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/* ********************************************************************** */
/* num.h */
/* ********************************************************************** */

#ifndef _NUM_H_
#define _NUM_H_

#include <stdlib.h>
#include <stdio.h>
#include <limits.h>
#include <string.h>
#include <assert.h>
#include <math.h>
#include <stdint.h>
#include "gmp.h"
#include "mpfr.h"

/* Be aware: 
   we erase the (obsolete) GMP function mpq_set_num */
#undef mpq_set_num

#include "num_config.h"

#if defined(NUM_LONGINT) || defined(NUM_LONGLONGINT) || defined(NUM_MPZ)
#include "num_numint.h"
#elif defined(NUM_LONGRAT) || defined(NUM_LONGLONGRAT) || defined(NUM_MPQ)
#include "num_numrat.h"
#elif defined(NUM_DOUBLE) || defined(NUM_LONGDOUBLE) || defined(NUM_MPFR)
#include "num_numflt.h"
#else
#error "HERE"
#endif

#include "num_name.h"

#ifdef __cplusplus
extern "C" {
#endif

/* Parameter: one of the following macros should be defined:
   NUM_LONGINT,
   NUM_LONGLONGINT,
   NUM_MPZ,

   NUM_LONGRAT,
   NUM_LONGLONGRAT,
   NUM_MPQ,

   NUM_DOUBLE,
   NUM_LONGDOUBLE,
   NUM_MPFR

   Each parameter induces the definition of the following macros:
   NUM_LONGINT:     NUM_NUMINT, NUMINT_LONGINT,     NUM_MAX, NUMINT_MAX, NUM_NATIVE, NUMINT_NATIVE
   NUM_LONGLONGINT: NUM_NUMINT, NUMINT_LONGLONGINT, NUM_MAX, NUMINT_MAX, NUM_NATIVE, NUMINT_NATIVE
   NUM_MPZ:         NUM_NUMINT, NUMINT_MPZ 

   NUM_LONGRAT:     NUM_NUMRAT, NUMINT_LONGINT,     NUM_NATIVE, NUMINT_NATIVE
   NUM_LONGLONGRAT: NUM_NUMRAT, NUMINT_LONGLONGINT, NUM_NATIVE, NUMINT_NATIVE
   NUM_MPQ:         NUM_NUMRAT, NUMINT_MPZ 

   NUM_DOUBLE:      NUM_NUMFLT, NUMFLT_DOUBLE,      NUM_MAX, NUMFLT_MAX, NUM_NATIVE, NUMFLT_NATIVE
   NUM_LONGDOUBLE:  NUM_NUMFLT, NUMFLT_LONGDOUBLE,  NUM_MAX, NUMFLT_MAX, NUM_NATIVE, NUMFLT_NATIVE

   Additionally, the following macros are defined:
   NUM_NAME       litteral string with human-readable name of number type
   NUM_SUFFIX     tag uniquely defining the number type (can be used as a function suffix)
   NUM_AP_SCALAR  preferred AP_SCALAR_ type
   NUMFUN(x)      name-mangling: append NUM_SUFFIX to x
*/

/* ====================================================================== */
/* Assignement */
/* ====================================================================== */
static inline void num_set(num_t a, num_t b);
static inline void num_set_array(num_t* a, num_t* b, size_t size);
static inline void num_set_int(num_t a, long int i);

/* ====================================================================== */
/* Constructors and Destructors */
/* ====================================================================== */

static inline void num_init(num_t a);
static inline void num_init_array(num_t* a, size_t size);
static inline void num_init_set(num_t a, num_t b);
static inline void num_init_set_int(num_t a, long int i);

static inline void num_clear(num_t a);
static inline void num_clear_array(num_t* a, size_t size);

static inline void num_swap(num_t a, num_t b);

/* ====================================================================== */
/* Arithmetic Operations */
/* ====================================================================== */

static inline void num_neg(num_t a, num_t b);
static inline void num_abs(num_t a, num_t b);
static inline void num_add(num_t a, num_t b, num_t c);
static inline void num_add_uint(num_t a, num_t b, unsigned long int c);
static inline void num_sub(num_t a, num_t b, num_t c);
static inline void num_sub_uint(num_t a, num_t b, unsigned long int c);
static inline void num_mul(num_t a, num_t b, num_t c);
static inline void num_mul_2(num_t a, num_t b);
static inline void num_div(num_t a, num_t b, num_t c);
static inline void num_div_2(num_t a, num_t b);
static inline void num_min(num_t a, num_t b, num_t c);
static inline void num_max(num_t a, num_t b, num_t c);

static inline void num_mul_2exp(num_t a, num_t b, int c);
  /* multiplies b by 2^c (c can be positive or negative) */

static inline void num_floor(num_t a, num_t b);
static inline void num_ceil(num_t a, num_t b);
static inline void num_trunc(num_t a, num_t b);
  /* Approximate to the nearest integer toward resp. -infty, +infty */

static inline void num_sqrt(num_t up, num_t down, num_t b);
  /* Compute both an upper bound and a lower bound */

/* ====================================================================== */
/* Arithmetic Tests */
/* ====================================================================== */

static inline int num_sgn(num_t a);
static inline int num_cmp(num_t a, num_t b);
static inline int num_cmp_int(num_t a, long int b);
static inline bool num_equal(num_t a, num_t b);
static inline bool num_integer(num_t a);

/* ====================================================================== */
/* Printing */
/* ====================================================================== */

static inline void num_print(num_t a);
static inline void num_fprint(FILE* stream, num_t a);
static inline int num_snprint(char* s, size_t size, num_t a);

/* ====================================================================== */
/* Conversions */
/* ====================================================================== */

static inline bool num_set_int2(num_t a, long int i, long int j);
  /* int2 -> num */
static inline bool num_set_mpz(num_t a, mpz_t b);
  /* mpz -> num */
static inline bool num_set_mpq(num_t a, mpq_t b);
  /* mpq -> num */
static inline bool num_set_double(num_t a, double b);
  /* double -> num */
static inline bool num_set_mpfr(num_t a, mpfr_t b);
  /* mpfr -> num */
static inline bool num_set_ap_scalar(num_t a, ap_scalar_t* b);
  /* (finite) ap_scalar -> num */

static inline bool int_set_num(long int* a, num_t b);
  /* num -> int */
static inline bool mpz_set_num(mpz_t a, num_t b);
  /* num -> mpz */
static inline bool mpq_set_num(mpq_t a, num_t b);
  /* num -> mpq */
static inline bool double_set_num(double* a, num_t b);
  /* num -> double */
static inline bool float_set_num(float* a, num_t b);
  /* num -> float */
static inline bool mpfr_set_num(mpfr_t a, num_t b);
  /* num -> mpfr */
static inline bool ap_scalar_set_num(ap_scalar_t* a, num_t b);
  /* num -> ap_scalar */

static inline bool mpz_fits_num(mpz_t a);
static inline bool mpq_fits_num(mpq_t a);
static inline bool double_fits_num(double a);
static inline bool mpfr_fits_num(mpfr_t a);
static inline bool num_fits_int(num_t a);
static inline bool num_fits_float(num_t a);
static inline bool num_fits_double(num_t a);
static inline bool num_fits_mpfr(num_t a);

/* Optimized versions */
/* mpfr should have exactly the precision NUMFLT_MANT_DIG */
static inline bool num_set_mpz_tmp(num_t a, mpz_t b, mpfr_t mpfr);
static inline bool num_set_mpq_tmp(num_t a, mpq_t b, 
				   mpz_t q, mpz_t r, mpfr_t mpfr);
static inline bool num_set_double_tmp(num_t a, double k, mpq_t mpq);

static inline bool int_set_num_tmp(long int* a, num_t b, 
				   mpz_t q, mpz_t r);
static inline bool mpz_set_num_tmp(mpz_t a, num_t b, mpz_t mpz);
/* mpfr should have exactly the precision DBL_MANT_DIG */
static inline bool double_set_num_tmp(double* a, num_t b, 
				      mpq_t mpq, mpfr_t mpfr);

static inline bool mpq_fits_num_tmp(mpq_t a, mpz_t mpz);
static inline bool double_fits_num_tmp(double k, mpq_t mpq);

/* ====================================================================== */
/* Serialization */
/* ====================================================================== */

/* Notes:
   - call _serialized_size to get the minimal size of the buffer to allocate
   - _serialize then returns the actual size of the serialized data (may be 
   less than _serialized_size)
   - deserialze assumes that the num destination has already been initialized
   - when deserializing an array, you must supply the number of elements in the
   array (it is not stored with the array by serialize)
   - serialization is not type-safe (it depends on the chosen numerical type
   and, for types using native integers, on whether the machine is 32 or 64 
   bits). You can only deserialize data if the num_serialize_id function 
   returns the same value as when the data was serialized. (This id is not
   stored systematically with each serialized number to save state, so, the
   checking is up to you.)
*/

static inline unsigned char num_serialize_id(void);

static inline size_t num_serialize(void* dst, num_t src);
static inline size_t num_deserialize(num_t dst, const void* src);
static inline size_t num_serialized_size(num_t a);

static inline size_t num_serialize_array(void* dst, num_t* src, size_t size)
{
  size_t i,n=0;
  for (i=0;i<size;i++)
    n += num_serialize((char*)dst+n,src[i]);
  return n;
}

static inline size_t num_deserialize_array(num_t* dst, const void* src, size_t size)
{
  size_t i,n=0;
  for (i=0;i<size;i++)
    n += num_deserialize(dst[i],(const char*)src+n);
  return n;
}

static inline size_t num_serialized_size_array(num_t* src, size_t size)
{
  size_t i,n=0;
  for (i=0;i<size;i++)
    n += num_serialized_size(src[i]);
  return n;
}

#ifdef __cplusplus
}
#endif

#endif