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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT RUN-TIME COMPONENTS --
4 -- --
5 -- S Y S T E M . I M G _ R E A L --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2017, Free Software Foundation, Inc. --
10 -- --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. --
17 -- --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
21 -- --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
26 -- --
27 -- GNAT was originally developed by the GNAT team at New York University. --
28 -- Extensive contributions were provided by Ada Core Technologies Inc. --
29 -- --
30 ------------------------------------------------------------------------------
40 -- The following defines the maximum number of digits that we can convert
41 -- accurately. This is limited by the precision of Long_Long_Float, and
42 -- also by the number of digits we can hold in Long_Long_Unsigned, which
43 -- is the integer type we use as an intermediate for the result.
45 -- We assume that in practice, the limitation will come from the digits
46 -- value, rather than the integer value. This is true for typical IEEE
47 -- implementations, and at worst, the only loss is for some precision
48 -- in very high precision floating-point output.
50 -- Note that in the following, the "-2" accounts for the sign and one
51 -- extra digits, since we need the maximum number of 9's that can be
52 -- supported, e.g. for the normal 64 bit case, Long_Long_Integer'Width
53 -- is 21, since the maximum value (approx 1.6 * 10**19) has 20 digits,
54 -- but the maximum number of 9's that can be supported is 19.
61 -- Number of digits that can be converted using type Unsigned
62 -- See above for the explanation of the -2.
65 -- Max decimal scaling required during conversion of floating-point
66 -- numbers to decimal. This is used to defend against infinite
67 -- looping in the conversion, as can be caused by erroneous executions.
68 -- The largest exponent used on any current system is 2**16383, which
69 -- is approximately 10**4932, and the highest number of decimal digits
70 -- is about 35 for 128-bit floating-point formats, so 5000 leaves
71 -- enough room for scaling such values
76 --------------------------
77 -- Image_Floating_Point --
78 --------------------------
80 procedure Image_Floating_Point
85 is
88 begin
89 -- Decide whether a blank should be prepended before the call to
90 -- Set_Image_Real. We generate a blank for positive values, and
91 -- also for positive zeroes. For negative zeroes, we generate a
92 -- space only if Signed_Zeroes is True (the RM only permits the
93 -- output of -0.0 on targets where this is the case). We can of
94 -- course still see a -0.0 on a target where Signed_Zeroes is
95 -- False (since this attribute refers to the proper handling of
96 -- negative zeroes, not to their existence). We do not generate
97 -- a blank for positive infinity, since we output an explicit +.
101 then
104 else
111 --------------------------------
112 -- Image_Ordinary_Fixed_Point --
113 --------------------------------
115 procedure Image_Ordinary_Fixed_Point
120 is
123 begin
124 -- Output space at start if non-negative
129 else
136 --------------------
137 -- Set_Image_Real --
138 --------------------
140 procedure Set_Image_Real
147 is
155 -- This should be the same value as Ada.[Wide_]Text_IO.Field'Last.
156 -- It is not worth dragging in Ada.Text_IO to pick up this value,
157 -- since it really should never be necessary to change it.
160 -- Array used to hold digits of converted integer value. This is a
161 -- large enough buffer to accommodate ludicrous values of Fore and Aft.
164 -- Number of digits stored in Digs (and also subscript of last digit)
167 -- Adjusts the value in X by multiplying or dividing by a power of
168 -- ten so that it is in the range 10**(S-1) <= X < 10**S. Includes
169 -- adding 0.5 to round the result, readjusting if the rounding causes
170 -- the result to wander out of the range. Scale is adjusted to reflect
171 -- the power of ten used to divide the result (i.e. one is added to
172 -- the scale value for each division by 10.0, or one is subtracted
173 -- for each multiplication by 10.0).
176 -- Takes the value in X, outputs integer digits into Digs. On return,
177 -- Ndigs is set to the number of digits stored. The digits are stored
178 -- in Digs (1 .. Ndigs),
181 -- Sets character C in output buffer
184 -- Sets leading blanks and minus sign if needed. N is the number of
185 -- positions to be filled (a minus sign is output even if N is zero
186 -- or negative, but for a positive value, if N is non-positive, then
187 -- the call has no effect).
190 -- Set digits S through E from Digs buffer. No effect if S > E
193 -- After outputting +Inf, -Inf or NaN, this routine fills out the
194 -- rest of the field with * characters. The argument is the number
195 -- of characters output so far (either 3 or 4)
198 -- Set N zeros, no effect if N is negative
204 ------------------
205 -- Adjust_Scale --
206 ------------------
214 begin
215 -- Cases where scaling up is required
219 -- What we are looking for is a power of ten to multiply X by
220 -- so that the result lies within the required range.
222 loop
229 -- The following exception is only raised in case of erroneous
230 -- execution, where a number was considered valid but still
231 -- fails to scale up. One situation where this can happen is
232 -- when a system which is supposed to be IEEE-compliant, but
233 -- has been reconfigured to flush denormals to zero.
239 -- Here we know that we must multiply by at least 10**1 and that
240 -- 10**Maxpow takes us too far: binary search to find right one.
242 -- Because of roundoff errors, it is possible for the value
243 -- of XP to be just outside of the interval when Lo >= Hi. In
244 -- that case we adjust explicitly by a factor of 10. This
245 -- can only happen with a value that is very close to an
246 -- exact power of 10.
251 loop
262 else
273 else
277 else
285 -- Cases where scaling down is required
289 -- What we are looking for is a power of ten to divide X by
290 -- so that the result lies within the required range.
292 loop
299 -- The following exception is only raised in case of erroneous
300 -- execution, where a number was considered valid but still
301 -- fails to scale up. One situation where this can happen is
302 -- when a system which is supposed to be IEEE-compliant, but
303 -- has been reconfigured to flush denormals to zero.
309 -- Here we know that we must divide by at least 10**1 and that
310 -- 10**Maxpow takes us too far, binary search to find right one.
315 loop
326 else
337 else
341 else
349 -- Here we are already scaled right
351 else
355 -- Round, readjusting scale if needed. Note that if a readjustment
356 -- occurs, then it is never necessary to round again, because there
357 -- is no possibility of such a second rounding causing a change.
368 ---------------------
369 -- Convert_Integer --
370 ---------------------
373 begin
374 -- Use Unsigned routine if possible, since on many machines it will
375 -- be significantly more efficient than the Long_Long_Unsigned one.
379 Set_Image_Unsigned
383 -- But if we want more digits than fit in Unsigned, we have to use
384 -- the Long_Long_Unsigned routine after all.
386 else
388 Set_Image_Long_Long_Unsigned
394 ---------
395 -- Set --
396 ---------
399 begin
404 -------------------------
405 -- Set_Blanks_And_Sign --
406 -------------------------
409 begin
417 else
424 --------------
425 -- Set_Digs --
426 --------------
429 begin
435 ----------------------
436 -- Set_Special_Fill --
437 ----------------------
442 begin
454 ---------------
455 -- Set_Zeros --
456 ---------------
459 begin
465 -- Start of processing for Set_Image_Real
467 begin
468 -- We call the floating-point processor reset routine so that we can
469 -- be sure the floating-point processor is properly set for conversion
470 -- calls. This is notably need on Windows, where calls to the operating
471 -- system randomly reset the processor into 64-bit mode.
477 -- Deal with invalid values first,
481 -- Note that we're taking our chances here, as V might be
482 -- an invalid bit pattern resulting from erroneous execution
483 -- (caused by using uninitialized variables for example).
485 -- No matter what, we'll at least get reasonable behavior,
486 -- converting to infinity or some other value, or causing an
487 -- exception to be raised is fine.
489 -- If the following test succeeds, then we definitely have
490 -- an infinite value, so we print Inf.
499 -- In all other cases we print NaN
508 else
518 -- Positive values
524 -- Negative values
530 -- Zero values
535 else
552 else
553 -- It should not be possible for a NaN to end up here.
554 -- Either the 'Valid test has failed, or we have some form
555 -- of erroneous execution. Raise Constraint_Error instead of
556 -- attempting to go ahead printing the value.
561 -- X and Sign are set here, and X is known to be a valid,
562 -- non-zero floating-point number.
564 -- Case of non-zero value with Exp = 0
568 -- First step is to multiply by 10 ** Nfrac to get an integer
569 -- value to be output, an then add 0.5 to round the result.
571 declare
574 begin
575 loop
576 -- If we are larger than Powten (Maxdigs) now, then
577 -- we have too many significant digits, and we have
578 -- not even finished multiplying by NFrac (NF shows
579 -- the number of unaccounted-for digits).
583 -- In this situation, we only to generate a reasonable
584 -- number of significant digits, and then zeroes after.
585 -- So first we rescale to get:
587 -- 10 ** (Maxdigs - 1) <= X < 10 ** Maxdigs
589 -- and then convert the resulting integer
592 Convert_Integer;
594 -- If that caused rescaling, then add zeros to the end
595 -- of the number to account for this scaling. Also add
596 -- zeroes to account for the undone multiplications
605 -- If multiplication is complete, then convert the resulting
606 -- integer after rounding (note that X is non-negative)
610 Convert_Integer;
613 -- Otherwise we can go ahead with the multiplication. If it
614 -- can be done in one step, then do it in one step.
620 -- If it cannot be done in one step, then do partial scaling
622 else
629 -- If number of available digits is less or equal to NFrac,
630 -- then we need an extra zero before the decimal point.
639 -- Normal case with some digits before the decimal point
641 else
648 -- Case of non-zero value with non-zero Exp value
650 else
651 -- If NFrac is less than Maxdigs, then all the fraction digits are
652 -- significant, so we can scale the resulting integer accordingly.
656 Convert_Integer;
658 -- Otherwise, we get the maximum number of digits available
660 else
662 Convert_Integer;
676 -- The exponent is the scaling factor adjusted for the digits
677 -- that we output after the decimal point, since these were
678 -- included in the scaled digits that we output.
688 else