* gcc-interface/decl.c (gnat_to_gnu_entity) <E_Array_Type>: Do not make
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT RUN-TIME COMPONENTS --
4 -- --
5 -- G N A T . R A N D O M _ N U M B E R S --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 2007-2009 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 ------------------------------------------------------------------------------
32 with Ada.Numerics.Long_Elementary_Functions;
33 use Ada.Numerics.Long_Elementary_Functions;
34 with Ada.Unchecked_Conversion;
35 with System.Random_Numbers; use System.Random_Numbers;
37 package body GNAT.Random_Numbers is
39 Sys_Max_Image_Width : constant := System.Random_Numbers.Max_Image_Width;
41 subtype Image_String is String (1 .. Max_Image_Width);
43 -- Utility function declarations
45 procedure Insert_Image
46 (S : in out Image_String;
47 Index : Integer;
48 V : Integer_64);
49 -- Insert string representation of V in S starting at position Index
51 ---------------
52 -- To_Signed --
53 ---------------
55 function To_Signed is
56 new Ada.Unchecked_Conversion (Unsigned_32, Integer_32);
57 function To_Signed is
58 new Ada.Unchecked_Conversion (Unsigned_64, Integer_64);
60 ------------------
61 -- Insert_Image --
62 ------------------
64 procedure Insert_Image
65 (S : in out Image_String;
66 Index : Integer;
67 V : Integer_64)
69 Image : constant String := Integer_64'Image (V);
70 begin
71 S (Index .. Index + Image'Length - 1) := Image;
72 end Insert_Image;
74 ---------------------
75 -- Random_Discrete --
76 ---------------------
78 function Random_Discrete
79 (Gen : Generator;
80 Min : Result_Subtype := Default_Min;
81 Max : Result_Subtype := Result_Subtype'Last) return Result_Subtype
83 function F is
84 new System.Random_Numbers.Random_Discrete
85 (Result_Subtype, Default_Min);
86 begin
87 return F (Gen.Rep, Min, Max);
88 end Random_Discrete;
90 ------------
91 -- Random --
92 ------------
94 function Random (Gen : Generator) return Float is
95 begin
96 return Random (Gen.Rep);
97 end Random;
99 function Random (Gen : Generator) return Long_Float is
100 begin
101 return Random (Gen.Rep);
102 end Random;
104 function Random (Gen : Generator) return Interfaces.Unsigned_32 is
105 begin
106 return Random (Gen.Rep);
107 end Random;
109 function Random (Gen : Generator) return Interfaces.Unsigned_64 is
110 begin
111 return Random (Gen.Rep);
112 end Random;
114 function Random (Gen : Generator) return Integer_64 is
115 begin
116 return To_Signed (Unsigned_64'(Random (Gen)));
117 end Random;
119 function Random (Gen : Generator) return Integer_32 is
120 begin
121 return To_Signed (Unsigned_32'(Random (Gen)));
122 end Random;
124 function Random (Gen : Generator) return Long_Integer is
125 function Random_Long_Integer is new Random_Discrete (Long_Integer);
126 begin
127 return Random_Long_Integer (Gen);
128 end Random;
130 function Random (Gen : Generator) return Integer is
131 function Random_Integer is new Random_Discrete (Integer);
132 begin
133 return Random_Integer (Gen);
134 end Random;
136 ------------------
137 -- Random_Float --
138 ------------------
140 function Random_Float (Gen : Generator) return Result_Subtype is
141 function F is new System.Random_Numbers.Random_Float (Result_Subtype);
142 begin
143 return F (Gen.Rep);
144 end Random_Float;
146 ---------------------
147 -- Random_Gaussian --
148 ---------------------
150 -- Generates pairs of normally distributed values using the polar method of
151 -- G. E. P. Box, M. E. Muller, and G. Marsaglia. See Donald E. Knuth, The
152 -- Art of Computer Programming, Vol 2: Seminumerical Algorithms, section
153 -- 3.4.1, subsection C, algorithm P. Returns half of the pair on each call,
154 -- using the Next_Gaussian field of Gen to hold the second member on
155 -- even-numbered calls.
157 function Random_Gaussian (Gen : Generator) return Long_Float is
158 G : Generator renames Gen'Unrestricted_Access.all;
160 V1, V2, Rad2, Mult : Long_Float;
162 begin
163 if G.Have_Gaussian then
164 G.Have_Gaussian := False;
165 return G.Next_Gaussian;
167 else
168 loop
169 V1 := 2.0 * Random (G) - 1.0;
170 V2 := 2.0 * Random (G) - 1.0;
171 Rad2 := V1 ** 2 + V2 ** 2;
172 exit when Rad2 < 1.0 and then Rad2 /= 0.0;
173 end loop;
175 -- Now V1 and V2 are coordinates in the unit circle
177 Mult := Sqrt (-2.0 * Log (Rad2) / Rad2);
178 G.Next_Gaussian := V2 * Mult;
179 G.Have_Gaussian := True;
180 return Long_Float'Machine (V1 * Mult);
181 end if;
182 end Random_Gaussian;
184 function Random_Gaussian (Gen : Generator) return Float is
185 V : constant Long_Float := Random_Gaussian (Gen);
186 begin
187 return Float'Machine (Float (V));
188 end Random_Gaussian;
190 -----------
191 -- Reset --
192 -----------
194 procedure Reset (Gen : out Generator) is
195 begin
196 Reset (Gen.Rep);
197 Gen.Have_Gaussian := False;
198 end Reset;
200 procedure Reset
201 (Gen : out Generator;
202 Initiator : Initialization_Vector)
204 begin
205 Reset (Gen.Rep, Initiator);
206 Gen.Have_Gaussian := False;
207 end Reset;
209 procedure Reset
210 (Gen : out Generator;
211 Initiator : Interfaces.Integer_32)
213 begin
214 Reset (Gen.Rep, Initiator);
215 Gen.Have_Gaussian := False;
216 end Reset;
218 procedure Reset
219 (Gen : out Generator;
220 Initiator : Interfaces.Unsigned_32)
222 begin
223 Reset (Gen.Rep, Initiator);
224 Gen.Have_Gaussian := False;
225 end Reset;
227 procedure Reset
228 (Gen : out Generator;
229 Initiator : Integer)
231 begin
232 Reset (Gen.Rep, Initiator);
233 Gen.Have_Gaussian := False;
234 end Reset;
236 procedure Reset
237 (Gen : out Generator;
238 From_State : Generator)
240 begin
241 Reset (Gen.Rep, From_State.Rep);
242 Gen.Have_Gaussian := From_State.Have_Gaussian;
243 Gen.Next_Gaussian := From_State.Next_Gaussian;
244 end Reset;
246 Frac_Scale : constant Long_Float :=
247 Long_Float
248 (Long_Float'Machine_Radix) ** Long_Float'Machine_Mantissa;
250 function Val64 (Image : String) return Integer_64;
251 -- Renames Integer64'Value
252 -- We cannot use a 'renames Integer64'Value' since for some strange
253 -- reason, this requires a dependency on s-auxdec.ads which not all
254 -- run-times support ???
256 function Val64 (Image : String) return Integer_64 is
257 begin
258 return Integer_64'Value (Image);
259 end Val64;
261 procedure Reset
262 (Gen : out Generator;
263 From_Image : String)
265 F0 : constant Integer := From_Image'First;
266 T0 : constant Integer := From_Image'First + Sys_Max_Image_Width;
268 begin
269 Reset (Gen.Rep, From_Image (F0 .. F0 + Sys_Max_Image_Width));
271 if From_Image (T0 + 1) = '1' then
272 Gen.Have_Gaussian := True;
273 Gen.Next_Gaussian :=
274 Long_Float (Val64 (From_Image (T0 + 3 .. T0 + 23))) / Frac_Scale
275 * Long_Float (Long_Float'Machine_Radix)
276 ** Integer (Val64 (From_Image (T0 + 25 .. From_Image'Last)));
277 else
278 Gen.Have_Gaussian := False;
279 end if;
280 end Reset;
282 -----------
283 -- Image --
284 -----------
286 function Image (Gen : Generator) return String is
287 Result : Image_String;
289 begin
290 Result := (others => ' ');
291 Result (1 .. Sys_Max_Image_Width) := Image (Gen.Rep);
293 if Gen.Have_Gaussian then
294 Result (Sys_Max_Image_Width + 2) := '1';
295 Insert_Image (Result, Sys_Max_Image_Width + 4,
296 Integer_64 (Long_Float'Fraction (Gen.Next_Gaussian)
297 * Frac_Scale));
298 Insert_Image (Result, Sys_Max_Image_Width + 24,
299 Integer_64 (Long_Float'Exponent (Gen.Next_Gaussian)));
301 else
302 Result (Sys_Max_Image_Width + 2) := '0';
303 end if;
305 return Result;
306 end Image;
308 end GNAT.Random_Numbers;