1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
5 -- S Y S T E M . V A L _ R E A L --
9 -- Copyright (C) 1992-2018, Free Software Foundation, Inc. --
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. --
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. --
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/>. --
27 -- GNAT was originally developed by the GNAT team at New York University. --
28 -- Extensive contributions were provided by Ada Core Technologies Inc. --
30 ------------------------------------------------------------------------------
32 with System
.Powten_Table
; use System
.Powten_Table
;
33 with System
.Val_Util
; use System
.Val_Util
;
34 with System
.Float_Control
;
36 package body System
.Val_Real
is
44 Ptr
: not null access Integer;
45 Max
: Integer) return Long_Long_Float
48 -- Local copy of string pointer
50 Base
: Long_Long_Float;
53 Uval
: Long_Long_Float;
54 -- Accumulated float result
56 subtype Digs
is Character range '0' .. '9';
57 -- Used to check for decimal digit
60 -- Power of Base to multiply result by
63 -- Position of starting non-blank character
66 -- Set to True if minus sign is present, otherwise to False
68 Bad_Base
: Boolean := False;
69 -- Set True if Base out of range or if out of range digit
71 After_Point
: Natural := 0;
72 -- Set to 1 after the point
74 Num_Saved_Zeroes
: Natural := 0;
75 -- This counts zeroes after the decimal point. A non-zero value means
76 -- that this number of previously scanned digits are zero. If the end
77 -- of the number is reached, these zeroes are simply discarded, which
78 -- ensures that trailing zeroes after the point never affect the value
79 -- (which might otherwise happen as a result of rounding). With this
80 -- processing in place, we can ensure that, for example, we get the
81 -- same exact result from 1.0E+49 and 1.0000000E+49. This is not
82 -- necessarily required in a case like this where the result is not
83 -- a machine number, but it is certainly a desirable behavior.
86 -- Scans integer literal value starting at current character position.
87 -- For each digit encountered, Uval is multiplied by 10.0, and the new
88 -- digit value is incremented. In addition Scale is decremented for each
89 -- digit encountered if we are after the point (After_Point = 1). The
90 -- longest possible syntactically valid numeral is scanned out, and on
91 -- return P points past the last character. On entry, the current
92 -- character is known to be a digit, so a numeral is definitely present.
103 Digit
:= Character'Pos (Str
(P
)) - Character'Pos ('0');
106 -- Save up trailing zeroes after the decimal point
108 if Digit
= 0 and then After_Point
= 1 then
109 Num_Saved_Zeroes
:= Num_Saved_Zeroes
+ 1;
111 -- Here for a non-zero digit
114 -- First deal with any previously saved zeroes
116 if Num_Saved_Zeroes
/= 0 then
117 while Num_Saved_Zeroes
> Maxpow
loop
118 Uval
:= Uval
* Powten
(Maxpow
);
119 Num_Saved_Zeroes
:= Num_Saved_Zeroes
- Maxpow
;
120 Scale
:= Scale
- Maxpow
;
123 Uval
:= Uval
* Powten
(Num_Saved_Zeroes
);
124 Scale
:= Scale
- Num_Saved_Zeroes
;
126 Num_Saved_Zeroes
:= 0;
129 -- Accumulate new digit
131 Uval
:= Uval
* 10.0 + Long_Long_Float (Digit
);
132 Scale
:= Scale
- After_Point
;
135 -- Done if end of input field
140 -- Check next character
142 elsif Str
(P
) not in Digs
then
143 if Str
(P
) = '_' then
144 Scan_Underscore
(Str
, P
, Ptr
, Max
, False);
152 -- Start of processing for System.Scan_Real
155 -- We do not tolerate strings with Str'Last = Positive'Last
157 if Str
'Last = Positive'Last then
158 raise Program_Error
with
159 "string upper bound is Positive'Last, not supported";
162 -- We call the floating-point processor reset routine so that we can
163 -- be sure the floating-point processor is properly set for conversion
164 -- calls. This is notably need on Windows, where calls to the operating
165 -- system randomly reset the processor into 64-bit mode.
167 System
.Float_Control
.Reset
;
169 Scan_Sign
(Str
, Ptr
, Max
, Minus
, Start
);
173 -- If digit, scan numeral before point
175 if Str
(P
) in Digs
then
179 -- Initial point, allowed only if followed by digit (RM 3.5(47))
183 and then Str
(P
+ 1) in Digs
187 -- Any other initial character is an error
193 -- Deal with based case. We reognize either the standard '#' or the
194 -- allowed alternative replacement ':' (see RM J.2(3)).
196 if P
< Max
and then (Str
(P
) = '#' or else Str
(P
) = ':') then
198 Base_Char
: constant Character := Str
(P
);
200 Fdigit
: Long_Long_Float;
203 -- Set bad base if out of range, and use safe base of 16.0,
204 -- to guard against division by zero in the loop below.
206 if Uval
< 2.0 or else Uval
> 16.0 then
215 -- Special check to allow initial point (RM 3.5(49))
217 if Str
(P
) = '.' then
222 -- Loop to scan digits of based number. On entry to the loop we
223 -- must have a valid digit. If we don't, then we have an illegal
224 -- floating-point value, and we raise Constraint_Error, note that
225 -- Ptr at this stage was reset to the proper (Start) value.
231 elsif Str
(P
) in Digs
then
232 Digit
:= Character'Pos (Str
(P
)) - Character'Pos ('0');
234 elsif Str
(P
) in 'A' .. 'F' then
236 Character'Pos (Str
(P
)) - (Character'Pos ('A') - 10);
238 elsif Str
(P
) in 'a' .. 'f' then
240 Character'Pos (Str
(P
)) - (Character'Pos ('a') - 10);
246 -- Save up trailing zeroes after the decimal point
248 if Digit
= 0 and then After_Point
= 1 then
249 Num_Saved_Zeroes
:= Num_Saved_Zeroes
+ 1;
251 -- Here for a non-zero digit
254 -- First deal with any previously saved zeroes
256 if Num_Saved_Zeroes
/= 0 then
257 Uval
:= Uval
* Base
** Num_Saved_Zeroes
;
258 Scale
:= Scale
- Num_Saved_Zeroes
;
259 Num_Saved_Zeroes
:= 0;
262 -- Now accumulate the new digit
264 Fdigit
:= Long_Long_Float (Digit
);
266 if Fdigit
>= Base
then
269 Scale
:= Scale
- After_Point
;
270 Uval
:= Uval
* Base
+ Fdigit
;
279 elsif Str
(P
) = '_' then
280 Scan_Underscore
(Str
, P
, Ptr
, Max
, True);
283 -- Skip past period after digit. Note that the processing
284 -- here will permit either a digit after the period, or the
285 -- terminating base character, as allowed in (RM 3.5(48))
287 if Str
(P
) = '.' and then After_Point
= 0 then
296 exit when Str
(P
) = Base_Char
;
300 -- Based number successfully scanned out (point was found)
305 -- Non-based case, check for being at decimal point now. Note that
306 -- in Ada 95, we do not insist on a decimal point being present
312 if P
<= Max
and then Str
(P
) = '.' then
315 -- Scan digits after point if any are present (RM 3.5(46))
317 if P
<= Max
and then Str
(P
) in Digs
then
325 -- At this point, we have Uval containing the digits of the value as
326 -- an integer, and Scale indicates the negative of the number of digits
327 -- after the point. Base contains the base value (an integral value in
328 -- the range 2.0 .. 16.0). Test for exponent, must be at least one
329 -- character after the E for the exponent to be valid.
331 Scale
:= Scale
+ Scan_Exponent
(Str
, Ptr
, Max
, Real
=> True);
333 -- At this point the exponent has been scanned if one is present and
334 -- Scale is adjusted to include the exponent value. Uval contains the
335 -- the integral value which is to be multiplied by Base ** Scale.
337 -- If base is not 10, use exponentiation for scaling
340 Uval
:= Uval
* Base
** Scale
;
342 -- For base 10, use power of ten table, repeatedly if necessary
345 while Scale
> Maxpow
loop
346 Uval
:= Uval
* Powten
(Maxpow
);
347 Scale
:= Scale
- Maxpow
;
350 -- Note that we still know that Scale > 0, since the loop
351 -- above leaves Scale in the range 1 .. Maxpow.
353 Uval
:= Uval
* Powten
(Scale
);
356 while (-Scale
) > Maxpow
loop
357 Uval
:= Uval
/ Powten
(Maxpow
);
358 Scale
:= Scale
+ Maxpow
;
361 -- Note that we still know that Scale < 0, since the loop
362 -- above leaves Scale in the range -Maxpow .. -1.
364 Uval
:= Uval
/ Powten
(-Scale
);
367 -- Here is where we check for a bad based number
372 -- If OK, then deal with initial minus sign, note that this processing
373 -- is done even if Uval is zero, so that -0.0 is correctly interpreted.
388 function Value_Real
(Str
: String) return Long_Long_Float is
390 -- We have to special case Str'Last = Positive'Last because the normal
391 -- circuit ends up setting P to Str'Last + 1 which is out of bounds. We
392 -- deal with this by converting to a subtype which fixes the bounds.
394 if Str
'Last = Positive'Last then
396 subtype NT
is String (1 .. Str
'Length);
398 return Value_Real
(NT
(Str
));
401 -- Normal case where Str'Last < Positive'Last
406 P
: aliased Integer := Str
'First;
408 V
:= Scan_Real
(Str
, P
'Access, Str
'Last);
409 Scan_Trailing_Blanks
(Str
, P
);