source: src/libcfa/stdlib.c@ c44e622

ADT aaron-thesis arm-eh ast-experimental cleanup-dtors ctor deferred_resn demangler enum forall-pointer-decay gc_noraii jacob/cs343-translation jenkins-sandbox memory new-ast new-ast-unique-expr new-env no_list persistent-indexer pthread-emulation qualifiedEnum resolv-new with_gc
Last change on this file since c44e622 was bd85400, checked in by Peter A. Buhr <pabuhr@…>, 10 years ago

remove offsetof keyword, parser 0/1 names as structure fields, update examples to new stdlib, rename algorithms to stdlib, extend stdlib, use correct type for box parameters
  • Property mode set to 100644
File size: 8.6 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// algorithm.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 : Fri Feb 5 15:41:24 2016
13// Update Count : 128
14//
15
16#include "stdlib"
17
18//---------------------------------------
19
20extern "C" {
21#define _XOPEN_SOURCE 600 // posix_memalign, *rand48
22#include <stdlib.h> // malloc, free, calloc, realloc, memalign, posix_memalign, bsearch
23#include <string.h> // memset
24#include <malloc.h> // malloc_usable_size
25#include <stdio.h>
26#include <math.h> // fabsf, fabs, fabsl
27#include <complex.h> // _Complex_I, cabsf, cabs, cabsl
28} // extern "C"
29
30forall( type T ) T * memset( T * ptr, unsigned char fill ) { // use default value '\0' for fill
31 printf( "memset1\n" );
32 return (T *)memset( ptr, (int)fill, malloc_usable_size( ptr ) );
33} // memset
34forall( type T ) T * memset( T * ptr ) { // remove when default value available
35 printf( "memset2\n" );
36 return (T *)memset( ptr, 0, malloc_usable_size( ptr ) );
37} // memset
38
39forall( type T ) T * malloc( void ) {
40 printf( "malloc1\n" );
41 return (T *)malloc( sizeof(T) );
42} // malloc
43forall( type T ) T * malloc( size_t size ) {
44 printf( "malloc2\n" );
45 return (T *)(void *)malloc( size );
46} // malloc
47forall( type T ) T * malloc( char fill ) {
48 printf( "malloc3\n" );
49 T * ptr = (T *)malloc( sizeof(T) );
50 return memset( ptr );
51} // malloc
52
53forall( type T ) T * calloc( size_t size ) {
54 printf( "calloc\n" );
55 return (T *)calloc( size, sizeof(T) );
56} // calloc
57
58forall( type T ) T * realloc( T * ptr, size_t size ) {
59 printf( "realloc1\n" );
60 return (T *)(void *)realloc( (void *)ptr, size );
61} // realloc
62forall( type T ) T * realloc( T * ptr, size_t size, unsigned char fill ) {
63 printf( "realloc2\n" );
64 char * nptr = (T *)(void *)realloc( (void *)ptr, size );
65 size_t unused = malloc_usable_size( nptr );
66 memset( nptr + size - unused, (int)fill, unused ); // initialize any new storage
67 return nptr;
68} // realloc
69
70forall( type T ) T * malloc( T * ptr, size_t size ) {
71 printf( "malloc4\n" );
72 return (T *)realloc( ptr, size );
73} // malloc
74forall( type T ) T * malloc( T * ptr, size_t size, unsigned char fill ) {
75 printf( "malloc5\n" );
76 return (T *)realloc( ptr, size, fill );
77} // malloc
78
79forall( type T ) T * aligned_alloc( size_t alignment ) {
80 printf( "aligned_alloc\n" );
81 return (T *)memalign( alignment, sizeof(T) );
82} // aligned_alloc
83
84forall( type T ) T * memalign( size_t alignment ) {
85 printf( "memalign\n" );
86 return (T *)memalign( alignment, sizeof(T) );
87} // memalign
88
89forall( type T ) int posix_memalign( T ** ptr, size_t alignment ) {
90 printf( "posix_memalign\n" );
91 return posix_memalign( (void **)ptr, alignment, sizeof(T) );
92} // posix_memalign
93
94//---------------------------------------
95
96int ato( const char * ptr ) {
97 int i;
98 if ( sscanf( ptr, "%d", &i ) == EOF ) {} // check return code
99 return i;
100}
101unsigned int ato( const char * ptr ) {
102 unsigned int ui;
103 if ( sscanf( ptr, "%u", &ui ) == EOF ) {} // check return code
104 return ui;
105}
106long int ato( const char * ptr ) {
107 long int li;
108 if ( sscanf( ptr, "%ld", &li ) == EOF ) {}; // check return code
109 return li;
110}
111unsigned long int ato( const char * ptr ) {
112 unsigned long int uli;
113 if ( sscanf( ptr, "%lu", &uli ) == EOF ) {}; // check return code
114 return uli;
115}
116long long int ato( const char * ptr ) {
117 long long int lli;
118 if ( sscanf( ptr, "%lld", &lli ) == EOF ) {}; // check return code
119 return lli;
120}
121unsigned long long int ato( const char * ptr ) {
122 unsigned long long int ulli;
123 if ( sscanf( ptr, "%llu", &ulli ) == EOF ) {}; // check return code
124 return ulli;
125}
126float ato( const char * ptr ) {
127 float f;
128 if ( sscanf( ptr, "%f", &f ) == EOF ) {}; // check return code
129 return f;
130}
131double ato( const char * ptr ) {
132 double d;
133 if ( sscanf( ptr, "%lf", &d ) == EOF ) {}; // check return code
134 return d;
135}
136long double ato( const char * ptr ) {
137 long double ld;
138 printf( "FRED " );
139 if ( sscanf( ptr, "%.32Lf", &ld ) == EOF ) {}; // check return code
140 return ld;
141}
142float _Complex ato( const char * ptr ) {
143 float re, im;
144 if ( sscanf( ptr, "%g%g", &re, &im ) == EOF ) {}; // check return code
145 return re + im * _Complex_I;
146}
147double _Complex ato( const char * ptr ) {
148 double re, im;
149 if ( sscanf( ptr, "%.16lg%.16lg", &re, &im ) == EOF ) {}; // check return code
150 return re + im * _Complex_I;
151}
152long double _Complex ato( const char * ptr ) {
153 long double re, im;
154 if ( sscanf( ptr, "%.32Lg%.32Lg", &re, &im ) == EOF ) {}; // check return code
155 return re + im * _Complex_I;
156}
157
158int strto( const char * sptr, char ** eptr, int base ) {
159 return (int)strtol( sptr, eptr, base );
160}
161unsigned int strto( const char * sptr, char ** eptr, int base ) {
162 return (unsigned int)strtoul( sptr, eptr, base );
163}
164long int strto( const char * sptr, char ** eptr, int base ) {
165 return strtol( sptr, eptr, base );
166}
167unsigned long int strto( const char * sptr, char ** eptr, int base ) {
168 return strtoul( sptr, eptr, base );
169}
170long long int strto( const char * sptr, char ** eptr, int base ) {
171 return strtoll( sptr, eptr, base );
172}
173unsigned long long int strto( const char * sptr, char ** eptr, int base ) {
174 return strtoull( sptr, eptr, base );
175}
176float strto( const char * sptr, char ** eptr ) {
177 return strtof( sptr, eptr );
178}
179double strto( const char * sptr, char ** eptr ) {
180 return strtod( sptr, eptr );
181}
182long double strto( const char * sptr, char ** eptr ) {
183 return strtold( sptr, eptr );
184}
185float _Complex strto( const char * sptr, char ** eptr ) {
186 float re, im;
187 re = strtof( sptr, eptr );
188 if ( sptr == *eptr ) return 0.0;
189 im = strtof( sptr, eptr );
190 if ( sptr == *eptr ) return 0.0;
191 return re + im * _Complex_I;
192}
193double _Complex strto( const char * sptr, char ** eptr ) {
194 double re, im;
195 re = strtod( sptr, eptr );
196 if ( sptr == *eptr ) return 0.0;
197 im = strtod( sptr, eptr );
198 if ( sptr == *eptr ) return 0.0;
199 return re + im * _Complex_I;
200}
201long double _Complex strto( const char * sptr, char ** eptr ) {
202 long double re, im;
203 re = strtold( sptr, eptr );
204 if ( sptr == *eptr ) return 0.0;
205 im = strtold( sptr, eptr );
206 if ( sptr == *eptr ) return 0.0;
207 return re + im * _Complex_I;
208}
209
210//---------------------------------------
211
212forall( type T | { int ?<?( T, T ); } )
213T * bsearch( const T key, const T * arr, size_t dimension ) {
214 int comp( const void * t1, const void * t2 ) { return *(T *)t1 < *(T *)t2 ? -1 : *(T *)t2 < *(T *)t1 ? 1 : 0; }
215 return (T *)bsearch( &key, arr, dimension, sizeof(T), comp );
216} // bsearch
217
218forall( type T | { int ?<?( T, T ); } )
219void qsort( const T * arr, size_t dimension ) {
220 int comp( const void * t1, const void * t2 ) { return *(T *)t1 < *(T *)t2 ? -1 : *(T *)t2 < *(T *)t1 ? 1 : 0; }
221 qsort( arr, dimension, sizeof(T), comp );
222} // qsort
223
224//---------------------------------------
225
226forall( type T | { T ?/?( T, T ); T ?%?( T, T ); } )
227[ T, T ] div( T t1, T t2 ) { /* return [ t1 / t2, t1 % t2 ]; */ }
228
229//---------------------------------------
230
231char abs( char v ) { return abs( (int)v ); }
232long int abs( long int v ) { return labs( v ); }
233long long int abs( long long int v ) { return llabs( v ); }
234float abs( float v ) { return fabsf( v ); }
235double abs( double v ) { return fabs( v ); }
236long double abs( long double v ) { return fabsl( v ); }
237float _Complex abs( float _Complex v ) { return cabsf( v ); }
238double _Complex abs( double _Complex v ) { return cabs( v ); }
239long double _Complex abs( long double _Complex v ) { return cabsl( v ); }
240
241//---------------------------------------
242
243void randseed( long int s ) { srand48( s ); }
244char random() { return lrand48(); }
245int random() { return mrand48(); }
246unsigned int random() { return lrand48(); }
247long int random() { return mrand48(); }
248unsigned long int random() { return lrand48(); }
249float random() { return (float)drand48(); } // otherwise float uses lrand48
250double random() { return drand48(); }
251float _Complex random() { return (float)drand48() + (float _Complex)(drand48() * _Complex_I); }
252double _Complex random() { return drand48() + (double _Complex)(drand48() * _Complex_I); }
253long double _Complex random() { return (long double)drand48() + (long double _Complex)(drand48() * _Complex_I); }
254
255//---------------------------------------
256
257forall( type T | { int ?<?( T, T ); } )
258T min( const T t1, const T t2 ) {
259 return t1 < t2 ? t1 : t2;
260} // min
261
262forall( type T | { int ?>?( T, T ); } )
263T max( const T t1, const T t2 ) {
264 return t1 > t2 ? t1 : t2;
265} // max
266
267forall( type T )
268void swap( T * t1, T * t2 ) {
269 T temp = *t1;
270 *t1 = *t2;
271 *t2 = temp;
272} // swap
273
274// Local Variables: //
275// tab-width: 4 //
276// End: //
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