// -*- mode:C++ ; compile-command: "g++ -I.. -g -c -DHAVE_CONFIG_H -DIN_GIAC gen.cc" -*-
/*
* Copyright (C) 2001 B. Parisse, Institut Fourier, 38402 St Martin d'Heres
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#ifndef _GIAC_GEN_H
#define _GIAC_GEN_H
/* Warning: the size of a gen depend on the architecture and of compile-time flags
Define -DSMARTPTR64 on 64 bit CPU if the pointers allocated by new are 48 bits
this will make sizeof(gen)==8 instead of 16
Currently the address of pointers is obtained by using the reserved and val fields
(48 bits) and adding 00 for the most significant bits
On systems that use pointers above 0x00ffffffff it might be better to use a table
of most significants 32 bits addresses (refered by the reserved field)
and use the val field for offset.
Define -DDOUBLEVAL if you did not define SMARTPTR64 and want full double precision
(53 bit mantissa). Otherwise, the 8 less significant bits will be used for the type
field of a gen, i.e. 0x01 for a double, hence 45 bit mantissa will be used for doubles
Using full double precision increases sizeof(gen) to 12 on a 32 bits CPU
(and 16 on a 64 bits CPU)
*/
// FIXME: macros defined in config.h are not welcome in a public header!
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "first.h"
// #include <gmp.h>
#ifdef USE_GMP_REPLACEMENTS
#undef HAVE_GMPXX_H
#undef HAVE_LIBMPFR
#endif
#ifdef HAVE_GMPXX_H
#include <gmpxx.h>
#endif
#ifdef HAVE_LIBMPFR
#include <mpfr.h>
// #include <mpf2mpfr.h>
#endif
#ifdef HAVE_LIBMPFI
#include <mpfi.h>
#endif
#include <iostream>
#include <string>
#include "vector.h"
#include <map>
#include "dispatch.h"
#include "vecteur.h"
#include "fraction.h"
#include "poly.h"
#include "giacintl.h"
#include <complex>
#include <stdlib.h>
#ifdef STATIC_BUILTIN_LEXER_FUNCTIONS
#include "static.h"
#endif
#ifndef NO_NAMESPACE_GIAC
namespace giac {
#endif // ndef NO_NAMESPACE_GIAC
#ifdef USE_GMP_REPLACEMENTS
#undef HAVE_GMPXX_H
#undef HAVE_LIBMPFR
#endif
class gen ;
// errors
void settypeerr(GIAC_CONTEXT0);
void setsizeerr(GIAC_CONTEXT0);
void setdimerr(GIAC_CONTEXT0);
void settypeerr(const std::string & s);
void setsizeerr(const std::string & s);
void setdimerr(const std::string & s);
void divisionby0err(const gen &,GIAC_CONTEXT0);
void cksignerr(const gen &,GIAC_CONTEXT0);
void invalidserieserr(const std::string &,GIAC_CONTEXT0);
void toofewargs(const std::string & s,GIAC_CONTEXT0);
void toomanyargs(const std::string & s,GIAC_CONTEXT0);
void maxordererr(GIAC_CONTEXT0);
void setstabilityerr(GIAC_CONTEXT0);
gen undeferr(const std::string & s);
gen gentypeerr(GIAC_CONTEXT0);
void gentypeerr(gen & g,GIAC_CONTEXT);
gen gensizeerr(GIAC_CONTEXT0);
void gensizeerr(gen & g,GIAC_CONTEXT);
gen gendimerr(GIAC_CONTEXT0);
void gendimerr(gen & g,GIAC_CONTEXT);
gen gentypeerr(const std::string & s);
void gentypeerr(const char * ch,gen & g);
gen gensizeerr(const std::string & s);
void gensizeerr(const char * ch,gen & g);
gen gendimerr(const std::string & s);
void gensizeerr(const char * ch,gen & g);
gen gendivisionby0err(const gen &,GIAC_CONTEXT0);
gen gencksignerr(const gen &,GIAC_CONTEXT0);
gen geninvalidserieserr(const std::string &,GIAC_CONTEXT0);
gen gentoofewargs(const std::string & s,GIAC_CONTEXT0);
gen gentoomanyargs(const std::string & s,GIAC_CONTEXT0);
gen genmaxordererr(GIAC_CONTEXT0);
gen genstabilityerr(GIAC_CONTEXT0);
// short integer arithmetic
int absint(int a);
int giacmin(int a,int b);
int giacmax(int a,int b);
int invmod(int n,int modulo);
unsigned invmod(unsigned a,int b);
int invmod(longlong a,int b);
#ifdef INT128
int invmod(int128_t a,int b);
inline int smod(int128_t r,int m){
int R=r%m;
return smod(R,m);
}
#endif
int gcd(int a,int b);
int smod(int a,int b); // where b is assumed to be positive
inline int smod(longlong r,int m){
int R=r%m;
return smod(R,m);
}
int simplify(int & a,int & b);
struct ref_mpz_t {
volatile int ref_count;
mpz_t z;
ref_mpz_t():ref_count(1) {mpz_init(z);}
ref_mpz_t(size_t nbits):ref_count(1) {mpz_init2(z,nbits);}
ref_mpz_t(const mpz_t & Z): ref_count(1) { mpz_init_set(z,Z); }
~ref_mpz_t() { mpz_clear(z); }
};
class identificateur;
struct ref_identificateur; // in identificateur.h
struct symbolic;
struct ref_symbolic; // in symbolic.h
class unary_function_eval;
struct unary_function_ptr;
typedef const unary_function_ptr * const_unary_function_ptr_ptr;
typedef const unary_function_eval * const_unary_function_eval_ptr;
struct ref_unary_function_ptr; // in unary.h
struct eqwdata;
struct ref_eqwdata ; // defined below after gen
struct ref_complex;
struct ref_algext;
struct ref_modulo;
// Graphic object
struct grob {
void (* grob_draw)(void);
int (* grob_handle) (int);
void * grob_data;
};
struct ref_grob {
volatile int ref_count;
grob g;
ref_grob(const grob & G):ref_count(1),g(G) {}
};
class gen_user;
struct ref_gen_user ; // user defined type
struct ref_string {
volatile int ref_count;
std::string s;
ref_string(const std::string & S):ref_count(1),s(S) {}
};
template <class T> class tensor;
typedef tensor<gen> polynome;
typedef std::vector< facteur< polynome > > factorization;
template<class T> class Tref_tensor; // in poly.h
typedef Tref_tensor<gen> ref_polynome;
typedef Tfraction<gen> fraction;
template<class T> class Tref_fraction;
typedef Tref_fraction<gen> ref_fraction;
struct ref_vecteur;
void delete_ref_vecteur(ref_vecteur * ptr);
ref_vecteur * new_ref_vecteur(const vecteur & v);
ref_symbolic * new_ref_symbolic(const symbolic & s);
template<class T> class Tref_fraction; // in fraction.h
struct ref_void_pointer {
volatile int ref_count;
void * p;
ref_void_pointer(void * P):ref_count(1),p(P) {}
};
struct monome;
// sparse polynomials: uncomment one of the 2 next lines
#ifdef DEBUG_SUPPORT
typedef dbgprint_vector<monome> sparse_poly1; // debugging support
#else
typedef std::vector<monome> sparse_poly1; // no debug. support
#endif
struct ref_sparse_poly1;
// arbitrary precision floats hierarchy (value or interval)
std::string printmpf_t(const mpf_t & inf);
class real_object {
public:
#ifdef HAVE_LIBMPFR
mpfr_t inf;
#else
mpf_t inf;
#endif
real_object(double d);
#ifdef HAVE_LIBMPFR
real_object(const mpfr_t & d);
real_object(const mpf_t & d);
#else
real_object(const mpf_t & d);
#endif
real_object(const gen & g);
real_object(const gen & g,unsigned int precision);
real_object() ;
virtual std::string print(GIAC_CONTEXT) const;
void dbgprint() const { std::cerr << this->print(0) << std::endl; }
virtual ~real_object() {
#ifdef HAVE_LIBMPFR
mpfr_clear(inf);
#else
mpf_clear(inf);
#endif
}
virtual real_object & operator = (const real_object & g);
real_object (const real_object & g) ;
gen addition (const gen & g,GIAC_CONTEXT) const;
gen operator + (const gen & g) const;
virtual real_object operator + (const real_object & g) const;
gen multiply (const gen & g,GIAC_CONTEXT) const;
gen operator * (const gen & g) const;
virtual real_object operator * (const real_object & g) const;
gen divide (const gen & g,GIAC_CONTEXT) const;
gen operator / (const gen & g) const;
gen substract (const gen & g,GIAC_CONTEXT) const;
virtual real_object operator / (const real_object & g) const;
gen operator - (const gen & g) const;
virtual real_object operator - (const real_object & g) const;
virtual real_object operator -() const;
virtual real_object inv() const;
virtual real_object sqrt() const;
virtual real_object abs() const;
virtual real_object exp() const;
virtual real_object log() const;
virtual real_object sin() const;
virtual real_object cos() const;
virtual real_object tan() const;
virtual real_object sinh() const;
virtual real_object cosh() const;
virtual real_object tanh() const;
virtual real_object asin() const;
virtual real_object acos() const;
virtual real_object atan() const;
virtual real_object asinh() const;
virtual real_object acosh() const;
virtual real_object atanh() const;
virtual bool is_zero();
virtual bool is_inf();
virtual bool is_nan();
virtual bool is_positive();
virtual double evalf_double() const;
};
struct ref_real_object {
volatile int ref_count;
real_object r;
ref_real_object():ref_count(1) {}
ref_real_object(const real_object & R):ref_count(1),r(R) {}
};
gen real2int(const gen & g,GIAC_CONTEXT);
gen real2double(const gen & g);
class real_interval : public real_object {
public:
#ifdef HAVE_LIBMPFI
mpfi_t infsup;
#else
#ifdef HAVE_LIBMPFR
mpfr_t sup;
#else
mpf_t sup;
#endif
#endif
real_interval(const real_object & r):real_object(r) {
#ifdef HAVE_LIBMPFI
mpfi_init_set_fr(infsup,r.inf);
#else
#ifdef HAVE_LIBMPFR
mpfr_init_set(sup,r.inf,GMP_RNDN);
#else
mpf_init_set(sup,r.inf);
#endif
#endif
}
real_interval(const real_interval & r):real_object(r) {
#ifdef HAVE_LIBMPFI
mpfi_init_set(infsup,r.infsup);
#else
#ifdef HAVE_LIBMPFR
mpfr_init_set(sup,r.sup,GMP_RNDN);
#else
mpf_init_set(sup,r.sup);
#endif
#endif
}
virtual ~real_interval() {
#ifdef HAVE_LIBMPFI
mpfi_clear(infsup);
#else
#ifdef HAVE_LIBMPFR
mpfr_clear(sup);
#else
mpf_clear(sup);
#endif
#endif
}
virtual real_object & operator = (const real_interval & g) ;
virtual real_object & operator = (const real_object & g) ;
virtual real_object operator + (const real_object & g) const;
virtual real_interval operator + (const real_interval & g) const;
virtual real_object operator * (const real_object & g) const;
virtual real_interval operator * (const real_interval & g) const;
virtual real_object operator - (const real_object & g) const;
virtual real_interval operator - (const real_interval & g) const ;
virtual real_object operator -() const;
virtual real_object inv() const;
};
std::string print_binary(const real_object & r);
gen read_binary(const std::string & s,unsigned int precision);
// Convert g to a real or complex object of precision nbits
gen accurate_evalf(const gen & g,int nbits);
vecteur accurate_evalf(const vecteur & v,int nbits);
std::string print_DOUBLE_(double d,GIAC_CONTEXT);
typedef std::map<gen,gen,const std::pointer_to_binary_function < const gen &, const gen &, bool> > gen_map;
struct ref_gen_map;
class my_mpz;
#ifdef NO_UNARY_FUNCTION_COMPOSE
class unary_function_eval;
#else
class unary_function_abstract;
#endif
struct alias_unary_function_eval;
struct unary_function_ptr {
#ifdef NO_UNARY_FUNCTION_COMPOSE
const unary_function_eval * _ptr;
// int quoted; // will be used to avoid evaluation of args by eval
// constructors
// lexer_register is true to add dynamically the function name
// to the list of functions names recognized by the lexer
unary_function_ptr():_ptr(0) {} ;
unary_function_ptr(const unary_function_eval * myptr):_ptr(myptr) {} ;
// unary_function_ptr(const unary_function_eval * myptr,int parser_token);
unary_function_ptr(const unary_function_eval * myptr,int myquoted,int parser_token);
// unary_function_ptr(const alias_unary_function_eval * myptr,int parser_token);
unary_function_ptr(const alias_unary_function_eval * myptr,int myquoted,int parser_token);
#else // NO_UNARY_FUNCTION_COMPOSE
const unary_function_abstract * _ptr;
// int * ref_count;
// int quoted; // will be used to avoid evaluation of args by eval
// constructors
// lexer_register is true to add dynamically the function name
// to the list of functions names recognized by the lexer
// unary_function_ptr(const unary_function_abstract & myptr);
unary_function_ptr():_ptr(0) {} ;
unary_function_ptr(const unary_function_abstract * myptr):_ptr(myptr) {} ;
// unary_function_ptr(const unary_function_abstract * myptr,int parser_token) ;
// unary_function_ptr(const unary_function_abstract & myptr,int myquoted,int parser_token=0);
unary_function_ptr(const unary_function_abstract * myptr,int myquoted,int parser_token);
// unary_function_ptr(const unary_function_ptr & myptr);
// unary_function_ptr(const alias_unary_function_eval * myptr,int parser_token);
unary_function_ptr(const alias_unary_function_eval * myptr,int myquoted,int parser_token);
#endif // NO_UNARY_FUNCTION_COMPOSE
// ~unary_function_ptr();
// unary_function_ptr & operator = (const unary_function_ptr & acopier);
gen operator () (const gen & arg,GIAC_CONTEXT) const;
#ifdef NO_UNARY_FUNCTION_COMPOSE
inline unary_function_eval * ptr() const {
#ifdef __x86_64__
return (unary_function_eval *) (((unsigned longlong ) _ptr) & 0xfffffffffffffffc);
#else
return (unary_function_eval *) (((unsigned long) _ptr) & 0xfffffffc);
#endif
}
#else // NO_UNARY_FUNCTION_COMPOSE
inline unary_function_abstract * ptr () const
{
#ifdef __x86_64__
return (unary_function_abstract *) (((ulonglong) _ptr) & 0xfffffffffffffffc);
#else
return (unary_function_abstract *) (((unsigned long) _ptr) & 0xfffffffc);
#endif
}
#endif // NO_UNARY_FUNCTION_COMPOSE
bool quoted() const ;
inline bool operator ==(const unary_function_ptr & u) const {
// if (&u==this) return true;
#ifdef __x86_64__
return ((ulonglong)(_ptr) & 0xfffffffffffffffc) == ((ulonglong)( u._ptr) & 0xfffffffffffffffc );
#else
return ((unsigned long)(_ptr) & 0xfffffffc) == ((unsigned long)(u._ptr) & 0xfffffffc);
#endif
}
inline bool operator !=(const unary_function_ptr & u) const { return !(*this==u); }
inline bool operator ==(const unary_function_ptr * u) const {
// if (&u==this) return true;
#ifdef __x86_64__
return u && ( ((ulonglong)(_ptr) & 0xfffffffffffffffc) == ((ulonglong)(u->_ptr) & 0xfffffffffffffffc) );
#else
return u && ( ((unsigned long)(_ptr) & 0xfffffffc) == ((unsigned long)(u->_ptr) & 0xfffffffc ) );
#endif
}
inline bool operator !=(const unary_function_ptr * u) const { return !(*this==u); }
void dbgprint() const;
};
// FIXME: for little-endian check if type/unused/subtype order is correct!
class gen {
public:
#ifdef GIAC_TYPE_ON_8BITS
unsigned char type; // see dispatch.h
#else
unsigned char type:5; // 32 types is enough, keep 3 bits more for double
unsigned char type_unused:3;
#endif
signed char subtype;
unsigned short reserved; // used if SMARTPTR is defined on 64 bit CPU (16 bits for pointer val)
union {
// immediate types
int val; // immediate int (type _INT_)
#ifdef DOUBLEVAL
double _DOUBLE_val; // immediate float (type _DOUBLE_)
giac_float _FLOAT_val;
#endif
#ifndef SMARTPTR64
// pointer types
ref_mpz_t * __ZINTptr; // long int (type _ZINT)
ref_real_object * __REALptr; // extended double (type _REAL)
ref_complex * __CPLXptr ; // complex as an gen[2] array (type _CPLX)
ref_identificateur * __IDNTptr; // global name identifier (type _IDNT)
ref_symbolic * __SYMBptr; // for symbolic objects (type _SYMB)
ref_modulo * __MODptr;
ref_algext * __EXTptr; // 2 gens for alg. extension (type ext)
// alg ext: 1st gen is a std::vector or a fraction, 2nd gen is
// a/ a std::vector, the minimal monic polynomial (the roots are permutable)
// b/ a real_complex_rootof given by it's min poly and
// c/ another type meaning that the root is expressed in terms
// of another rootof, in this case ext_reduce should be called
// For 2nd order extension, X^2=d is used if d!=1 mod 4
// X is the positive solution
// if d=1 mod 4 the equation is X^2-X=(d-1)/4
Tref_fraction<gen> * __FRACptr; // fraction (type _FRAC)
Tref_tensor<gen> * __POLYptr ; // multidim. sparse polynomials (type poly)
// _VECTosite types (std::vector<>)
ref_vecteur * __VECTptr ; // vecteur: std::vectors & dense_POLY1 (type _VECT)
ref_sparse_poly1 * __SPOL1ptr ; // std::vector<monome>: sparse 1-d poly (type _SPOL1)
ref_string * __STRNGptr;
unsigned _FUNC_;
// ref_unary_function_ptr * __FUNCptr;
ref_gen_user * __USERptr;
ref_gen_map * __MAPptr;
ref_eqwdata * __EQWptr;
ref_grob * __GROBptr;
ref_void_pointer * __POINTERptr;
#endif
};
inline volatile int & ref_count() const {
#ifdef SMARTPTR64
return ((ref_mpz_t *) ((* (longlong *) (this))>>16))->ref_count;
#else
return __ZINTptr->ref_count;
#endif
}
gen(): type(_INT_),subtype(0),val(0) {
#ifdef COMPILE_FOR_STABILITY
control_c();
#endif
};
#ifdef SMARTPTR64
gen(void *ptr,short int subt) {
#ifdef COMPILE_FOR_STABILITY
control_c();
#endif
longlong __POINTERptr = (longlong ) new ref_void_pointer(ptr);
#ifndef NO_STDEXCEPT
if (__POINTERptr & 0xffff000000000000)
setsizeerr(gettext("Pointer out of range"));
#endif
* ((longlong *) this) = __POINTERptr << 16;
subtype=subt;
type=_POINTER_;
};
#else
gen(void *ptr,short int subt): type(_POINTER_),subtype(char(subt)) {
#ifdef COMPILE_FOR_STABILITY
control_c();
#endif
__POINTERptr=new ref_void_pointer(ptr);
};
#endif
gen(int i): type(_INT_),subtype(0),val(i) {
#ifdef COMPILE_FOR_STABILITY
control_c();
#endif
};
gen(size_t i): type(_INT_),subtype(0),val((int)i) {
#ifdef COMPILE_FOR_STABILITY
control_c();
#endif
};
gen(longlong i);
#ifdef INT128
gen(int128_t i);
#endif
gen(const mpz_t & m);
// WARNING coerce *mptr to an int if possible, in this case delete mptr
// Pls do not use this constructor unless you know exactly what you do!!
gen(ref_mpz_t * mptr);
#ifdef DOUBLEVAL
gen(double d): type(_DOUBLE_),_DOUBLE_val(d) {};
#else
// Warning this does not work on ia64 with -O2
gen(double d) { *((double *) this) = d; type=_DOUBLE_; };
#endif
gen(const giac_float & f);
#ifdef BCD
gen(accurate_bcd_float * b);
#endif
// inline
double DOUBLE_val() const ;
giac_float FLOAT_val() const ;
gen(int a,int b);
gen(double a,double b);
gen(const gen & a,const gen & b);
gen(const std::complex<double> & c);
gen(const gen & e);
gen (const identificateur & s);
gen (ref_identificateur * sptr);
gen (const vecteur & v,short int s=0);
gen (ref_vecteur * vptr,short int s=0);
// vptr must be a pointer allocated by new, do not delete it explicitly
gen (const symbolic & s);
gen (ref_symbolic * sptr);
gen (const gen_user & g);
gen (const real_object & g);
// Pls do not use this constructor unless you know exactly what you do
gen (Tref_tensor<gen> * pptr);
gen (const polynome & p);
gen (const fraction & p);
gen (const std::string & s,GIAC_CONTEXT);
gen (const wchar_t * s,GIAC_CONTEXT);
gen (const char * s,GIAC_CONTEXT){ type=0; *this=gen(std::string(s),contextptr); };
gen (const sparse_poly1 & p);
gen (const unary_function_ptr & f,int nargs=1);
gen (const unary_function_ptr * f,int nargs=1);
gen (const gen_map & m);
gen (const eqwdata & );
gen (const grob & );
#ifdef HAVE_GMPXX_H
gen (const mpz_class &);
#endif
gen (const my_mpz &);
~gen();
bool in_eval(int level,gen & evaled,const context * contextptr) const;
gen eval(int level,const context * contextptr) const;
// inline gen eval() const { return eval(DEFAULT_EVAL_LEVEL,context0); }
bool in_evalf(int level,gen & evaled,const context * contextptr) const;
gen evalf(int level,const context * contextptr) const;
// inline gen evalf() const { return evalf(DEFAULT_EVAL_LEVEL,context0); }
gen evalf_double(int level,const context * contextptr) const ;
gen evalf2double(int level,const context * contextptr) const;
gen & operator = (const gen & a);
int to_int() const ;
bool is_real(GIAC_CONTEXT) const ;
bool is_cinteger() const ;
bool is_integer() const ;
bool is_constant() const;
std::string print(GIAC_CONTEXT) const;
inline const char * printcharptr(GIAC_CONTEXT) const { return print(contextptr).c_str(); };
// if sptr==0, return length required, otherwise print at end of *sptr
int sprint(std::string * sptr,GIAC_CONTEXT) const;
std::string print_universal(GIAC_CONTEXT) const;
std::string print() const;
inline const char * printcharptr() const { return print().c_str(); };
wchar_t * wprint(GIAC_CONTEXT) const ;
// print then convert to a malloc-ated wchar_t *
void modify(int i) { *this =gen(i); };
void dbgprint() const;
void uncoerce() ;
gen conj(GIAC_CONTEXT) const;
gen re(GIAC_CONTEXT) const ;
gen im(GIAC_CONTEXT) const ;
gen inverse(GIAC_CONTEXT) const;
gen squarenorm(GIAC_CONTEXT) const;
int bindigits() const ;
gen operator [] (int i) const ;
gen operator [] (const gen & i) const;
gen operator_at(int i,GIAC_CONTEXT) const;
gen operator_at(const gen & i,GIAC_CONTEXT) const;
// gen & operator [] (int i) ;
// gen & operator [] (const gen & i) ;
gen operator () (const gen & i,GIAC_CONTEXT) const;
gen operator () (const gen & i,const gen & progname,GIAC_CONTEXT) const;
bool islesscomplexthan(const gen & other) const;
bool is_approx() const ; // true if double/real or cmplx with re/im
int symb_size() const;
gen change_subtype(int newsubtype);
bool is_symb_of_sommet(const unary_function_ptr & u) const ;
bool is_symb_of_sommet(const unary_function_ptr * u) const ;
gen makegen(int i) const; // make a gen of same type as this with integer i
// For compatibility with older versions
inline mpz_t * ref_ZINTptr() const ;
inline real_object * ref_REALptr() const ;
inline gen * ref_CPLXptr() const ;
inline identificateur * ref_IDNTptr() const ;
inline symbolic * ref_SYMBptr() const ;
inline gen * ref_MODptr () const ;
inline Tfraction<gen> * ref_FRACptr() const ;
inline gen * ref_EXTptr () const ;
inline polynome * ref_POLYptr() const ;
inline vecteur * ref_VECTptr() const ;
inline sparse_poly1 * ref_SPOL1ptr() const ;
inline std::string * ref_STRNGptr() const ;
inline unary_function_ptr * ref_FUNCptr() const ;
inline gen_user * ref_USERptr() const ;
inline gen_map * ref_MAPptr() const ;
inline eqwdata * ref_EQWptr() const ;
inline grob * ref_GROBptr() const ;
inline void * ref_POINTER_val() const ;
};
// pointer to an int describing display mode for complex numbers
int * complex_display_ptr(const gen & g);
// value==0 to cartesian, 1 to polar, 2 toggle, 3 count complex
// returns the number of complex
int adjust_complex_display(gen & res,int value);
#if defined(SMARTPTR64)
typedef ulonglong alias_gen;
#else
struct alias_gen {
unsigned char type; // see dispatch.h
signed char subtype;
unsigned short reserved; // not used
#ifdef DOUBLEVAL
longlong value;
#else
long value ;
#endif
};
#endif
class vectpoly:public std::vector<polynome> {
public:
vectpoly():std::vector<polynome>::vector() {};
vectpoly(int i,const polynome & p):std::vector<polynome>::vector(i,p) {};
void dbgprint(){
std::cerr << *this << std::endl;
}
};
struct ref_gen_map {
volatile int ref_count;
gen_map m;
ref_gen_map(const std::pointer_to_binary_function < const gen &, const gen &, bool> & p): ref_count(1),m(p) {}
ref_gen_map(const gen_map & M):ref_count(1),m(M) {}
};
struct alias_ref_fraction { int ref_count; alias_gen num; alias_gen den; };
struct alias_ref_complex {
int ref_count;
int display;
alias_gen re,im;
};
struct ref_vecteur {
volatile int ref_count;
vecteur v;
ref_vecteur():ref_count(1) {}
ref_vecteur(unsigned s):ref_count(1),v(s) {}
ref_vecteur(unsigned s,const gen & g):ref_count(1),v(s,g) {}
ref_vecteur(const_iterateur it,const_iterateur itend):ref_count(1),v(it,itend) {}
ref_vecteur(const vecteur & w):ref_count(1),v(w) {}
};
#ifdef SMARTPTR64
#define define_alias_gen(name,type,subtype,ptr) alias_gen name={(longlong(ptr) << 16) | (subtype << 8) | type };
#define define_alias_ref_symbolic(name,sommet,type,subtype,ptr) alias_ref_symbolic name={-1,(unary_function_eval *)sommet,(longlong(ptr) << 16) | (subtype << 8) | type};
#define define_alias_ref_fraction(name,numtype,numsubtype,numptr,dentype,densubtype,denptr) alias_ref_fraction name={-1,{(longlong(numptr) << 16) | (numsubtype << 8) | numtype },{(longlong(denptr) << 16) | (densubtype << 8) | dentype }};
#define define_alias_ref_complex(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_ref_complex name={-1,0,{(longlong(reptr) << 16) | (resubtype << 8) | retype },{(longlong(imptr) << 16) | (imsubtype << 8) | imtype }};
#define define_tab2_alias_gen(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_gen name[]={{(longlong(reptr) << 16) | (resubtype << 8) | retype },{(longlong(imptr) << 16) | (imsubtype << 8) | imtype }};
#else // SMARTPTR64
#ifdef DOUBLEVAL
#define define_alias_gen(name,type,subtype,ptr) alias_gen name={type,subtype,0,longlong(ptr)};
#define define_alias_ref_symbolic(name,sommet,type,subtype,ptr) alias_ref_symbolic name={-1,(unary_function_eval *)sommet,type,subtype,0,longlong(ptr)};
#define define_alias_ref_fraction(name,numtype,numsubtype,numptr,dentype,densubtype,denptr) alias_ref_fraction name={-1,{numtype,numsubtype,0,longlong(numptr)},{dentype,densubtype,0,longlong(denptr)}};
#define define_alias_ref_complex(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_ref_complex name={-1,0,{retype,resubtype,0,longlong(reptr)},{imtype,imsubtype,0,longlong(imptr)}};
#define define_tab2_alias_gen(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_gen name[]={{retype,resubtype,0,longlong(reptr)},{imtype,imsubtype,0,longlong(imptr)}};
#else // DOUBLEVAL
#define define_alias_gen(name,type,subtype,ptr) alias_gen name={type,subtype,0,long(ptr)};
#define define_alias_ref_symbolic(name,sommet,type,subtype,ptr) alias_ref_symbolic name={-1,(unary_function_eval *)sommet,type,subtype,0,long(ptr)};
#define define_alias_ref_fraction(name,numtype,numsubtype,numptr,dentype,densubtype,denptr) alias_ref_fraction name={-1,{numtype,numsubtype,0,long(numptr)},{dentype,densubtype,0,long(denptr)}};
#define define_alias_ref_complex(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_ref_complex name={-1,0,{retype,resubtype,0,long(reptr)},{imtype,imsubtype,0,long(imptr)}};
#define define_tab2_alias_gen(name,retype,resubtype,reptr,imtype,imsubtype,imptr) alias_gen name[]={{retype,resubtype,0,long(reptr)},{imtype,imsubtype,0,long(imptr)}};
#endif // DOUBLEVAL
#endif // SMARTPTR64
// ? #ifdef __GNUC__
#ifdef IMMEDIATE_VECTOR
struct alias_ref_vecteur { int ref_count; const int _taille; const alias_gen * begin_immediate_vect; const alias_gen * end_immediate_vect; void * ptr; };
#define define_alias_ref_vecteur(name,b) alias_ref_vecteur name={-1,sizeof(b)/sizeof(gen),(const alias_gen *)b,(const alias_gen *)b+sizeof(b)/sizeof(gen),0};
#define define_alias_ref_vecteur2(name,b) alias_ref_vecteur name={-1,2,&b[0],&b[2],0};
#else
struct alias_ref_vecteur { int ref_count; const alias_gen * begin; const alias_gen * end; const alias_gen * finish; void * ptr; };
#define define_alias_ref_vecteur(name,b) alias_ref_vecteur name={-1,(const alias_gen *)b,(const alias_gen *)b+sizeof(b)/sizeof(gen),(const alias_gen *)b+sizeof(b)/sizeof(gen),0};
#define define_alias_ref_vecteur2(name,b) alias_ref_vecteur name={-1,&b[0],&b[2],&b[2],0};
#endif
struct ref_complex {
volatile int ref_count;
int display;
gen re,im;
ref_complex(const gen & R,const gen & I):ref_count(1),display(0),re(R),im(I) {}
ref_complex(const gen & R,const gen & I,int display_mode):ref_count(1),display(display_mode),re(R),im(I) {}
};
struct ref_modulo {
volatile int ref_count;
gen n,modulo;
ref_modulo():ref_count(1) {}
ref_modulo(const gen &N,const gen &M):ref_count(1),n(N),modulo(M) {}
};
struct ref_algext {
volatile int ref_count;
gen P,Pmin;
ref_algext():ref_count(1) {}
};
bool poly_is_real(const polynome & p);
polynome addpoly(const polynome & p,const gen & c);
polynome subpoly(const polynome & p,const gen & c);
bool islesscomplexthanf(const gen & a,const gen & b);
gen makemap(); // make a new map
gen chartab2gen(char * & s,GIAC_CONTEXT);
bool is_zero(const gen & a,GIAC_CONTEXT0);
bool is_exactly_zero(const gen & a);
bool is_one(const gen & a);
bool is_minus_one(const gen & a);
bool is_sq_minus_one(const gen & a);
bool is_inf(const gen & e);
bool is_undef(const gen & e);
bool is_undef(const polynome & p);
bool is_undef(const vecteur & v);
bool is_undef(const sparse_poly1 & s);
bool is_zero__VECT(const vecteur & a,GIAC_CONTEXT);
bool has_denominator(const gen & n);
bool has_i(const gen & g);
// basic arithmetic
gen operator && (const gen & a,const gen & b);
gen operator || (const gen & a,const gen & b);
gen operator_plus (const gen & a,const gen & b,GIAC_CONTEXT);
gen operator + (const gen & a,const gen & b);
gen operator_plus_eq (gen & a,const gen & b,GIAC_CONTEXT);
inline gen operator += (gen & a,const gen & b){
return operator_plus_eq(a,b,giac::context0);
}
Tfraction<gen> operator + (const Tfraction<gen> & a,const Tfraction<gen> & b); // specialization
gen sym_add (const gen & a,const gen & b,GIAC_CONTEXT);
gen operator_minus_eq (gen & a,const gen & b,GIAC_CONTEXT);
inline gen operator -= (gen & a,const gen & b){
return operator_minus_eq(a,b,giac::context0);
}
gen operator_minus (const gen & a,const gen & b,GIAC_CONTEXT);
gen operator - (const gen & a,const gen & b);
gen operator - (const gen & a);
gen sym_sub (const gen & a,const gen & b,GIAC_CONTEXT);
gen operator_times (const gen & a,const gen & b,GIAC_CONTEXT);
gen operator * (const gen & a,const gen & b);
inline gen operator * (int a,const gen & b){ return gen(a)*b; }
inline gen operator * (double a,const gen & b){ return gen(a)*b; }
gen sym_mult (const gen & a,const gen & b,GIAC_CONTEXT);
gen pow(const gen & base,const gen & exponent,GIAC_CONTEXT);
gen giac_pow(const gen & base,const gen & exponent,GIAC_CONTEXT);
gen iquo(const gen & a,const gen & b); // same
gen irem(const gen & a,const gen & b,gen & q); // same
gen smod(const gen & a,const gen & b); // same
void smod(const vecteur & v,const gen & g,vecteur & w);
vecteur smod(const vecteur & a,const gen & b); // same
gen rdiv(const gen & a,const gen & b); // rational division
inline gen operator /(const gen & a,const gen & b){ return rdiv(a,b); };
gen operator %(const gen & a,const gen & b); // for int only
// gen inv(const gen & a);
gen inv(const gen & a,GIAC_CONTEXT);
inline wchar_t * wprint(const gen & g,GIAC_CONTEXT){ return g.wprint(contextptr); }
inline void swapgen(gen & a,gen &b){
gen tmp=a; a=b; b=tmp;
}
gen algebraic_EXTension(const gen & a,const gen & v);
gen ext_reduce(const gen & a, const gen & v);
gen maptoarray(const gen_map & m,GIAC_CONTEXT);
gen evalf_VECT(const vecteur & v,int subtype,int level,const context * contextptr);
gen m_gamma(int nbits); // Euler gamma constant precision nbits
gen m_gamma(GIAC_CONTEXT);
gen m_pi(int nbits); // pi precision nbits
gen m_pi(GIAC_CONTEXT);
// a*b -> tmp, may modify tmp in place
void type_operator_times(const gen & a,const gen &b,gen & tmp);
// c += a*b, may modify c in place
/*
inline void type_operator_plus_times(const gen & a,const gen & b,gen & c){
gen g;
type_operator_times(a,b,g);
c += g;
}
*/
void type_operator_plus_times(const gen & a,const gen & b,gen & c);
inline void type_operator_plus_times_reduce(const gen & a,const gen & b,gen & c,int reduce){
type_operator_plus_times(a,b,c);
if (reduce)
c=smod(c,reduce);
}
inline void type_operator_reduce(const gen & a,const gen & b,gen & c,int reduce){
type_operator_times(a,b,c);
if (reduce)
c=smod(c,reduce);
}
bool operator ==(const gen & a,const gen & b);
bool operator ==(const gen & a,const identificateur & b);
bool operator_equal(const gen & a,const gen & b,GIAC_CONTEXT);
bool operator !=(const gen & a,const gen & b);
inline bool operator !=(const gen & a,const identificateur & b){ return !(a==b); }
gen equal(const gen & a,const gen &b,GIAC_CONTEXT);
gen operator !(const gen & a);
int fastsign(const gen & a,GIAC_CONTEXT); // 0 if unknown, 1 if >0, -1 if <0
gen sign(const gen & a,GIAC_CONTEXT);
// Large tests if strictly not precised, if sign is unknown return false
bool is_greater(const gen & a,const gen &b,GIAC_CONTEXT);
bool is_strictly_greater(const gen & a,const gen &b,GIAC_CONTEXT);
inline bool operator > (const gen & a,const gen & b){
return is_strictly_greater(a,b,giac::context0);
}
bool is_positive(const gen & a,GIAC_CONTEXT);
bool is_strictly_positive(const gen & a,GIAC_CONTEXT);
// Large tests if strictly not precised, if sign is unknown make an error
bool ck_is_greater(const gen & a,const gen &b,GIAC_CONTEXT);
bool ck_is_strictly_greater(const gen & a,const gen &b,GIAC_CONTEXT);
bool ck_is_positive(const gen & a,GIAC_CONTEXT);
bool ck_is_strictly_positive(const gen & a,GIAC_CONTEXT);
gen superieur_strict(const gen & a,const gen & b,GIAC_CONTEXT);
gen superieur_egal(const gen & a,const gen & b,GIAC_CONTEXT);
gen inferieur_strict(const gen & a,const gen & b,GIAC_CONTEXT);
gen inferieur_egal(const gen & a,const gen & b,GIAC_CONTEXT);
bool symb_size_less(const gen & a,const gen & b);
gen min(const gen & a, const gen & b,GIAC_CONTEXT);
gen max(const gen & a, const gen & b,GIAC_CONTEXT=context0);
// default context0 is required for instantiation in poly.h
gen factorial(unsigned long int i);
gen comb(unsigned long int i,unsigned long j);
gen perm(unsigned long int i,unsigned long j);
gen pow(const gen & base, unsigned long int exponent);
gen pow(const gen & base, int exponent);
gen pow(unsigned long int base, unsigned long int exponent);
// more advanced arithmetic
gen gcd(const gen & A,const gen & B);
gen lcm(const gen & a,const gen & b);
gen simplify(gen & n, gen & d);
void egcd(const gen &a,const gen &b, gen & u,gen &v,gen &d );
gen ichinrem(const gen & a,const gen &b,const gen & amod, const gen & bmod);
gen invmod(const gen & A,const gen & modulo);
gen fracmod(const gen & a_orig,const gen & modulo); // -> p/q=a mod modulo
bool fracmod(const gen & a_orig,const gen & modulo,gen & res);
gen powmod(const gen &base,const gen & expo,const gen & modulo);
gen isqrt(const gen & A);
gen re(const gen & a,GIAC_CONTEXT);
gen no_context_re(const gen & a);
gen im(const gen & a,GIAC_CONTEXT);
gen no_context_im(const gen & a);
void reim(const gen & g,gen & r,gen & i,GIAC_CONTEXT);
gen conj(const gen & a,GIAC_CONTEXT);
gen no_context_conj(const gen & a);
gen sq(const gen & a);
gen abs(const gen & a,const context * contextptr=context0);
// default context0 is required for instantiation in poly.h
gen linfnorm(const gen & a,const context * contextptr=context0);
// default context0 is required for instantiation in poly.h
gen arg(const gen & a,GIAC_CONTEXT);
gen arg_CPLX(const gen & a,GIAC_CONTEXT);
int is_perfect_square(const gen & A);
int is_probab_prime_p(const gen & A);
gen nextprime(const gen & a); // more precisely next probably prime
gen prevprime(const gen & a); // more precisely prev probably prime
int jacobi(const gen & A, const gen &B);
int legendre(const gen & A, const gen & B);
vecteur pascal_next_line(const vecteur & v);
vecteur pascal_nth_line(int n);
// convert a __VECTOR__VECT vecteur to a normal vecteur
gen vector2vecteur(const vecteur & v);
// if b is a _MOD, returns a as a b _MOD
gen chkmod(const gen& a,const gen & b);
// make a _MOD a%b
gen makemod(const gen & a,const gen & b);
// same without evaluating %
gen makemodquoted(const gen & a,const gen & b);
// from a sum in x returns a list of [coeff monomial]
// e.g. 5+2x+3*x*y -> [ [5 1] [2 x] [ 3 x*y] ]
vecteur symbolique2liste(const gen & x,GIAC_CONTEXT);
// v should be sorted and shrinked
gen liste2symbolique(const vecteur & v);
bool is_atomic(const gen & e);
symbolic _FRAC2_SYMB(const fraction & f);
symbolic _FRAC2_SYMB(const gen & e);
symbolic _FRAC2_SYMB(const gen & n,const gen & d);
gen string2gen(const std::string & ss,bool remove_ss_quotes=true);
// by default ss is assumed to be delimited by " and "
std::complex<double> gen2complex_d(const gen & e);
gen eval_VECT(const vecteur & v,int subtype,int level,const context * context_ptr );
// functional equivalent of gen methods
inline gen eval(const gen & e,int level,const context * contextptr){ return e.eval(level,contextptr); };
inline gen eval(const gen & e,const context * contextptr){ return e.eval(eval_level(contextptr),contextptr); };
gen no_context_evalf(const gen & e);
gen evalf(const gen & e,int level,const context * contextptr );
gen evalf2bcd_nock(const gen & g0,int level,const context * contextptr);
gen evalf2bcd(const gen & g0,int level,const context * contextptr);
inline gen evalf_double(const gen & e,int level,const context * contextptr){ return e.evalf_double(level,contextptr); };
// return true if g can be converted to a double or real or complex
bool has_evalf(const gen & g,gen & res,int level,const context * contextptr);
inline std::string print(const gen & e,context * contextptr){ return e.print(contextptr); }
inline bool is_real(const gen & g,GIAC_CONTEXT){ return g.is_real(contextptr); }
inline bool is_cinteger(const gen & g){ return g.is_cinteger();} ;
inline bool is_integer(const gen & g){ return g.is_integer(); } ;
double int2double(int i);
inline bool is_constant(const gen & g){ return g.is_constant(); } ;
inline bool is_approx(const gen & g){ return g.is_approx(); };
gen aplatir_fois_plus(const gen & g);
gen collect(const gen & g,GIAC_CONTEXT);
class gen_user{
public:
virtual gen_user * memory_alloc() const { gen_user * ptr = new gen_user(*this); return ptr; }
virtual ~gen_user() {};
// redefine operations if it makes sense.
// You can redefine gen_user + gen_user for speed
virtual gen operator + (const gen &) const { return gensizeerr(gettext("+ not redefined")); }
virtual gen operator + (const gen_user & a) const { return (*this) + gen(a); }
virtual gen operator - (const gen &) const { return gensizeerr(gettext("Binary - not redefined")); }
virtual gen operator - (const gen_user & a) const { return (*this) - gen(a); }
virtual gen operator - () const { return gensizeerr(gettext("Unary - not redefined")); }
virtual gen operator * (const gen &) const { return gensizeerr(gettext("Binary * not redefined")); }
virtual gen operator * (const gen_user & a) const { return (*this) * gen(a); }
virtual gen operator / (const gen_user & a) const { return (*this) * a.inv(); }
virtual gen operator / (const gen & a) const { return gensizeerr(gettext("Binary / not redefined")); }
virtual bool is_zero() const {
#ifndef NO_STDEXCEPT
setsizeerr(gettext("==0 not redefined"));
#endif
return false;
}
virtual bool is_one() const {
#ifndef NO_STDEXCEPT
setsizeerr(gettext("==1 not redefined"));
#endif
return false;
}
virtual bool is_minus_one() const {
#ifndef NO_STDEXCEPT
setsizeerr(gettext("==-1 not redefined"));
#endif
return false;
}
virtual gen inv() const { return gensizeerr(gettext("Inv not redefined")); }
virtual gen conj(GIAC_CONTEXT) const { return gensizeerr(gettext("Conj not redefined"));}
virtual gen re(GIAC_CONTEXT) const { return gensizeerr(gettext("Real part not redefined"));}
virtual gen im(GIAC_CONTEXT) const { return gensizeerr(gettext("Imaginary part not redefined")); }
virtual gen abs(GIAC_CONTEXT) const { return gensizeerr(gettext("Abs not redefined"));}
virtual gen arg(GIAC_CONTEXT) const { return gensizeerr(gettext("Arg not redefined")); }
virtual gen sqrt(GIAC_CONTEXT) const { return gensizeerr(gettext("Sqrt not redefined")); }
virtual gen operator () (const gen &,GIAC_CONTEXT) const { return gensizeerr(gettext("() not redefined")); }
virtual gen operator [] (const gen &) { return gensizeerr(gettext("[] not redefined")); }
virtual bool operator == (const gen &) const {
#ifndef NO_STDEXCEPT
setsizeerr(gettext("== not redefined"));
#endif
return false;
}
virtual bool operator == (const gen_user & a) const { return (*this) == gen(a); }
// must redefine > AND <= since we do not have symetrical type arguments
virtual gen operator > (const gen &) const { return gensizeerr(gettext("== not redefined")); }
virtual gen operator > (const gen_user & a) const { return superieur_strict(*this, gen(a),0); }
virtual gen operator <= (const gen &) const { return gensizeerr(gettext("<= not redefined")); }
virtual gen operator <= (const gen_user & a) const { return inferieur_egal(*this, gen(a),0); }
virtual gen polygcd (const polynome &,const polynome &,polynome &) const { return gensizeerr(gettext("Polynomial gcd not redefined")); }
virtual gen polyfactor (const polynome & p,
factorization & f) const {
return gensizeerr(gettext("Polynomial gcd not redefined"));
}
virtual gen gcd (const gen &) const { return gensizeerr(gettext("gcd not redefined")); }
virtual gen gcd (const gen_user & a) const { return gcd(gen(a)); }
virtual std::string print (GIAC_CONTEXT) const { return "Nothing_to_print";}
void dbgprint () const { std::cerr << this->print(0) << std::endl;}
virtual std::string texprint (GIAC_CONTEXT) const { return "Nothing_to_print_tex"; }
virtual gen eval(int level,const context * contextptr) const {return *this;};
virtual gen evalf(int level,const context * contextptr) const {return *this;};
virtual gen makegen(int i) const { return string2gen("makegen not redefined"); } ;
virtual gen rand(GIAC_CONTEXT) const { return string2gen("rand not redefined"); };
};
struct ref_gen_user {
volatile int ref_count;
gen_user * u;
ref_gen_user(const gen_user & U):ref_count(1),u(U.memory_alloc()) {}
};
std::string print_the_type(int val,GIAC_CONTEXT);
// I/O
std::ostream & operator << (std::ostream & os,const gen & a);
std::istream & operator >> (std::istream & is,gen & a);
#if defined(GIAC_GENERIC_CONSTANTS) // || (defined(VISUALC) && !defined(RTOS_THREADX)) || defined(__x86_64__)
extern const gen zero;
#else
extern const gen & zero;
#endif
struct monome {
gen coeff;
gen exponent;
monome():coeff(0),exponent(0) {};
monome(const gen & mycoeff) : coeff(mycoeff),exponent(zero) {};
monome(const gen &mycoeff,const gen &myexponent) : coeff(mycoeff),exponent(myexponent) {};
std::string print() const ;
void dbgprint() const ;
};
std::ostream & operator << (std::ostream & os,const monome & m);
inline bool operator == (const monome & a,const monome & b){ return a.coeff==b.coeff && a.exponent==b.exponent; }
inline bool operator != (const monome & a,const monome & b){ return a.coeff!=b.coeff || a.exponent!=b.exponent; }
polynome apply( const polynome & p, const context * contextptr, gen (* f) (const gen &, const context *));
const char * printi(GIAC_CONTEXT);
std::string hexa_print_ZINT(const mpz_t & a);
std::string octal_print_ZINT(const mpz_t & a);
std::string binary_print_ZINT(const mpz_t & a);
std::string print_ZINT(const mpz_t & a);
std::string printinner_VECT(const vecteur & v, int subtype,GIAC_CONTEXT);
std::string & add_printinner_VECT(std::string & s,const vecteur &v,int subtype,GIAC_CONTEXT);
std::string begin_VECT_string(int subtype,bool tex,GIAC_CONTEXT);
std::string end_VECT_string(int subtype,bool tex,GIAC_CONTEXT);
std::string print_VECT(const vecteur & v,int subtype,GIAC_CONTEXT); // subtype was 0 by default
std::string print_SPOL1(const sparse_poly1 & p,GIAC_CONTEXT);
std::string print_STRNG(const std::string & s);
std::string printint32(int val,int subtype,GIAC_CONTEXT);
std::string print_FLOAT_(const giac_float & f,GIAC_CONTEXT);
// find closing or opening () [] {}
bool matchpos(const std::string & s,int & pos);
std::string cut_string(const std::string & chaine,int nchar,std::vector<int> & ligne_end) ;
std::string calc_endlines_positions(const vecteur & history_in,const vecteur & history_out,int nchar,std::vector<int> & endlines,std::vector<int> & positions);
bool is_operator_char(char c);
void increase_selection(const std::string & s,int & pos1,int& pos2);
void decrease_selection(const std::string & s,int & pos1,int& pos2);
void move_selection_right(const std::string & s,int & pos1, int & pos2);
void move_selection_left(const std::string & s,int & pos1, int & pos2);
std::string remove_extension(const std::string & chaine);
// This type collects global variables to enable threading
struct environment {
gen modulo; // characteristic
bool moduloon; // Set to false if non modular arithmetic required
bool complexe; // true if working on Z/pZ[i]
gen pn; // cardinal of the field, 0 means equal to modulo
gen coeff; // exemple of coeff, so that we can call coeff.makegen
environment(){
modulo=13;
moduloon=false;
complexe=false;
coeff=pn=0;
}
};
struct ref_sparse_poly1 {
volatile int ref_count;
sparse_poly1 s;
ref_sparse_poly1(const sparse_poly1 & S):ref_count(1),s(S) {}
};
// extern environment * env;
struct attributs {
int fontsize;
int background;
int text_color;
attributs(int f,int b,int t): fontsize(f),background(b),text_color(t) {};
attributs():fontsize(0),background(0),text_color(0) {};
};
// Terminal data for EQW display
struct eqwdata {
gen g;
attributs eqw_attributs;
int x,y,dx,dy;
bool selected;
bool active;
bool hasbaseline;
bool modifiable;
int baseline;
eqwdata(int dxx,int dyy,int xx, int yy,const attributs & a,const gen& gg):g(gg),eqw_attributs(a),x(xx),y(yy),dx(dxx),dy(dyy),selected(false),active(false),hasbaseline(false),modifiable(true),baseline(0) {};
eqwdata(int dxx,int dyy,int xx, int yy,const attributs & a,const gen& gg,int mybaseline):g(gg),eqw_attributs(a),x(xx),y(yy),dx(dxx),dy(dyy),selected(false),active(false),hasbaseline(true),modifiable(true),baseline(mybaseline) {};
void dbgprint(){ std::cerr << g << ":" << dx<< ","<< dy<< "+"<<x <<","<< y<< "," << baseline << "," << eqw_attributs.fontsize << "," << eqw_attributs.background << "," << eqw_attributs.text_color << std::endl; }
};
struct ref_eqwdata {
volatile int ref_count;
eqwdata e;
ref_eqwdata(const eqwdata & E): ref_count(1),e(E) {}
};
class identificateur {
public:
int * ref_count;
gen * value;
// std::string * name;
const char * id_name;
vecteur * localvalue;
// value / localvalue might be an assumption if it's a vecteur
// of subtype _ASSUME__VECT
// The first gen of an assumption vecteur is the type (_FRAC for rational)
// If the type is _REAL, the vecteur has 2 other elements
// * an interval or a _SET_VECT of intervals
// where interval=vecteur of length 2 of subtype _LINE__VECT
// * a list of excluded particular values
// If the type is _DOUBLE_ the variable will be evalf-ed but not eval-ed
// This is useful in geometry to make figures and get exact results
// If the type is _INT_ it
short int * quoted;
identificateur();
explicit identificateur(const std::string & s);
explicit identificateur(const char * s);
explicit identificateur(const char * s,const gen & e);
identificateur(const std::string & s,const gen & e);
identificateur(const identificateur & s);
~identificateur();
identificateur & operator =(const identificateur & s);
gen eval(int level,const gen & orig,const context * context_ptr) ;
bool in_eval(int level,const gen & orig,gen & evaled,const context * context_ptr, bool No38Lookup=false); // if No38Lookup, does not check if HP38 knows about this name...
const char * print(const context * context_ptr) const ;
std::string name() const { return id_name; }
void dbgprint() const { std::cout << this->print(context0); }
void unassign() ;
void push(int protection,const gen & e);
bool operator ==(const identificateur & i);
bool operator ==(const gen & i);
inline bool operator !=(const identificateur & i){ return !(*this==i); }
inline bool operator !=(const gen & i){ return !(*this==i);}
void MakeCopyOfNameIfNotLocal(); ///< if the name is not dynamicaly allocated, create a copy for that id.
};
struct ref_identificateur {
volatile int ref_count;
identificateur i;
ref_identificateur(const char * s):ref_count(1),i(s){}
ref_identificateur(const std::string & s):ref_count(1),i(s){}
ref_identificateur(const identificateur & s):ref_count(1),i(s){}
};
struct alias_ref_identificateur {
int i;
int * ref_count;
gen * value;
const char * id_name;
vecteur * localvalue;
short int * quoted;
};
struct ref_unary_function_ptr {
volatile int ref_count;
unary_function_ptr u;
ref_unary_function_ptr(const unary_function_ptr & U):ref_count(1),u(U) {}
ref_unary_function_ptr(const unary_function_ptr * U):ref_count(1),u(*U) {}
};
struct symbolic {
unary_function_ptr sommet;
gen feuille;
symbolic(const unary_function_ptr & o,const gen & e): sommet(o),feuille(e){};
symbolic(const unary_function_ptr & o,const gen & e1,const gen &e2): sommet(o), feuille(makevecteur(e1,e2)) {};
symbolic(const unary_function_ptr & o,const gen & e1,const gen &e2,const gen & e3): sommet(o), feuille(makevecteur(e1,e2,e3)) {};
symbolic(const unary_function_ptr & o,const gen & e1,const gen &e2,const gen & e3,const gen & e4): sommet(o), feuille(makevecteur(e1,e2,e3,e4)) {};
symbolic(const unary_function_ptr * o,const gen & e): sommet(*o),feuille(e){};
symbolic(const unary_function_ptr * o,const gen & e1,const gen &e2): sommet(*o), feuille(makevecteur(e1,e2)) {};
symbolic(const unary_function_ptr * o,const gen & e1,const gen &e2,const gen & e3): sommet(*o), feuille(makevecteur(e1,e2,e3)) {};
symbolic(const unary_function_ptr * o,const gen & e1,const gen &e2,const gen & e3,const gen & e4): sommet(*o), feuille(makevecteur(e1,e2,e3,e4)) {};
symbolic(const symbolic & mys) : sommet(mys.sommet),feuille(mys.feuille) {};
symbolic(const symbolic & mys,const gen & e);
symbolic(const gen & a,const unary_function_ptr & o,const gen & b);
symbolic(const gen & a,const unary_function_ptr * o,const gen & b);
std::string print(GIAC_CONTEXT) const;
void dbgprint() const{ std::cout << this->print(context0) << std::endl; }
gen eval(int level,const context * context_ptr) const;
gen evalf(int level,const context * context_ptr) const;
int size() const;
};
struct ref_symbolic {
volatile int ref_count;
symbolic s;
ref_symbolic(const symbolic & S):ref_count(1),s(S) {}
};
#ifdef SMARTPTR64
struct alias_ref_symbolic {
int ref_count;
unary_function_eval * sommet;
ulonglong feuille;
};
#else
struct alias_ref_symbolic {
int ref_count;
unary_function_eval * sommet;
unsigned char type; // see dispatch.h
signed char subtype;
unsigned short reserved; // not used
#ifdef DOUBLEVAL
longlong value;
#else
long value ;
#endif
};
#endif
#ifdef SMARTPTR64
inline mpz_t * gen::ref_ZINTptr() const { return & ((ref_mpz_t *) (* (longlong *) this >> 16))->z ; }
inline real_object * gen::ref_REALptr() const { return & ((ref_real_object *) (* (longlong *) this >> 16)) ->r; }
inline gen * gen::ref_CPLXptr() const { return & ((ref_complex *)(* (longlong *) this >> 16))->re; }
inline gen * gen::ref_MODptr () const { return & ((ref_modulo *)(* (longlong *) this >> 16))->n; }
inline gen * gen::ref_EXTptr () const { return & ((ref_algext *)(* (longlong *) this >> 16))->P; }
inline vecteur * gen::ref_VECTptr() const { return &((ref_vecteur*)(* (longlong *) this >> 16))->v; }
inline sparse_poly1 * gen::ref_SPOL1ptr() const { return &((ref_sparse_poly1*)(* (longlong *) this >> 16))->s; }
inline std::string * gen::ref_STRNGptr() const { return &((ref_string*)(* (longlong *) this >> 16))->s; }
inline gen_user * gen::ref_USERptr() const { return ((ref_gen_user*)(* (longlong *) this >> 16))->u; }
inline gen_map * gen::ref_MAPptr() const { return &((ref_gen_map*)(* (longlong *) this >> 16))->m; }
inline eqwdata * gen::ref_EQWptr() const { return &((ref_eqwdata*)(* (longlong *) this >> 16))->e; }
inline grob * gen::ref_GROBptr() const { return &((ref_grob*)(* (longlong *) this >> 16))->g; }
inline void * gen::ref_POINTER_val() const { return ((ref_void_pointer*)(* (longlong *) this >> 16))->p; }
inline Tfraction<gen> * gen::ref_FRACptr() const { return &((ref_fraction *)(* (longlong *) this >> 16))->f; }
inline polynome * gen::ref_POLYptr() const { return &((ref_polynome*)(* (longlong *) this >> 16))->t; }
inline identificateur * gen::ref_IDNTptr() const {return &((ref_identificateur*)(* (longlong *) this >> 16))->i; }
inline symbolic * gen::ref_SYMBptr() const { return &((ref_symbolic*)(* (longlong *) this >> 16))->s; }
inline unary_function_ptr * gen::ref_FUNCptr() const { return &((ref_unary_function_ptr*)(* (longlong *) this >> 16))->u; }
#else // SMARTPTR64
inline mpz_t * gen::ref_ZINTptr() const { return &__ZINTptr->z; }
inline real_object * gen::ref_REALptr() const { return &__REALptr->r; }
inline gen * gen::ref_CPLXptr() const { return &__CPLXptr->re; }
inline gen * gen::ref_MODptr () const { return &__MODptr->n; }
inline gen * gen::ref_EXTptr () const { return &__EXTptr->P; }
inline vecteur * gen::ref_VECTptr() const { return &__VECTptr->v; }
inline sparse_poly1 * gen::ref_SPOL1ptr() const { return &__SPOL1ptr->s; }
inline std::string * gen::ref_STRNGptr() const { return &__STRNGptr->s; }
inline gen_user * gen::ref_USERptr() const { return __USERptr->u; }
inline gen_map * gen::ref_MAPptr() const { return &__MAPptr->m; }
inline eqwdata * gen::ref_EQWptr() const { return &__EQWptr->e; }
inline grob * gen::ref_GROBptr() const { return &__GROBptr->g; }
inline void * gen::ref_POINTER_val() const { return __POINTERptr->p; }
inline Tfraction<gen> * gen::ref_FRACptr() const { return &__FRACptr->f; }
inline polynome * gen::ref_POLYptr() const { return &__POLYptr->t; }
inline identificateur * gen::ref_IDNTptr() const {return &__IDNTptr->i; }
inline symbolic * gen::ref_SYMBptr() const { return &__SYMBptr->s; }
// inline unary_function_ptr * gen::ref_FUNCptr() const { return &__FUNCptr->u; }
inline unary_function_ptr * gen::ref_FUNCptr() const { return (unary_function_ptr*) &_FUNC_; }
#endif // SMARTPTR64
#ifndef DOUBLEVAL
#define _DOUBLE_val DOUBLE_val()
#define _FLOAT_val FLOAT_val()
#endif // DOUBLEVAL
#define _ZINTptr ref_ZINTptr()
#define _REALptr ref_REALptr()
#define _CPLXptr ref_CPLXptr()
#define _IDNTptr ref_IDNTptr()
#define _SYMBptr ref_SYMBptr()
#define _MODptr ref_MODptr()
#define _FRACptr ref_FRACptr()
#define _EXTptr ref_EXTptr()
#define _POLYptr ref_POLYptr ()
#define _VECTptr ref_VECTptr()
#define _SPOL1ptr ref_SPOL1ptr()
#define _STRNGptr ref_STRNGptr()
#define _FUNCptr ref_FUNCptr()
#define _ROOTptr ref_ROOTptr()
#define _USERptr ref_USERptr()
#define _MAPptr ref_MAPptr()
#define _EQWptr ref_EQWptr()
#define _GROBptr ref_GROBptr()
#define _POINTER_val ref_POINTER_val()
// function that are indexed
extern const unsigned long alias_at_plus;
extern const unsigned long alias_at_neg;
extern const unsigned long alias_at_binary_minus;
extern const unsigned long alias_at_prod;
extern const unsigned long alias_at_division;
extern const unsigned long alias_at_inv;
extern const unsigned long alias_at_pow;
extern const unsigned long alias_at_exp;
extern const unsigned long alias_at_ln;
extern const unsigned long alias_at_abs;
extern const unsigned long alias_at_arg;
extern const unsigned long alias_at_pnt;
extern const unsigned long alias_at_point;
extern const unsigned long alias_at_segment;
extern const unsigned long alias_at_sto;
extern const unsigned long alias_at_sin;
extern const unsigned long alias_at_cos;
extern const unsigned long alias_at_tan;
extern const unsigned long alias_at_asin;
extern const unsigned long alias_at_acos;
extern const unsigned long alias_at_atan;
extern const unsigned long alias_at_sinh;
extern const unsigned long alias_at_cosh;
extern const unsigned long alias_at_tanh;
extern const unsigned long alias_at_asinh;
extern const unsigned long alias_at_acosh;
extern const unsigned long alias_at_atanh;
extern const unsigned long alias_at_interval;
extern const unsigned long alias_at_union;
extern const unsigned long alias_at_minus;
extern const unsigned long alias_at_intersect;
extern const unsigned long alias_at_not;
extern const unsigned long alias_at_and;
extern const unsigned long alias_at_ou;
extern const unsigned long alias_at_inferieur_strict;
extern const unsigned long alias_at_inferieur_egal;
extern const unsigned long alias_at_superieur_strict;
extern const unsigned long alias_at_superieur_egal;
extern const unsigned long alias_at_different;
extern const unsigned long alias_at_equal;
extern const unsigned long alias_at_rpn_prog;
extern const unsigned long alias_at_local;
extern const unsigned long alias_at_return;
extern const unsigned long alias_at_Dialog;
extern const unsigned long alias_at_double_deux_points;
extern const unsigned long alias_at_pointprod;
extern const unsigned long alias_at_pointdivision;
extern const unsigned long alias_at_pointpow;
extern const unsigned long alias_at_hash;
extern const unsigned long alias_at_pourcent;
extern const unsigned long alias_at_tilocal;
extern const unsigned long alias_at_break;
extern const unsigned long alias_at_continue;
extern const unsigned long alias_at_ampersand_times;
extern const unsigned long alias_at_maple_lib;
extern const unsigned long alias_at_unit;
extern const unsigned long alias_at_plot_style;
extern const unsigned long alias_at_xor;
extern const unsigned long alias_at_check_type;
extern const unsigned long alias_at_quote_pow;
extern const unsigned long alias_at_case;
extern const unsigned long alias_at_dollar;
extern const unsigned long alias_at_IFTE;
extern const unsigned long alias_at_RPN_CASE;
extern const unsigned long alias_at_RPN_LOCAL;
extern const unsigned long alias_at_RPN_FOR;
extern const unsigned long alias_at_RPN_WHILE;
extern const unsigned long alias_at_NOP;
extern const unsigned long alias_at_unit;
extern const unsigned long alias_at_ifte;
extern const unsigned long alias_at_for;
extern const unsigned long alias_at_bloc;
extern const unsigned long alias_at_program;
extern const unsigned long alias_at_same;
extern const unsigned long alias_at_increment;
extern const unsigned long alias_at_decrement;
extern const unsigned long alias_at_multcrement;
extern const unsigned long alias_at_divcrement;
extern const unsigned long alias_at_sq;
extern const unsigned long alias_at_display;
extern const unsigned long alias_at_of;
extern const unsigned long alias_at_at;
extern const unsigned long alias_at_normalmod;
#ifdef BCD
inline bool ck_gentobcd(const gen & g,accurate_bcd_float * bcdptr){
if (g.type!=_FLOAT_)
return false;
fExpand(g._FLOAT_val.f,bcdptr);
return true;
}
inline accurate_bcd_float * gentobcd(const gen & g,accurate_bcd_float * bcdptr){
return fExpand(g._FLOAT_val.f,bcdptr);
}
#endif
// should be in input_lexer.h
// return true/false to tell if s is recognized. return the appropriate gen if true
bool CasIsBuildInFunction(char const *s, gen &g);
#ifndef NO_NAMESPACE_GIAC
} // namespace giac
#endif // ndef NO_NAMESPACE_GIAC
#endif // _GIAC_GEN_H