source: libcfa/src/stdlib.cfa@ 33e62f1b

ADT arm-eh ast-experimental enum forall-pointer-decay jacob/cs343-translation new-ast new-ast-unique-expr pthread-emulation qualifiedEnum
Last change on this file since 33e62f1b was 76e2113, checked in by Peter A. Buhr <pabuhr@…>, 6 years ago

add setter routines for sticky operations, add allocation size to header
  • Property mode set to 100644
File size: 9.6 KB
Line 
1//
2// Cforall Version 1.0.0 Copyright (C) 2016 University of Waterloo
3//
4// The contents of this file are covered under the licence agreement in the
5// file "LICENCE" distributed with Cforall.
6//
7// stdlib.c --
8//
9// Author : Peter A. Buhr
10// Created On : Thu Jan 28 17:10:29 2016
11// Last Modified By : Peter A. Buhr
12// Last Modified On : Thu Apr 16 22:43:33 2020
13// Update Count : 498
14//
15
16#include "stdlib.hfa"
17
18//---------------------------------------
19
20#define _XOPEN_SOURCE 600 // posix_memalign, *rand48
21#include <string.h> // memcpy, memset
22//#include <math.h> // fabsf, fabs, fabsl
23#include <complex.h> // _Complex_I
24#include <assert.h>
25
26//---------------------------------------
27
28forall( dtype T | sized(T) ) {
29 T * alloc_set( T ptr[], size_t dim, char fill ) { // realloc array with fill
30 size_t olen = malloc_usable_size( ptr ); // current allocation
31 void * nptr = (void *)realloc( (void *)ptr, dim * sizeof(T) ); // C realloc
32 size_t nlen = malloc_usable_size( nptr ); // new allocation
33 if ( nlen > olen ) { // larger ?
34 memset( (char *)nptr + olen, (int)fill, nlen - olen ); // initialize added storage
35 } // if
36 return (T *)nptr;
37 } // alloc_set
38
39 T * alloc_set( T ptr[], size_t dim, T fill ) { // realloc array with fill
40 size_t olen = malloc_usable_size( ptr ); // current allocation
41 void * nptr = (void *)realloc( (void *)ptr, dim * sizeof(T) ); // C realloc
42 size_t nlen = malloc_usable_size( nptr ); // new allocation
43 if ( nlen > olen ) { // larger ?
44 for ( i; malloc_size( ptr ) / sizeof(T) ~ dim ) {
45 memcpy( &ptr[i], &fill, sizeof(T) ); // initialize with fill value
46 } // for
47 } // if
48 return (T *)nptr;
49 } // alloc_align_set
50
51 T * alloc_align_set( T ptr[], size_t align, char fill ) { // aligned realloc with fill
52 size_t olen = malloc_usable_size( ptr ); // current allocation
53 void * nptr = (void *)realloc( (void *)ptr, align, sizeof(T) ); // CFA realloc
54 // char * nptr = alloc_align( ptr, align );
55 size_t nlen = malloc_usable_size( nptr ); // new allocation
56 if ( nlen > olen ) { // larger ?
57 memset( (char *)nptr + olen, (int)fill, nlen - olen ); // initialize added storage
58 } // if
59 return (T *)nptr;
60 } // alloc_align_set
61
62 T * alloc_align_set( T ptr[], size_t align, size_t dim, T fill ) { // aligned realloc with fill
63 size_t olen = malloc_usable_size( ptr ); // current allocation
64 void * nptr = (void *)realloc( (void *)ptr, align, sizeof(T) ); // CFA realloc
65 // char * nptr = alloc_align( ptr, align );
66 size_t nlen = malloc_usable_size( nptr ); // new allocation
67 if ( nlen > olen ) { // larger ?
68 for ( i; dim ) { memcpy( &ptr[i], &fill, sizeof(T) ); } // initialize with fill value
69 } // if
70 return (T *)nptr;
71 } // alloc_align_set
72} // distribution
73
74// allocation/deallocation and constructor/destructor, non-array types
75forall( dtype T | sized(T), ttype Params | { void ?{}( T &, Params ); } )
76T * new( Params p ) {
77 return &(*malloc()){ p }; // run constructor
78} // new
79
80forall( dtype T | sized(T) | { void ^?{}( T & ); } )
81void delete( T * ptr ) {
82 if ( ptr ) { // ignore null
83 ^(*ptr){}; // run destructor
84 free( ptr );
85 } // if
86} // delete
87
88forall( dtype T, ttype Params | sized(T) | { void ^?{}( T & ); void delete( Params ); } )
89void delete( T * ptr, Params rest ) {
90 if ( ptr ) { // ignore null
91 ^(*ptr){}; // run destructor
92 free( ptr );
93 } // if
94 delete( rest );
95} // delete
96
97
98// allocation/deallocation and constructor/destructor, array types
99forall( dtype T | sized(T), ttype Params | { void ?{}( T &, Params ); } )
100T * anew( size_t dim, Params p ) {
101 T * arr = alloc( dim );
102 for ( unsigned int i = 0; i < dim; i += 1 ) {
103 (arr[i]){ p }; // run constructor
104 } // for
105 return arr;
106} // anew
107
108forall( dtype T | sized(T) | { void ^?{}( T & ); } )
109void adelete( size_t dim, T arr[] ) {
110 if ( arr ) { // ignore null
111 for ( int i = dim - 1; i >= 0; i -= 1 ) { // reverse allocation order, must be unsigned
112 ^(arr[i]){}; // run destructor
113 } // for
114 free( arr );
115 } // if
116} // adelete
117
118forall( dtype T | sized(T) | { void ^?{}( T & ); }, ttype Params | { void adelete( Params ); } )
119void adelete( size_t dim, T arr[], Params rest ) {
120 if ( arr ) { // ignore null
121 for ( int i = dim - 1; i >= 0; i -= 1 ) { // reverse allocation order, must be unsigned
122 ^(arr[i]){}; // run destructor
123 } // for
124 free( arr );
125 } // if
126 adelete( rest );
127} // adelete
128
129//---------------------------------------
130
131float _Complex strto( const char sptr[], char ** eptr ) {
132 float re, im;
133 char * eeptr;
134 re = strtof( sptr, &eeptr );
135 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0f + 0.0f * _Complex_I; }
136 im = strtof( eeptr, &eeptr );
137 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0f + 0.0f * _Complex_I; }
138 if ( *eeptr != 'i' ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0f + 0.0f * _Complex_I; }
139 return re + im * _Complex_I;
140} // strto
141
142double _Complex strto( const char sptr[], char ** eptr ) {
143 double re, im;
144 char * eeptr;
145 re = strtod( sptr, &eeptr );
146 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0 + 0.0 * _Complex_I; }
147 im = strtod( eeptr, &eeptr );
148 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0 + 0.0 * _Complex_I; }
149 if ( *eeptr != 'i' ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0 + 0.0 * _Complex_I; }
150 return re + im * _Complex_I;
151} // strto
152
153long double _Complex strto( const char sptr[], char ** eptr ) {
154 long double re, im;
155 char * eeptr;
156 re = strtold( sptr, &eeptr );
157 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0L + 0.0L * _Complex_I; }
158 im = strtold( eeptr, &eeptr );
159 if ( sptr == eeptr ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0L + 0.0L * _Complex_I; }
160 if ( *eeptr != 'i' ) { if ( eptr != 0 ) *eptr = eeptr; return 0.0L + 0.0L * _Complex_I; }
161 return re + im * _Complex_I;
162} // strto
163
164//---------------------------------------
165
166forall( otype E | { int ?<?( E, E ); } ) {
167 E * bsearch( E key, const E * vals, size_t dim ) {
168 int cmp( const void * t1, const void * t2 ) {
169 return *(E *)t1 < *(E *)t2 ? -1 : *(E *)t2 < *(E *)t1 ? 1 : 0;
170 } // cmp
171 return (E *)bsearch( &key, vals, dim, sizeof(E), cmp );
172 } // bsearch
173
174 size_t bsearch( E key, const E * vals, size_t dim ) {
175 E * result = bsearch( key, vals, dim );
176 return result ? result - vals : dim; // pointer subtraction includes sizeof(E)
177 } // bsearch
178
179 size_t bsearchl( E key, const E * vals, size_t dim ) {
180 size_t l = 0, m, h = dim;
181 while ( l < h ) {
182 m = (l + h) / 2;
183 if ( (E &)(vals[m]) < key ) { // cast away const
184 l = m + 1;
185 } else {
186 h = m;
187 } // if
188 } // while
189 return l;
190 } // bsearchl
191
192 E * bsearchl( E key, const E * vals, size_t dim ) {
193 size_t posn = bsearchl( key, vals, dim );
194 return (E *)(&vals[posn]); // cast away const
195 } // bsearchl
196
197 size_t bsearchu( E key, const E * vals, size_t dim ) {
198 size_t l = 0, m, h = dim;
199 while ( l < h ) {
200 m = (l + h) / 2;
201 if ( ! ( key < (E &)(vals[m]) ) ) { // cast away const
202 l = m + 1;
203 } else {
204 h = m;
205 } // if
206 } // while
207 return l;
208 } // bsearchu
209
210 E * bsearchu( E key, const E * vals, size_t dim ) {
211 size_t posn = bsearchu( key, vals, dim );
212 return (E *)(&vals[posn]);
213 } // bsearchu
214
215
216 void qsort( E * vals, size_t dim ) {
217 int cmp( const void * t1, const void * t2 ) {
218 return *(E *)t1 < *(E *)t2 ? -1 : *(E *)t2 < *(E *)t1 ? 1 : 0;
219 } // cmp
220 qsort( vals, dim, sizeof(E), cmp );
221 } // qsort
222} // distribution
223
224
225forall( otype K, otype E | { int ?<?( K, K ); K getKey( const E & ); } ) {
226 E * bsearch( K key, const E * vals, size_t dim ) {
227 int cmp( const void * t1, const void * t2 ) {
228 return *(K *)t1 < getKey( *(E *)t2 ) ? -1 : getKey( *(E *)t2 ) < *(K *)t1 ? 1 : 0;
229 } // cmp
230 return (E *)bsearch( &key, vals, dim, sizeof(E), cmp );
231 } // bsearch
232
233 size_t bsearch( K key, const E * vals, size_t dim ) {
234 E * result = bsearch( key, vals, dim );
235 return result ? result - vals : dim; // pointer subtraction includes sizeof(E)
236 } // bsearch
237
238 size_t bsearchl( K key, const E * vals, size_t dim ) {
239 size_t l = 0, m, h = dim;
240 while ( l < h ) {
241 m = (l + h) / 2;
242 if ( getKey( vals[m] ) < key ) {
243 l = m + 1;
244 } else {
245 h = m;
246 } // if
247 } // while
248 return l;
249 } // bsearchl
250
251 E * bsearchl( K key, const E * vals, size_t dim ) {
252 size_t posn = bsearchl( key, vals, dim );
253 return (E *)(&vals[posn]); // cast away const
254 } // bsearchl
255
256 size_t bsearchu( K key, const E * vals, size_t dim ) {
257 size_t l = 0, m, h = dim;
258 while ( l < h ) {
259 m = (l + h) / 2;
260 if ( ! ( key < getKey( vals[m] ) ) ) {
261 l = m + 1;
262 } else {
263 h = m;
264 } // if
265 } // while
266 return l;
267 } // bsearchu
268
269 E * bsearchu( K key, const E * vals, size_t dim ) {
270 size_t posn = bsearchu( key, vals, dim );
271 return (E *)(&vals[posn]);
272 } // bsearchu
273} // distribution
274
275//---------------------------------------
276
277extern "C" { // override C version
278 void srandom( unsigned int seed ) { srand48( (long int)seed ); }
279 long int random( void ) { return mrand48(); }
280} // extern "C"
281
282float random( void ) { return (float)drand48(); } // cast otherwise float uses lrand48
283double random( void ) { return drand48(); }
284float _Complex random( void ) { return (float)drand48() + (float _Complex)(drand48() * _Complex_I); }
285double _Complex random( void ) { return drand48() + (double _Complex)(drand48() * _Complex_I); }
286long double _Complex random( void ) { return (long double)drand48() + (long double _Complex)(drand48() * _Complex_I); }
287
288//---------------------------------------
289
290bool threading_enabled(void) __attribute__((weak)) {
291 return false;
292}
293
294// Local Variables: //
295// tab-width: 4 //
296// End: //
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