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stdlib.cfa@ 33e62f1b

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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

Rev	Line
[bd85400]	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	//
[f4a6101]	7	// stdlib.c --
[bd85400]	8	//
	9	// Author : Peter A. Buhr
	10	// Created On : Thu Jan 28 17:10:29 2016
	11	// Last Modified By : Peter A. Buhr
[76e2113]	12	// Last Modified On : Thu Apr 16 22:43:33 2020
	13	// Update Count : 498
[bd85400]	14	//
	15
[58b6d1b]	16	#include "stdlib.hfa"
[bd85400]	17
	18	//---------------------------------------
	19
	20	#define _XOPEN_SOURCE 600 // posix_memalign, *rand48
[f3fc631f]	21	#include <string.h> // memcpy, memset
[89124ff]	22	//#include <math.h> // fabsf, fabs, fabsl
[6e991d6]	23	#include <complex.h> // _Complex_I
[e672372]	24	#include <assert.h>
[bd85400]	25
[f4a6101]	26	//---------------------------------------
	27
[cafb687]	28	forall( 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
[d74369b]	31	void * nptr = (void )realloc( (void )ptr, dim * sizeof(T) ); // C realloc
[cafb687]	32	size_t nlen = malloc_usable_size( nptr ); // new allocation
	33	if ( nlen > olen ) { // larger ?
[d74369b]	34	memset( (char *)nptr + olen, (int)fill, nlen - olen ); // initialize added storage
[cafb687]	35	} // if
	36	return (T *)nptr;
	37	} // alloc_set
	38
[76e2113]	39	T * alloc_set( T ptr[], size_t dim, T fill ) { // realloc array with fill
[cfbc703d]	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 ?
[76e2113]	44	for ( i; malloc_size( ptr ) / sizeof(T) ~ dim ) {
	45	memcpy( &ptr[i], &fill, sizeof(T) ); // initialize with fill value
	46	} // for
[cfbc703d]	47	} // if
	48	return (T *)nptr;
	49	} // alloc_align_set
	50
[cafb687]	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
[d74369b]	53	void * nptr = (void )realloc( (void )ptr, align, sizeof(T) ); // CFA realloc
	54	// char * nptr = alloc_align( ptr, align );
[cafb687]	55	size_t nlen = malloc_usable_size( nptr ); // new allocation
	56	if ( nlen > olen ) { // larger ?
[d74369b]	57	memset( (char *)nptr + olen, (int)fill, nlen - olen ); // initialize added storage
[cafb687]	58	} // if
	59	return (T *)nptr;
	60	} // alloc_align_set
[cfbc703d]	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
[cafb687]	72	} // distribution
[f3ddc21]	73
[6065b3aa]	74	// allocation/deallocation and constructor/destructor, non-array types
[aca65621]	75	forall( dtype T \| sized(T), ttype Params \| { void ?{}( T &, Params ); } )
[627f585]	76	T * new( Params p ) {
[cafb687]	77	return &(*malloc()){ p }; // run constructor
[f3ddc21]	78	} // new
[627f585]	79
[83a071f9]	80	forall( dtype T \| sized(T) \| { void ^?{}( T & ); } )
[627f585]	81	void delete( T * ptr ) {
[6065b3aa]	82	if ( ptr ) { // ignore null
[cafb687]	83	^(*ptr){}; // run destructor
[f3ddc21]	84	free( ptr );
[f3fc631f]	85	} // if
[f3ddc21]	86	} // delete
[627f585]	87
[83a071f9]	88	forall( dtype T, ttype Params \| sized(T) \| { void ^?{}( T & ); void delete( Params ); } )
[bf76eab]	89	void delete( T * ptr, Params rest ) {
[6065b3aa]	90	if ( ptr ) { // ignore null
[cafb687]	91	^(*ptr){}; // run destructor
[bf76eab]	92	free( ptr );
[f3fc631f]	93	} // if
[bf76eab]	94	delete( rest );
[f3ddc21]	95	} // delete
[bf76eab]	96
[6065b3aa]	97
	98	// allocation/deallocation and constructor/destructor, array types
[aca65621]	99	forall( dtype T \| sized(T), ttype Params \| { void ?{}( T &, Params ); } )
[6065b3aa]	100	T * anew( size_t dim, Params p ) {
[6887a99]	101	T * arr = alloc( dim );
[6065b3aa]	102	for ( unsigned int i = 0; i < dim; i += 1 ) {
[a493682]	103	(arr[i]){ p }; // run constructor
[6065b3aa]	104	} // for
	105	return arr;
	106	} // anew
	107
[aca65621]	108	forall( dtype T \| sized(T) \| { void ^?{}( T & ); } )
[6065b3aa]	109	void 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
[a493682]	112	^(arr[i]){}; // run destructor
[6065b3aa]	113	} // for
	114	free( arr );
	115	} // if
	116	} // adelete
	117
[aca65621]	118	forall( dtype T \| sized(T) \| { void ^?{}( T & ); }, ttype Params \| { void adelete( Params ); } )
[6065b3aa]	119	void 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
[a493682]	122	^(arr[i]){}; // run destructor
[6065b3aa]	123	} // for
	124	free( arr );
	125	} // if
	126	adelete( rest );
	127	} // adelete
	128
[bd85400]	129	//---------------------------------------
	130
[e3fea42]	131	float _Complex strto( const char sptr[], char ** eptr ) {
[bd85400]	132	float re, im;
[e672372]	133	char * eeptr;
	134	re = strtof( sptr, &eeptr );
[bbf3fda]	135	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0f + 0.0f _Complex_I; }
[e672372]	136	im = strtof( eeptr, &eeptr );
[bbf3fda]	137	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0f + 0.0f _Complex_I; }
[e672372]	138	if ( eeptr != 'i' ) { if ( eptr != 0 ) eptr = eeptr; return 0.0f + 0.0f * _Complex_I; }
[bd85400]	139	return re + im * _Complex_I;
[f3ddc21]	140	} // strto
	141
[e3fea42]	142	double _Complex strto( const char sptr[], char ** eptr ) {
[bd85400]	143	double re, im;
[e672372]	144	char * eeptr;
	145	re = strtod( sptr, &eeptr );
[bbf3fda]	146	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0 + 0.0 _Complex_I; }
[e672372]	147	im = strtod( eeptr, &eeptr );
[bbf3fda]	148	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0 + 0.0 _Complex_I; }
[e672372]	149	if ( eeptr != 'i' ) { if ( eptr != 0 ) eptr = eeptr; return 0.0 + 0.0 * _Complex_I; }
[bd85400]	150	return re + im * _Complex_I;
[f3ddc21]	151	} // strto
	152
[e3fea42]	153	long double _Complex strto( const char sptr[], char ** eptr ) {
[bd85400]	154	long double re, im;
[e672372]	155	char * eeptr;
	156	re = strtold( sptr, &eeptr );
[bbf3fda]	157	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0L + 0.0L _Complex_I; }
[e672372]	158	im = strtold( eeptr, &eeptr );
[bbf3fda]	159	if ( sptr == eeptr ) { if ( eptr != 0 ) eptr = eeptr; return 0.0L + 0.0L _Complex_I; }
[e672372]	160	if ( eeptr != 'i' ) { if ( eptr != 0 ) eptr = eeptr; return 0.0L + 0.0L * _Complex_I; }
[bd85400]	161	return re + im * _Complex_I;
[f3ddc21]	162	} // strto
[bd85400]	163
	164	//---------------------------------------
	165
[3ce0d440]	166	forall( 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
	225	forall( 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
[bd85400]	274
	275	//---------------------------------------
	276
[bbe1a87]	277	extern "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
[e672372]	282	float random( void ) { return (float)drand48(); } // cast otherwise float uses lrand48
[70e4895d]	283	double random( void ) { return drand48(); }
	284	float _Complex random( void ) { return (float)drand48() + (float _Complex)(drand48() * _Complex_I); }
	285	double _Complex random( void ) { return drand48() + (double _Complex)(drand48() * _Complex_I); }
[e672372]	286	long double _Complex random( void ) { return (long double)drand48() + (long double _Complex)(drand48() * _Complex_I); }
[a9f2c13]	287
[2026bb6]	288	//---------------------------------------
	289
	290	bool threading_enabled(void) __attribute__((weak)) {
	291	return false;
	292	}
[bd85400]	293
	294	// Local Variables: //
	295	// tab-width: 4 //
	296	// End: //

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