source: src/libcfa/stdlib.c@ 461bfef

//
// Cforall Version 1.0.0 Copyright (C) 2016 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// algorithm.c --
//
// Author           : Peter A. Buhr
// Created On       : Thu Jan 28 17:10:29 2016
// Last Modified By : Peter A. Buhr
// Last Modified On : Thu Jul 20 16:01:40 2017
// Update Count     : 282
//

#include "stdlib"

//---------------------------------------

#define _XOPEN_SOURCE 600                                                               // posix_memalign, *rand48
#include <stdlib.h>                                                                             // malloc, free, calloc, realloc, memalign, posix_memalign, bsearch
#include <string.h>                                                                             // memcpy, memset
#include <malloc.h>                                                                             // malloc_usable_size
#include <math.h>                                                                               // fabsf, fabs, fabsl
#include <complex.h>                                                                    // _Complex_I

// resize, non-array types
forall( dtype T | sized(T) ) T * alloc( T ptr[], size_t dim, char fill ) {
        size_t olen = malloc_usable_size( ptr );                        // current allocation
    char * nptr = (void *)realloc( (void *)ptr, dim * (size_t)sizeof(T) ); // C realloc
        size_t nlen = malloc_usable_size( nptr );                       // new allocation
        if ( nlen > olen ) {                                                            // larger ?
                memset( nptr + olen, (int)fill, nlen - olen );  // initialize added storage
        } // 
    return (T *)nptr;
} // alloc

// allocation/deallocation and constructor/destructor, non-array types
forall( dtype T | sized(T), ttype Params | { void ?{}( T *, Params ); } )
T * new( Params p ) {
        return (malloc()){ p };                                                         // run constructor
} // new

forall( dtype T | { void ^?{}( T * ); } )
void delete( T * ptr ) {
        if ( ptr ) {                                                                            // ignore null
                ^ptr{};                                                                                 // run destructor
                free( ptr );
        } // if
} // delete

forall( dtype T, ttype Params | { void ^?{}( T * ); void delete( Params ); } )
void delete( T * ptr, Params rest ) {
        if ( ptr ) {                                                                            // ignore null
                ^ptr{};                                                                                 // run destructor
                free( ptr );
        } // if
        delete( rest );
} // delete


// allocation/deallocation and constructor/destructor, array types
forall( dtype T | sized(T), ttype Params | { void ?{}( T *, Params ); } )
T * anew( size_t dim, Params p ) {
        T *arr = alloc( dim );
        for ( unsigned int i = 0; i < dim; i += 1 ) {
                (&arr[i]){ p };                                                                 // run constructor
        } // for
        return arr;
} // anew

forall( dtype T | sized(T) | { void ^?{}( T * ); } )
void adelete( size_t dim, T arr[] ) {
        if ( arr ) {                                                                            // ignore null
                for ( int i = dim - 1; i >= 0; i -= 1 ) {               // reverse allocation order, must be unsigned
                        ^(&arr[i]){};                                                           // run destructor
                } // for
                free( arr );
        } // if
} // adelete

forall( dtype T | sized(T) | { void ^?{}( T * ); }, ttype Params | { void adelete( Params ); } )
void adelete( size_t dim, T arr[], Params rest ) {
        if ( arr ) {                                                                            // ignore null
                for ( int i = dim - 1; i >= 0; i -= 1 ) {               // reverse allocation order, must be unsigned
                        ^(&arr[i]){};                                                           // run destructor
                } // for
                free( arr );
        } // if
        adelete( rest );
} // adelete

//---------------------------------------

int ato( const char * ptr ) {
        int i;
        if ( sscanf( ptr, "%d", &i ) == EOF ) {}
        return i;
} // ato

unsigned int ato( const char * ptr ) {
        unsigned int ui;
        if ( sscanf( ptr, "%u", &ui ) == EOF ) {}
        return ui;
} // ato

long int ato( const char * ptr ) {
        long int li;
        if ( sscanf( ptr, "%ld", &li ) == EOF ) {}
        return li;
} // ato

unsigned long int ato( const char * ptr ) {
        unsigned long int uli;
        if ( sscanf( ptr, "%lu", &uli ) == EOF ) {}
        return uli;
} // ato

long long int ato( const char * ptr ) {
        long long int lli;
        if ( sscanf( ptr, "%lld", &lli ) == EOF ) {}
        return lli;
} // ato

unsigned long long int ato( const char * ptr ) {
        unsigned long long int ulli;
        if ( sscanf( ptr, "%llu", &ulli ) == EOF ) {}
        return ulli;
} // ato


float ato( const char * ptr ) {
        float f;
        if ( sscanf( ptr, "%f", &f ) == EOF ) {}
        return f;
} // ato

double ato( const char * ptr ) {
        double d;
        if ( sscanf( ptr, "%lf", &d ) == EOF ) {}
        return d;
} // ato

long double ato( const char * ptr ) {
        long double ld;
        if ( sscanf( ptr, "%Lf", &ld ) == EOF ) {}
        return ld;
} // ato


float _Complex ato( const char * ptr ) {
        float re, im;
        if ( sscanf( ptr, "%g%gi", &re, &im ) == EOF ) {}
        return re + im * _Complex_I;
} // ato

double _Complex ato( const char * ptr ) {
        double re, im;
        if ( sscanf( ptr, "%lf%lfi", &re, &im ) == EOF ) {}
        return re + im * _Complex_I;
} // ato

long double _Complex ato( const char * ptr ) {
        long double re, im;
        if ( sscanf( ptr, "%Lf%Lfi", &re, &im ) == EOF ) {}
        return re + im * _Complex_I;
} // ato


int strto( const char * sptr, char ** eptr, int base ) {
        return (int)strtol( sptr, eptr, base );
} // strto

unsigned int strto( const char * sptr, char ** eptr, int base ) {
        return (unsigned int)strtoul( sptr, eptr, base );
} // strto

long int strto( const char * sptr, char ** eptr, int base ) {
        return strtol( sptr, eptr, base );
} // strto

unsigned long int strto( const char * sptr, char ** eptr, int base ) {
        return strtoul( sptr, eptr, base );
} // strto

long long int strto( const char * sptr, char ** eptr, int base ) {
        return strtoll( sptr, eptr, base );
} // strto

unsigned long long int strto( const char * sptr, char ** eptr, int base ) {
        return strtoull( sptr, eptr, base );
} // strto


float strto( const char * sptr, char ** eptr ) {
        return strtof( sptr, eptr );
} // strto

double strto( const char * sptr, char ** eptr ) {
        return strtod( sptr, eptr );
} // strto

long double strto( const char * sptr, char ** eptr ) {
        return strtold( sptr, eptr );
} // strto


float _Complex strto( const char * sptr, char ** eptr ) {
        float re, im;
        re = strtof( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        im = strtof( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        return re + im * _Complex_I;
} // strto

double _Complex strto( const char * sptr, char ** eptr ) {
        double re, im;
        re = strtod( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        im = strtod( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        return re + im * _Complex_I;
} // strto

long double _Complex strto( const char * sptr, char ** eptr ) {
        long double re, im;
        re = strtold( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        im = strtold( sptr, eptr );
        if ( sptr == *eptr ) return 0.0;
        return re + im * _Complex_I;
} // strto

//---------------------------------------

forall( otype T | { int ?<?( T, T ); } )
T * bsearch( T key, const T * arr, size_t dim ) {
        int comp( const void * t1, const void * t2 ) { return *(T *)t1 < *(T *)t2 ? -1 : *(T *)t2 < *(T *)t1 ? 1 : 0; }
        return (T *)bsearch( &key, arr, dim, sizeof(T), comp );
} // bsearch

forall( otype T | { int ?<?( T, T ); } )
unsigned int bsearch( T key, const T * arr, size_t dim ) {
        T *result = bsearch( key, arr, dim );
        return result ? result - arr : dim;                                     // pointer subtraction includes sizeof(T)
} // bsearch

forall( otype T | { int ?<?( T, T ); } )
void qsort( const T * arr, size_t dim ) {
        int comp( const void * t1, const void * t2 ) { return *(T *)t1 < *(T *)t2 ? -1 : *(T *)t2 < *(T *)t1 ? 1 : 0; }
        qsort( arr, dim, sizeof(T), comp );
} // qsort

//---------------------------------------

forall( otype T | { T ?/?( T, T ); T ?%?( T, T ); } )
[ T, T ] div( T t1, T t2 ) { return [ t1 / t2, t1 % t2 ]; }

//---------------------------------------

unsigned char abs( signed char v ) { return abs( (int)v ); }
unsigned long int abs( long int v ) { return labs( v ); }
unsigned long long int abs( long long int v ) { return llabs( v ); }
float abs( float x ) { return fabsf( x ); }
double abs( double x ) { return fabs( x ); }
long double abs( long double x ) { return fabsl( x ); }
float abs( float _Complex x ) { return cabsf( x ); }
double abs( double _Complex x ) { return cabs( x ); }
long double abs( long double _Complex x ) { return cabsl( x ); }

//---------------------------------------

void rand48seed( long int s ) { srand48( s ); }
char rand48( void ) { return mrand48(); }
int rand48( void ) { return mrand48(); }
unsigned int rand48( void ) { return lrand48(); }
long int rand48( void ) { return mrand48(); }
unsigned long int rand48( void ) { return lrand48(); }
float rand48( void ) { return (float)drand48(); }               // otherwise float uses lrand48
double rand48( void ) { return drand48(); }
float _Complex rand48( void ) { return (float)drand48() + (float _Complex)(drand48() * _Complex_I); }
double _Complex rand48( void ) { return drand48() + (double _Complex)(drand48() * _Complex_I); }
long double _Complex rand48( void) { return (long double)drand48() + (long double _Complex)(drand48() * _Complex_I); }

//---------------------------------------

forall( otype T | { int ?<?( T, T ); } )
T min( T t1, T t2 ) {
        return t1 < t2 ? t1 : t2;
} // min

forall( otype T | { int ?>?( T, T ); } )
T max( T t1, T t2 ) {
        return t1 > t2 ? t1 : t2;
} // max

forall( otype T | { T min( T, T ); T max( T, T ); } )
T clamp( T value, T min_val, T max_val ) {
        return max( min_val, min( value, max_val ) );
} // clamp

forall( otype T )
void swap( T * t1, T * t2 ) {
        T temp = *t1;
        *t1 = *t2;
        *t2 = temp;
} // swap

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