// // 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. // // builtins.c -- // // Author : Peter A. Buhr // Created On : Fri Jul 21 16:21:03 2017 // Last Modified By : Peter A. Buhr // Last Modified On : Sun Aug 5 21:40:38 2018 // Update Count : 20 // // exception implementation typedef unsigned long long __cfaabi_abi_exception_type_t; #include "../src/virtual.h" #include "../src/exception.h" void exit( int status, const char fmt[], ... ) __attribute__ (( format(printf, 2, 3), __nothrow__, __leaf__, __noreturn__ )); void abort( const char fmt[], ... ) __attribute__ (( format(printf, 1, 2), __nothrow__, __leaf__, __noreturn__ )); // increment/decrement unification static inline forall( dtype T | { T& ?+=?( T&, one_t ); } ) T& ++? ( T& x ) { return x += 1; } static inline forall( dtype T | sized(T) | { void ?{}( T&, T ); void ^?{}( T& ); T& ?+=?( T&, one_t ); } ) T& ?++ ( T& x ) { T tmp = x; x += 1; return tmp; } static inline forall( dtype T | { T& ?-=?( T&, one_t ); } ) T& --? ( T& x ) { return x -= 1; } static inline forall( dtype T | sized(T) | { void ?{}( T&, T ); void ^?{}( T& ); T& ?-=?( T&, one_t ); } ) T& ?-- ( T& x ) { T tmp = x; x -= 1; return tmp; } // exponentiation operator implementation extern "C" { float powf( float x, float y ); double pow( double x, double y ); long double powl( long double x, long double y ); float _Complex cpowf( float _Complex x, _Complex float z ); double _Complex cpow( double _Complex x, _Complex double z ); long double _Complex cpowl( long double _Complex x, _Complex long double z ); } // extern "C" static inline float ?\?( float x, float y ) { return powf( x, y ); } static inline double ?\?( double x, double y ) { return pow( x, y ); } static inline long double ?\?( long double x, long double y ) { return powl( x, y ); } static inline float _Complex ?\?( float _Complex x, _Complex float y ) { return cpowf(x, y ); } static inline double _Complex ?\?( double _Complex x, _Complex double y ) { return cpow( x, y ); } static inline long double _Complex ?\?( long double _Complex x, _Complex long double y ) { return cpowl( x, y ); } static inline long int ?\?( long int ep, unsigned long int y ) { // disallow negative exponent if ( y == 0 ) return 1; // base case if ( ep == 2 ) return ep << (y - 1); // special case, positive shifting only typeof( ep ) op = 1; // accumulate odd product for ( ; y > 1; y >>= 1 ) { // squaring exponentiation, O(log2 y) if ( (y & 1) == 1 ) op *= ep; // odd ? ep *= ep; } // for return ep * op; } // ?\? static inline forall( otype T | { void ?{}( T & this, one_t ); T ?*?( T, T ); } ) T ?\?( T ep, unsigned long int y ) { if ( y == 0 ) return 1; T op = 1; for ( ; y > 1; y >>= 1 ) { // squaring exponentiation, O(log2 y) if ( (y & 1) == 1 ) op = op * ep; // odd ? ep = ep * ep; } // for return ep * op; } // ?\? // unsigned computation may be faster and larger static inline unsigned long int ?\?( unsigned long int ep, unsigned long int y ) { // disallow negative exponent if ( y == 0 ) return 1; // base case if ( ep == 2 ) return ep << (y - 1); // special case, positive shifting only typeof( ep ) op = 1; // accumulate odd product for ( ; y > 1; y >>= 1 ) { // squaring exponentiation, O(log2 y) if ( (y & 1) == 1 ) op *= ep; // odd ? ep *= ep; } // for return ep * op; } // ?\? static inline double ?\?( long int x, signed long int y ) { // allow negative exponent if ( y >= 0 ) return (double)(x \ (unsigned long int)y); else return 1.0 / x \ (unsigned int)(-y); } // ?\? // FIXME (x \ (unsigned long int)y) relies on X ?\?(T, unsigned long) a function that is neither // defined, nor passed as an assertion parameter. Without user-defined conversions, cannot specify // X as a type that casts to double, yet it doesn't make sense to write functions with that type // signature where X is double. // static inline forall( otype T | { void ?{}( T & this, one_t ); T ?*?( T, T ); double ?/?( double, T ); } ) // double ?\?( T x, signed long int y ) { // if ( y >= 0 ) return (double)(x \ (unsigned long int)y); // else return 1.0 / x \ (unsigned long int)(-y); // } // ?\? static inline long int ?\=?( long int & x, unsigned long int y ) { x = x \ y; return x; } static inline unsigned long int ?\=?( unsigned long int & x, unsigned long int y ) { x = x \ y; return x; } static inline int ?\=?( int & x, unsigned long int y ) { x = x \ y; return x; } static inline unsigned int ?\=?( unsigned int & x, unsigned long int y ) { x = x \ y; return x; } // Local Variables: // // mode: c // // tab-width: 4 // // End: //