
3396 shift element 2 left 16 bits. */
3400 }
3402 /* Convert from the internal format to the 12-byte Intel format for
3403 an IEEE extended real. */
3404 static void
3407 {
3409 {
3410 /* All the padding in an Intel-format extended real goes at the high
3411 end, which in this case is after the mantissa, not the exponent.
3412 Therefore we must shift everything down 16 bits. */
3418 }
3419 else
3420 /* encode_ieee_extended produces what we want directly. */
3422 }
3424 /* Convert from the internal format to the 16-byte Intel format for
3425 an IEEE extended real. */
3426 static void
3429 {
3430 /* All the padding in an Intel-format extended real goes at the high end. */
3433 }
3435 /* As above, we have a helper function which converts from 12-byte
3436 little-endian Intel format to internal format. Functions below
3437 adjust for the other possible formats. */
3438 static void
3441 {
3457 {
3459 {
3463 /* When the IEEE format contains a hidden bit, we know that
3464 it's zero at this point, and so shift up the significand
3465 and decrease the exponent to match. In this case, Motorola
3466 defines the explicit integer bit to be valid, so we don't
3467 know whether the msb is set or not. */
3470 {
3473 }
3474 else
3478 }
3481 }
3483 {
3484 /* See above re "pseudo-infinities" and "pseudo-nans".
3485 Short summary is that the MSB will likely always be
3486 set, and that we don't care about it. */
3490 {
3495 {
3498 }
3499 else
3501 }
3502 else
3503 {
3506 }
3507 }
3508 else
3509 {
3514 {
3517 }
3518 else
3520 }
3521 }
3523 /* Convert from the internal format to the 12-byte Motorola format
3524 for an IEEE extended real. */
3525 static void
3528 {
3531 /* Motorola chips are assumed always to be big-endian. Also, the
3532 padding in a Motorola extended real goes between the exponent and
3533 the mantissa; remove it. */
3539 }
3541 /* Convert from the internal format to the 12-byte Intel format for
3542 an IEEE extended real. */
3543 static void
3546 {
3548 {
3549 /* All the padding in an Intel-format extended real goes at the high
3550 end, which in this case is after the mantissa, not the exponent.
3551 Therefore we must shift everything up 16 bits. */
3559 }
3560 else
3561 /* decode_ieee_extended produces what we want directly. */
3563 }
3565 /* Convert from the internal format to the 16-byte Intel format for
3566 an IEEE extended real. */
3567 static void
3570 {
3571 /* All the padding in an Intel-format extended real goes at the high end. */
3573 }
3576 {
3577 encode_ieee_extended_motorola,
3578 decode_ieee_extended_motorola,
3593 true
3594 };
3597 {
3598 encode_ieee_extended_intel_96,
3599 decode_ieee_extended_intel_96,
3614 false
3615 };
3618 {
3619 encode_ieee_extended_intel_128,
3620 decode_ieee_extended_intel_128,
3635 false
3636 };
3638 /* The following caters to i386 systems that set the rounding precision
3639 to 53 bits instead of 64, e.g. FreeBSD. */
3641 {
3642 encode_ieee_extended_intel_96,
3643 decode_ieee_extended_intel_96,
3658 false
3659 };
3660 \f
3661 /* IBM 128-bit extended precision format: a pair of IEEE double precision
3662 numbers whose sum is equal to the extended precision value. The number
3663 with greater magnitude is first. This format has the same magnitude
3664 range as an IEEE double precision value, but effectively 106 bits of
3665 significand precision. Infinity and NaN are represented by their IEEE
3666 double precision value stored in the first number, the second number is
3667 +0.0 or -0.0 for Infinity and don't-care for NaN. */
3674 static void
3677 {
3683 /* Renormalize R before doing any arithmetic on it. */
3688 /* u = IEEE double precision portion of significand. */
3694 {
3696 /* Call round_for_format since we might need to denormalize. */
3699 }
3700 else
3701 {
3702 /* Inf, NaN, 0 are all representable as doubles, so the
3703 least-significant part can be 0.0. */
3706 }
3707 }
3709 static void
3712 {
3720 {
3723 }
3724 else
3726 }
3729 {
3730 encode_ibm_extended,
3731 decode_ibm_extended,
3746 false
3747 };
3750 {
3751 encode_ibm_extended,
3752 decode_ibm_extended,
3767 true
3768 };
3770 \f
3771 /* IEEE quad precision format. */
3778 static void
3781 {
3784 REAL_VALUE_TYPE u;
3794 {
3801 else
3802 {
3807 }
3812 {
3816 {
3818 {
3821 }
3822 }
3824 {
3829 }
3830 else
3831 {
3838 }
3841 else
3845 }
3846 else
3847 {
3852 }
3856 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
3857 whereas the intermediate representation is 0.F x 2**exp.
3858 Which means we're off by one. */
3861 else
3866 {
3871 }
3872 else
3873 {
3880 }
3885 }
3888 {
3893 }
3894 else
3895 {
3900 }
3901 }
3903 static void
3906 {
3912 {
3917 }
3918 else
3919 {
3924 }
3936 {
3938 {
3944 {
3949 }
3950 else
3951 {
3954 }
3957 }
3960 }
3962 {
3964 {
3970 {
3975 }
3976 else
3977 {
3980 }
3982 }
3983 else
3984 {
3987 }
3988 }
3989 else
3990 {
3996 {
4001 }
4002 else
4003 {
4006 }
4009 }
4010 }
4013 {
4014 encode_ieee_quad,
4015 decode_ieee_quad,
4030 false
4031 };
4034 {
4035 encode_ieee_quad,
4036 decode_ieee_quad,
4051 true
4052 };
4053 \f
4054 /* Descriptions of VAX floating point formats can be found beginning at
4056 http://h71000.www7.hp.com/doc/73FINAL/4515/4515pro_013.html#f_floating_point_format
4058 The thing to remember is that they're almost IEEE, except for word
4059 order, exponent bias, and the lack of infinities, nans, and denormals.
4061 We don't implement the H_floating format here, simply because neither
4062 the VAX or Alpha ports use it. */
4077 static void
4080 {
4086 {
4108 }
4111 }
4113 static void
4116 {
4123 {
4130 }
4131 }
4133 static void
4136 {
4140 {
4152 /* Extract the significand into straight hi:lo. */
4154 {
4158 }
4159 else
4160 {
4165 }
4167 /* Rearrange the half-words of the significand to match the
4168 external format. */
4172 /* Add the sign and exponent. */
4179 }
4183 else
4185 }
4187 static void
4190 {
4196 else
4206 {
4211 /* Rearrange the half-words of the external format into
4212 proper ascending order. */
4217 {
4222 }
4223 else
4224 {
4229 }
4230 }
4231 }
4233 static void
4236 {
4240 {
4252 /* Extract the significand into straight hi:lo. */
4254 {
4258 }
4259 else
4260 {
4265 }
4267 /* Rearrange the half-words of the significand to match the
4268 external format. */
4272 /* Add the sign and exponent. */
4279 }
4283 else
4285 }
4287 static void
4290 {
4296 else
4306 {
4311 /* Rearrange the half-words of the external format into
4312 proper ascending order. */
4317 {
4322 }
4323 else
4324 {
4329 }
4330 }
4331 }
4334 {
4335 encode_vax_f,
4336 decode_vax_f,
4351 false
4352 };
4355 {
4356 encode_vax_d,
4357 decode_vax_d,
4372 false
4373 };
4376 {
4377 encode_vax_g,
4378 decode_vax_g,
4393 false
4394 };
4395 \f
4396 /* Encode real R into a single precision DFP value in BUF. */
4397 static void
4401 {
4403 }
4405 /* Decode a single precision DFP value in BUF into a real R. */
4406 static void
4410 {
4412 }
4414 /* Encode real R into a double precision DFP value in BUF. */
4415 static void
4419 {
4421 }
4423 /* Decode a double precision DFP value in BUF into a real R. */
4424 static void
4428 {
4430 }
4432 /* Encode real R into a quad precision DFP value in BUF. */
4433 static void
4437 {
4439 }
4441 /* Decode a quad precision DFP value in BUF into a real R. */
4442 static void
4446 {
4448 }
4450 /* Single precision decimal floating point (IEEE 754). */
4452 {
4453 encode_decimal_single,
4454 decode_decimal_single,
4469 false
4470 };
4472 /* Double precision decimal floating point (IEEE 754). */
4474 {
4475 encode_decimal_double,
4476 decode_decimal_double,
4491 false
4492 };
4494 /* Quad precision decimal floating point (IEEE 754). */
4496 {
4497 encode_decimal_quad,
4498 decode_decimal_quad,
4513 false
4514 };
4515 \f
4516 /* Encode half-precision floats. This routine is used both for the IEEE
4517 ARM alternative encodings. */
4518 static void
4521 {
4530 {
4537 else
4543 {
4548 else
4555 }
4556 else
4561 /* Recall that IEEE numbers are interpreted as 1.F x 2**exp,
4562 whereas the intermediate representation is 0.F x 2**exp.
4563 Which means we're off by one. */
4566 else
4574 }
4577 }
4579 /* Decode half-precision floats. This routine is used both for the IEEE
4580 ARM alternative encodings. */
4581 static void
4584 {
4594 {
4596 {
4602 }
4605 }
4607 {
4609 {
4615 }
4616 else
4617 {
4620 }
4621 }
4622 else
4623 {
4628 }
4629 }
4631 /* Half-precision format, as specified in IEEE 754R. */
4633 {
4634 encode_ieee_half,
4635 decode_ieee_half,
4650 false
4651 };
4653 /* ARM's alternative half-precision format, similar to IEEE but with
4654 no reserved exponent value for NaNs and infinities; rather, it just
4655 extends the range of exponents by one. */
4657 {
4658 encode_ieee_half,
4659 decode_ieee_half,
4674 false
4675 };
4676 \f
4677 /* A synthetic "format" for internal arithmetic. It's the size of the
4678 internal significand minus the two bits needed for proper rounding.
4679 The encode and decode routines exist only to satisfy our paranoia
4680 harness. */
4687 static void
4690 {
4692 }
4694 static void
4697 {
4699 }
4702 {
4703 encode_internal,
4704 decode_internal,
4709 MAX_EXP,
4719 false
4720 };
4721 \f
4722 /* Calculate the square root of X in mode MODE, and store the result
4723 in R. Return TRUE if the operation does not raise an exception.
4724 For details see "High Precision Division and Square Root",
4725 Alan H. Karp and Peter Markstein, HP Lab Report 93-93-42, June
4726 1993. http://www.hpl.hp.com/techreports/93/HPL-93-42.pdf. */
4728 bool
4731 {
4737 /* sqrt(-0.0) is -0.0. */
4739 {
4742 }
4744 /* Negative arguments return NaN. */
4746 {
4749 }
4751 /* Infinity and NaN return themselves. */
4753 {
4756 }
4759 {
4762 }
4764 /* Initial guess for reciprocal sqrt, i. */
4768 /* Newton's iteration for reciprocal sqrt, i. */
4770 {
4771 /* i(n+1) = i(n) * (1.5 - 0.5*i(n)*i(n)*x). */
4778 /* Check for early convergence. */
4782 /* ??? Unroll loop to avoid copying. */
4784 }
4786 /* Final iteration: r = i*x + 0.5*i*x*(1.0 - i*(i*x)). */
4794 /* ??? We need a Tuckerman test to get the last bit. */
4798 }
4800 /* Calculate X raised to the integer exponent N in mode MODE and store
4801 the result in R. Return true if the result may be inexact due to
4802 loss of precision. The algorithm is the classic "left-to-right binary
4803 method" described in section 4.6.3 of Donald Knuth's "Seminumerical
4804 Algorithms", "The Art of Computer Programming", Volume 2. */
4806 bool
4809 {
4811 REAL_VALUE_TYPE t;
4818 {
4821 }
4823 {
4824 /* Don't worry about overflow, from now on n is unsigned. */
4827 }
4828 else
4834 {
4836 {
4840 }
4844 }
4851 }
4853 /* Round X to the nearest integer not larger in absolute value, i.e.
4854 towards zero, placing the result in R in mode MODE. */
4856 void
4859 {
4863 }
4865 /* Round X to the largest integer not greater in value, i.e. round
4866 down, placing the result in R in mode MODE. */
4868 void
4871 {
4872 REAL_VALUE_TYPE t;
4879 else
4881 }
4883 /* Round X to the smallest integer not less then argument, i.e. round
4884 up, placing the result in R in mode MODE. */
4886 void
4889 {
4890 REAL_VALUE_TYPE t;
4897 else
4899 }
4901 /* Round X to the nearest integer, but round halfway cases away from
4902 zero. */
4904 void
4907 {
4912 }
4914 /* Set the sign of R to the sign of X. */
4916 void
4918 {
4920 }
4922 /* Convert from REAL_VALUE_TYPE to MPFR. The caller is responsible
4923 for initializing and clearing the MPFR parameter. */
4925 void
4927 {
4928 /* We use a string as an intermediate type. */
4932 /* Take care of Infinity and NaN. */
4934 {
4937 }
4940 {
4943 }
4946 /* mpfr_set_str() parses hexadecimal floats from strings in the same
4947 format that GCC will output them. Nothing extra is needed. */
4950 }
4952 /* Convert from MPFR to REAL_VALUE_TYPE, for a given type TYPE and rounding
4953 mode RNDMODE. TYPE is only relevant if M is a NaN. */
4955 void
4957 {
4958 /* We use a string as an intermediate type. */
4960 mp_exp_t exp;
4962 /* Take care of Infinity and NaN. */
4964 {
4969 }
4972 {
4975 }
4979 /* The additional 12 chars add space for the sprintf below. This
4980 leaves 6 digits for the exponent which is supposedly enough. */
4983 /* REAL_VALUE_ATOF expects the exponent for mantissa * 2**exp,
4984 mpfr_get_str returns the exponent for mantissa * 16**exp, adjust
4985 for that. */
4990 else
4996 }
4998 /* Check whether the real constant value given is an integer. */
5000 bool
5002 {
5003 REAL_VALUE_TYPE cint;
5007 }
5009 /* Write into BUF the maximum representable finite floating-point
5010 number, (1 - b**-p) * b**emax for a given FP format FMT as a hex
5011 float string. LEN is the size of BUF, and the buffer must be large
5012 enough to contain the resulting string. */
5014 void
5016 {
5028 {
5029 /* This is an IBM extended double format made up of two IEEE
5030 doubles. The value of the long double is the sum of the
5031 values of the two parts. The most significant part is
5032 required to be the value of the long double rounded to the
5033 nearest double. Rounding means we need a slightly smaller
5034 value for LDBL_MAX. */
5036 }
5039 }