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/* Copyright (C) 2000 MySQL AB
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; version 2 of the License.
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., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */
#ifndef DRIZZLED_DECIMAL_H
#define DRIZZLED_DECIMAL_H
#include <assert.h>
#include <drizzled/sql_string.h>
#include "drizzled/definitions.h"
#include "drizzled/drizzle_time.h"
namespace drizzled
{
typedef enum
{TRUNCATE=0, HALF_EVEN, HALF_UP, CEILING, FLOOR}
decimal_round_mode;
typedef int32_t decimal_digit_t;
typedef struct st_decimal_t {
int intg, frac, len;
bool sign;
decimal_digit_t *buf;
} decimal_t;
int internal_str2dec(char *from, decimal_t *to, char **end,
bool fixed);
int decimal2string(const decimal_t *from, char *to, int *to_len,
int fixed_precision, int fixed_decimals,
char filler);
int decimal2uint64_t(const decimal_t *from, uint64_t *to);
int uint64_t2decimal(const uint64_t from, decimal_t *to);
int decimal2int64_t(const decimal_t *from, int64_t *to);
int int64_t2decimal(const int64_t from, decimal_t *to);
int decimal2double(const decimal_t *from, double *to);
int double2decimal(const double from, decimal_t *to);
int decimal_actual_fraction(decimal_t *from);
int decimal2bin(const decimal_t *from, unsigned char *to, int precision, int scale);
int bin2decimal(const unsigned char *from, decimal_t *to, int precision, int scale);
int decimal_bin_size(int precision, int scale);
int decimal_intg(const decimal_t *from);
int decimal_add(const decimal_t *from1, const decimal_t *from2, decimal_t *to);
int decimal_sub(const decimal_t *from1, const decimal_t *from2, decimal_t *to);
int decimal_cmp(const decimal_t *from1, const decimal_t *from2);
int decimal_mul(const decimal_t *from1, const decimal_t *from2, decimal_t *to);
int decimal_div(const decimal_t *from1, const decimal_t *from2, decimal_t *to,
int scale_incr);
int decimal_mod(const decimal_t *from1, const decimal_t *from2, decimal_t *to);
int decimal_round(const decimal_t *from, decimal_t *to, int new_scale,
decimal_round_mode mode);
int decimal_is_zero(const decimal_t *from);
void max_decimal(int precision, int frac, decimal_t *to);
#define string2decimal(A,B,C) internal_str2dec((A), (B), (C), 0)
/* set a decimal_t to zero */
#define decimal_make_zero(dec) do { \
(dec)->buf[0]=0; \
(dec)->intg=1; \
(dec)->frac=0; \
(dec)->sign=0; \
} while(0)
/*
returns the length of the buffer to hold string representation
of the decimal (including decimal dot, possible sign and \0)
*/
#define decimal_string_size(dec) (((dec)->intg ? (dec)->intg : 1) + \
(dec)->frac + ((dec)->frac > 0) + 2)
/* negate a decimal */
#define decimal_neg(dec) do { (dec)->sign^=1; } while(0)
/*
conventions:
decimal_smth() == 0 -- everything's ok
decimal_smth() <= 1 -- result is usable, but precision loss is possible
decimal_smth() <= 2 -- result can be unusable, most significant digits
could've been lost
decimal_smth() > 2 -- no result was generated
*/
#define E_DEC_OK 0
#define E_DEC_TRUNCATED 1
#define E_DEC_OVERFLOW 2
#define E_DEC_DIV_ZERO 4
#define E_DEC_BAD_NUM 8
#define E_DEC_OOM 16
#define E_DEC_ERROR 31
#define E_DEC_FATAL_ERROR 30
#define DECIMAL_LONGLONG_DIGITS 22
#define DECIMAL_LONG_DIGITS 10
#define DECIMAL_LONG3_DIGITS 8
/** maximum length of buffer in our big digits (uint32_t). */
#define DECIMAL_BUFF_LENGTH 9
/* the number of digits that my_decimal can possibly contain */
#define DECIMAL_MAX_POSSIBLE_PRECISION (DECIMAL_BUFF_LENGTH * 9)
/**
maximum guaranteed precision of number in decimal digits (number of our
digits * number of decimal digits in one our big digit - number of decimal
digits in one our big digit decreased by 1 (because we always put decimal
point on the border of our big digits))
*/
#define DECIMAL_MAX_PRECISION (DECIMAL_MAX_POSSIBLE_PRECISION - 8*2)
#define DECIMAL_MAX_SCALE 30
#define DECIMAL_NOT_SPECIFIED 31
/**
maximum length of string representation (number of maximum decimal
digits + 1 position for sign + 1 position for decimal point)
*/
#define DECIMAL_MAX_STR_LENGTH (DECIMAL_MAX_POSSIBLE_PRECISION + 2)
/**
maximum size of packet length.
*/
#define DECIMAL_MAX_FIELD_SIZE DECIMAL_MAX_PRECISION
inline int my_decimal_int_part(uint32_t precision, uint32_t decimals)
{
return precision - ((decimals == DECIMAL_NOT_SPECIFIED) ? 0 : decimals);
}
/**
my_decimal class limits 'decimal_t' type to what we need in MySQL.
It contains internally all necessary space needed by the instance so
no extra memory is needed. One should call fix_buffer_pointer() function
when he moves my_decimal objects in memory.
*/
class my_decimal :public decimal_t
{
decimal_digit_t buffer[DECIMAL_BUFF_LENGTH];
public:
void init()
{
len= DECIMAL_BUFF_LENGTH;
buf= buffer;
#if !defined (HAVE_purify)
/* Set buffer to 'random' value to find wrong buffer usage */
for (uint32_t i= 0; i < DECIMAL_BUFF_LENGTH; i++)
buffer[i]= i;
#endif
}
my_decimal()
{
init();
}
void fix_buffer_pointer() { buf= buffer; }
bool sign() const { return decimal_t::sign; }
void sign(bool s) { decimal_t::sign= s; }
uint32_t precision() const { return intg + frac; }
};
int decimal_operation_results(int result);
inline void max_my_decimal(my_decimal *to, int precision, int frac)
{
assert((precision <= DECIMAL_MAX_PRECISION)&&
(frac <= DECIMAL_MAX_SCALE));
max_decimal(precision, frac, (decimal_t*) to);
}
inline void max_internal_decimal(my_decimal *to)
{
max_my_decimal(to, DECIMAL_MAX_PRECISION, 0);
}
inline int check_result(uint32_t mask, int result)
{
if (result & mask)
decimal_operation_results(result);
return result;
}
inline int check_result_and_overflow(uint32_t mask, int result, my_decimal *val)
{
if (check_result(mask, result) & E_DEC_OVERFLOW)
{
bool sign= val->sign();
val->fix_buffer_pointer();
max_internal_decimal(val);
val->sign(sign);
}
return result;
}
inline uint32_t my_decimal_length_to_precision(uint32_t length, uint32_t scale,
bool unsigned_flag)
{
return (uint32_t) (length - (scale>0 ? 1:0) - (unsigned_flag ? 0:1));
}
inline uint32_t my_decimal_precision_to_length(uint32_t precision, uint8_t scale,
bool unsigned_flag)
{
set_if_smaller(precision, (uint32_t)DECIMAL_MAX_PRECISION);
return static_cast<uint32_t>(precision + (scale>0 ? 1:0) + (unsigned_flag ? 0:1));
}
inline
int my_decimal_string_length(const my_decimal *d)
{
return decimal_string_size(d);
}
inline
int my_decimal_max_length(const my_decimal *d)
{
/* -1 because we do not count \0 */
return decimal_string_size(d) - 1;
}
inline
int my_decimal_get_binary_size(uint32_t precision, uint32_t scale)
{
return decimal_bin_size(static_cast<int>(precision), static_cast<int>(scale));
}
inline
void my_decimal2decimal(const my_decimal *from, my_decimal *to)
{
*to= *from;
to->fix_buffer_pointer();
}
int my_decimal2binary(uint32_t mask, const my_decimal *d, unsigned char *bin, int prec,
int scale);
inline
int binary2my_decimal(uint32_t mask, const unsigned char *bin, my_decimal *d, int prec,
int scale)
{
return check_result(mask, bin2decimal(bin, static_cast<decimal_t*>(d), prec, scale));
}
inline
int my_decimal_set_zero(my_decimal *d)
{
decimal_make_zero(static_cast<decimal_t*> (d));
return 0;
}
inline
bool my_decimal_is_zero(const my_decimal *decimal_value)
{
return decimal_is_zero(static_cast<const decimal_t*>(decimal_value));
}
inline
int my_decimal_round(uint32_t mask, const my_decimal *from, int scale,
bool truncate, my_decimal *to)
{
return check_result(mask, decimal_round(static_cast<const decimal_t*>(from), to, scale,
(truncate ? TRUNCATE : HALF_UP)));
}
inline
int my_decimal_floor(uint32_t mask, const my_decimal *from, my_decimal *to)
{
return check_result(mask, decimal_round(static_cast<const decimal_t*>(from), to, 0, FLOOR));
}
inline
int my_decimal_ceiling(uint32_t mask, const my_decimal *from, my_decimal *to)
{
return check_result(mask, decimal_round(static_cast<const decimal_t*>(from), to, 0, CEILING));
}
int my_decimal2string(uint32_t mask, const my_decimal *d, uint32_t fixed_prec,
uint32_t fixed_dec, char filler, String *str);
inline
int my_decimal2int(uint32_t mask, const my_decimal *d, bool unsigned_flag,
int64_t *l)
{
my_decimal rounded;
/* decimal_round can return only E_DEC_TRUNCATED */
decimal_round(static_cast<const decimal_t*>(d), &rounded, 0, HALF_UP);
return check_result(mask, (unsigned_flag ?
decimal2uint64_t(&rounded, reinterpret_cast<uint64_t *>(l)) :
decimal2int64_t(&rounded, l)));
}
inline
int my_decimal2double(uint32_t, const my_decimal *d, double *result)
{
/* No need to call check_result as this will always succeed */
return decimal2double(static_cast<const decimal_t*>(d), result);
}
inline
int str2my_decimal(uint32_t mask, char *str, my_decimal *d, char **end)
{
return check_result_and_overflow(mask, string2decimal(str, static_cast<decimal_t*>(d),end),
d);
}
int str2my_decimal(uint32_t mask, const char *from, uint32_t length,
const CHARSET_INFO * charset, my_decimal *decimal_value);
inline
int string2my_decimal(uint32_t mask, const String *str, my_decimal *d)
{
return str2my_decimal(mask, str->ptr(), str->length(), str->charset(), d);
}
my_decimal *date2my_decimal(DRIZZLE_TIME *ltime, my_decimal *dec);
inline
int double2my_decimal(uint32_t mask, double val, my_decimal *d)
{
return check_result_and_overflow(mask, double2decimal(val, static_cast<decimal_t*>(d)), d);
}
inline
int int2my_decimal(uint32_t mask, int64_t i, bool unsigned_flag, my_decimal *d)
{
return check_result(mask, (unsigned_flag ?
uint64_t2decimal(static_cast<uint64_t>(i), d) :
int64_t2decimal(i, d)));
}
inline
void my_decimal_neg(decimal_t *arg)
{
if (decimal_is_zero(arg))
{
arg->sign= 0;
return;
}
decimal_neg(arg);
}
inline
int my_decimal_add(uint32_t mask, my_decimal *res, const my_decimal *a,
const my_decimal *b)
{
return check_result_and_overflow(mask,
decimal_add(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b), res),
res);
}
inline
int my_decimal_sub(uint32_t mask, my_decimal *res, const my_decimal *a,
const my_decimal *b)
{
return check_result_and_overflow(mask,
decimal_sub(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b), res),
res);
}
inline
int my_decimal_mul(uint32_t mask, my_decimal *res, const my_decimal *a,
const my_decimal *b)
{
return check_result_and_overflow(mask,
decimal_mul(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b),res),
res);
}
inline
int my_decimal_div(uint32_t mask, my_decimal *res, const my_decimal *a,
const my_decimal *b, int div_scale_inc)
{
return check_result_and_overflow(mask,
decimal_div(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b),res,
div_scale_inc),
res);
}
inline
int my_decimal_mod(uint32_t mask, my_decimal *res, const my_decimal *a,
const my_decimal *b)
{
return check_result_and_overflow(mask,
decimal_mod(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b),res),
res);
}
/**
@return
-1 if a<b, 1 if a>b and 0 if a==b
*/
inline
int my_decimal_cmp(const my_decimal *a, const my_decimal *b)
{
return decimal_cmp(static_cast<const decimal_t*>(a),
static_cast<const decimal_t*>(b));
}
inline
int my_decimal_intg(const my_decimal *a)
{
return decimal_intg(static_cast<const decimal_t*>(a));
}
void my_decimal_trim(uint32_t *precision, uint32_t *scale);
} /* namespace drizzled */
#endif /* DRIZZLED_DECIMAL_H */
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