postgresql/src/backend/utils/adt/int.c

/*-------------------------------------------------------------------------
 *
 * int.c--
 *	  Functions for the built-in integer types.
 *
 * Copyright (c) 1994, Regents of the University of California
 *
 *
 * IDENTIFICATION
 *	  $Header: /cvsroot/pgsql/src/backend/utils/adt/int.c,v 1.5 1997/09/07 04:50:21 momjian Exp $
 *
 *-------------------------------------------------------------------------
 */
/*
 * OLD COMMENTS
 *		I/O routines:
 *		 int2in, int2out, int28in, int28out, int4in, int4out
 *		Conversion routines:
 *		 itoi
 *		Boolean operators:
 *		 inteq, intne, intlt, intle, intgt, intge
 *		Arithmetic operators:
 *		 intpl, intmi, int4mul, intdiv
 *
 *		Arithmetic operators:
 *		 intmod, int4fac
 *
 * XXX makes massive and possibly unwarranted type promotion assumptions.
 * fix me when we figure out what we want to do about ANSIfication...
 */
#include <stdio.h>

#include "postgres.h"
#include "fmgr.h"
#include "utils/builtins.h"		/* where the declarations go */

/*****************************************************************************
 *	 USER I/O ROUTINES														 *
 *****************************************************************************/

/*
 *		int2in			- converts "num" to short
 */
int32
int2in(char *num)
{
	return ((int32) pg_atoi(num, sizeof(int16), '\0'));
}

/*
 *		int2out			- converts short to "num"
 */
char		   *
int2out(int16 sh)
{
	char		   *result;

	result = (char *) palloc(7);/* assumes sign, 5 digits, '\0' */
	itoa((int) sh, result);
	return (result);
}

/*
 *		int28in			- converts "num num ..." to internal form
 *
 *		Note:
 *				Fills any nonexistent digits with NULLs.
 */
int16		   *
int28in(char *shs)
{
	register		int16(*result)[];
	int				nums;

	if (shs == NULL)
		return (NULL);
	result = (int16(*)[]) palloc(sizeof(int16[8]));
	if ((nums = sscanf(shs, "%hd%hd%hd%hd%hd%hd%hd%hd",
					   *result,
					   *result + 1,
					   *result + 2,
					   *result + 3,
					   *result + 4,
					   *result + 5,
					   *result + 6,
					   *result + 7)) != 8)
	{
		do
			(*result)[nums++] = 0;
		while (nums < 8);
	}
	return ((int16 *) result);
}

/*
 *		int28out		- converts internal form to "num num ..."
 */
char		   *
int28out(int16(*shs)[])
{
	register int	num;
	register int16 *sp;
	register char  *rp;
	char		   *result;

	if (shs == NULL)
	{
		result = (char *) palloc(2);
		result[0] = '-';
		result[1] = '\0';
		return (result);
	}
	rp = result = (char *) palloc(8 * 7);		/* assumes sign, 5 digits,
												 * ' ' */
	sp = *shs;
	for (num = 8; num != 0; num--)
	{
		itoa(*sp++, rp);
		while (*++rp != '\0')
			;
		*rp++ = ' ';
	}
	*--rp = '\0';
	return (result);
}

/*
 *		int28in			- converts "num num ..." to internal form
 *
 *		Note:
 *				Fills any nonexistent digits with NULLs.
 */
int32		   *
int44in(char *input_string)
{
	int32		   *foo = (int32 *) palloc(4 * sizeof(int32));
	register int	i = 0;

	i = sscanf(input_string,
			   "%d, %d, %d, %d",
			   &foo[0],
			   &foo[1],
			   &foo[2],
			   &foo[3]);
	while (i < 4)
		foo[i++] = 0;

	return (foo);
}

/*
 *		int28out		- converts internal form to "num num ..."
 */
char		   *
int44out(int32 an_array[])
{
	int				temp = 4;
	char		   *output_string = NULL;
	int				i;

	if (temp > 0)
	{
		char		   *walk;

		output_string = (char *) palloc(16 * temp);		/* assume 15 digits +
														 * sign */
		walk = output_string;
		for (i = 0; i < temp; i++)
		{
			itoa(an_array[i], walk);
			while (*++walk != '\0')
				;
			*walk++ = ' ';
		}
		*--walk = '\0';
	}
	return (output_string);
}


/*****************************************************************************
 *	 PUBLIC ROUTINES														 *
 *****************************************************************************/

/*
 *		int4in			- converts "num" to int4
 */
int32
int4in(char *num)
{
	return (pg_atoi(num, sizeof(int32), '\0'));
}

/*
 *		int4out			- converts int4 to "num"
 */
char		   *
int4out(int32 l)
{
	char		   *result;

	result = (char *) palloc(12);		/* assumes sign, 10 digits, '\0' */
	ltoa(l, result);
	return (result);
}


/*
 *		===================
 *		CONVERSION ROUTINES
 *		===================
 */

int32
i2toi4(int16 arg1)
{
	return ((int32) arg1);
}

int16
i4toi2(int32 arg1)
{
	if (arg1 < -0x8000)
		elog(NOTICE, "i4toi2: \"%d\" causes int2 underflow", arg1);
	if (arg1 > 0x7FFF)
		elog(NOTICE, "i4toi2: \"%d\" causes int2 overflow", arg1);

	return ((int16) arg1);
}


/*
 *		=========================
 *		BOOLEAN OPERATOR ROUTINES
 *		=========================
 */

/*
 *		inteq			- returns 1 iff arg1 == arg2
 *		intne			- returns 1 iff arg1 != arg2
 *		intlt			- returns 1 iff arg1 < arg2
 *		intle			- returns 1 iff arg1 <= arg2
 *		intgt			- returns 1 iff arg1 > arg2
 *		intge			- returns 1 iff arg1 >= arg2
 */
bool			int4eq(int32 arg1, int32 arg2)
{
	return (arg1 == arg2);
}
bool			int4ne(int32 arg1, int32 arg2)
{
	return (arg1 != arg2);
}
bool			int4lt(int32 arg1, int32 arg2)
{
	return (arg1 < arg2);
}
bool			int4le(int32 arg1, int32 arg2)
{
	return (arg1 <= arg2);
}
bool			int4gt(int32 arg1, int32 arg2)
{
	return (arg1 > arg2);
}
bool			int4ge(int32 arg1, int32 arg2)
{
	return (arg1 >= arg2);
}

bool			int2eq(int16 arg1, int16 arg2)
{
	return (arg1 == arg2);
}
bool			int2ne(int16 arg1, int16 arg2)
{
	return (arg1 != arg2);
}
bool			int2lt(int16 arg1, int16 arg2)
{
	return (arg1 < arg2);
}
bool			int2le(int16 arg1, int16 arg2)
{
	return (arg1 <= arg2);
}
bool			int2gt(int16 arg1, int16 arg2)
{
	return (arg1 > arg2);
}
bool			int2ge(int16 arg1, int16 arg2)
{
	return (arg1 >= arg2);
}

bool			int24eq(int32 arg1, int32 arg2)
{
	return (arg1 == arg2);
}
bool			int24ne(int32 arg1, int32 arg2)
{
	return (arg1 != arg2);
}
bool			int24lt(int32 arg1, int32 arg2)
{
	return (arg1 < arg2);
}
bool			int24le(int32 arg1, int32 arg2)
{
	return (arg1 <= arg2);
}
bool			int24gt(int32 arg1, int32 arg2)
{
	return (arg1 > arg2);
}
bool			int24ge(int32 arg1, int32 arg2)
{
	return (arg1 >= arg2);
}

bool			int42eq(int32 arg1, int32 arg2)
{
	return (arg1 == arg2);
}
bool			int42ne(int32 arg1, int32 arg2)
{
	return (arg1 != arg2);
}
bool			int42lt(int32 arg1, int32 arg2)
{
	return (arg1 < arg2);
}
bool			int42le(int32 arg1, int32 arg2)
{
	return (arg1 <= arg2);
}
bool			int42gt(int32 arg1, int32 arg2)
{
	return (arg1 > arg2);
}
bool			int42ge(int32 arg1, int32 arg2)
{
	return (arg1 >= arg2);
}


bool			keyfirsteq(int16 * arg1, int16 arg2)
{
	return (*arg1 == arg2);
}

/*
 *		int[24]pl		- returns arg1 + arg2
 *		int[24]mi		- returns arg1 - arg2
 *		int[24]mul		- returns arg1 * arg2
 *		int[24]div		- returns arg1 / arg2
 */
int32			int4um(int32 arg)
{
	return (-arg);
}
int32			int4pl(int32 arg1, int32 arg2)
{
	return (arg1 + arg2);
}
int32			int4mi(int32 arg1, int32 arg2)
{
	return (arg1 - arg2);
}
int32			int4mul(int32 arg1, int32 arg2)
{
	return (arg1 * arg2);
}
int32			int4div(int32 arg1, int32 arg2)
{
	return (arg1 / arg2);
}
int32			int4inc(int32 arg)
{
	return (arg + (int32) 1);
}

int16			int2um(int16 arg)
{
	return (-arg);
}
int16			int2pl(int16 arg1, int16 arg2)
{
	return (arg1 + arg2);
}
int16			int2mi(int16 arg1, int16 arg2)
{
	return (arg1 - arg2);
}
int16			int2mul(int16 arg1, int16 arg2)
{
	return (arg1 * arg2);
}
int16			int2div(int16 arg1, int16 arg2)
{
	return (arg1 / arg2);
}
int16			int2inc(int16 arg)
{
	return (arg + (int16) 1);
}

int32			int24pl(int32 arg1, int32 arg2)
{
	return (arg1 + arg2);
}
int32			int24mi(int32 arg1, int32 arg2)
{
	return (arg1 - arg2);
}
int32			int24mul(int32 arg1, int32 arg2)
{
	return (arg1 * arg2);
}
int32			int24div(int32 arg1, int32 arg2)
{
	return (arg1 / arg2);
}

int32			int42pl(int32 arg1, int32 arg2)
{
	return (arg1 + arg2);
}
int32			int42mi(int32 arg1, int32 arg2)
{
	return (arg1 - arg2);
}
int32			int42mul(int32 arg1, int32 arg2)
{
	return (arg1 * arg2);
}
int32			int42div(int32 arg1, int32 arg2)
{
	return (arg1 / arg2);
}

/*
 *		int[24]mod		- returns arg1 mod arg2
 */
int32			int4mod(int32 arg1, int32 arg2)
{
	return (arg1 % arg2);
}
int32			int2mod(int16 arg1, int16 arg2)
{
	return (arg1 % arg2);
}
int32			int24mod(int32 arg1, int32 arg2)
{
	return (arg1 % arg2);
}
int32			int42mod(int32 arg1, int32 arg2)
{
	return (arg1 % arg2);
}

/*
 *		int[24]fac		- returns arg1!
 */
int32
int4fac(int32 arg1)
{
	int32			result;

	if (arg1 < 1)
		result = 0;
	else
		for (result = 1; arg1 > 0; --arg1)
			result *= arg1;
	return (result);
}

int32
int2fac(int16 arg1)
{
	int16			result;

	if (arg1 < 1)
		result = 0;
	else
		for (result = 1; arg1 > 0; --arg1)
			result *= arg1;
	return (result);
}

int16
int2larger(int16 arg1, int16 arg2)
{
	return ((arg1 > arg2) ? arg1 : arg2);
}

int16
int2smaller(int16 arg1, int16 arg2)
{
	return ((arg1 < arg2) ? arg1 : arg2);
}

int32
int4larger(int32 arg1, int32 arg2)
{
	return ((arg1 > arg2) ? arg1 : arg2);
}

int32
int4smaller(int32 arg1, int32 arg2)
{
	return ((arg1 < arg2) ? arg1 : arg2);
}