/*
 	File:		Math64.h
 
 	Contains:	64-bit integer math Interfaces.
 
 	Version:	Technology:	System 7.5
 				Release:	QuickTime 4.0
 
 	Copyright:	(c) 1994-1998 by Apple Computer, Inc., all rights reserved
 
 	Bugs?:		For bug reports, consult the following page on
 				the World Wide Web:
 
 					http://developer.apple.com/bugreporter/
 
*/
#ifndef __MATH64__
#define __MATH64__

#ifndef __CONDITIONALMACROS__
#include <ConditionalMacros.h>
#endif
#ifndef __MACTYPES__
#include <MacTypes.h>
#endif



#if PRAGMA_ONCE
#pragma once
#endif

#ifdef __cplusplus
extern "C" {
#endif

#if PRAGMA_IMPORT
#pragma import on
#endif

#if PRAGMA_STRUCT_ALIGN
	#pragma options align=mac68k
#elif PRAGMA_STRUCT_PACKPUSH
	#pragma pack(push, 2)
#elif PRAGMA_STRUCT_PACK
	#pragma pack(2)
#endif


/*--------------------------------------------------------------------------------
				These routines are intended to provide C software support for
				64 bit integer types.  Their behavior should mimic anticipated
				64 bit hardware. This implementation should replace use of the
				"wide" type found in PowerPC.

	The following routines are available for performing math on 64-bit integers:
	
	S64Max
				Returns the largest representable SInt64.
	S64Min
				Returns the smallest (i.e. most negative) SInt64.  Note: the negative
				(absolute value) of this number is not representable in an SInt64.
				That means that S64Negate(S64Min) is not representable (in fact,
				it returns S64Min).
	S64Add
				Adds two integers, producing an integer result.  If an overflow
				occurs the result is congruent mod (2^64) as if the operands and
				result were unsigned.  No overflow is signaled.
	
	S64Subtract
				Subtracts two integers, producing an integer result.  If an overflow
				occurs the result is congruent mod (2^64) as if the operands and
				result were unsigned.  No overflow is signaled.

	S64Negate
				Returns the additive inverse of a signed number (i.e. it returns
				0 - the number).  S64Negate (S64Min) is not representable (in fact,
				it returns S64Min).
	
	S64Absolute
				Returns the absolute value of the number (i.e. the number if
				it is positive, or 0 - the number if it is negative).
				See S64Negate above.
				
	S64Multiply
				Multiplies two signed numbers, producing a signed result.  Overflow
				is ignored and the low-order part of the product is returned.  The
				sign of the result is not guaranteed to be correct if the magnitude
				of the product is not representable.
				
	S64Div
				Divides dividend by divisor, returning the quotient.  

	S64Divide
				Divides dividend by divisor, returning the quotient.  The remainder
				is returned in *remainder if remainder (the pointer) is non-NULL.
				The sign of the remainder is the same as the sign of the dividend
				(i.e. it takes the absolute values of the operands, does the division,
				then fixes the sign of the quotient and remainder).  If the divisor
				is zero, then S64Max() will be returned (or S64Min() if the dividend
				is negative), and the remainder will be the dividend; no error is
				reported.
	
	S64Set
				Given an SInt32, returns an SInt64 with the same value.  Use this
				routine instead of coding 64-bit constants (at least when the
				constant will fit in an SInt32).
	
	S64SetU
				Given a UInt32, returns a SInt64 with the same value.
	
	S64Compare
				Given two signed numbers, left and right, returns an
				SInt32 that compares with zero the same way left compares with
				right.  If you wanted to perform a comparison on 64-bit integers
				of the form:
						operand_1 <operation> operand_2
				then you could use an expression of the form:
						xxxS64Compare(operand_1,operand_2) <operation> 0
				to test for the same condition.
				
				CAUTION: DO NOT depend on the exact value returned by this routine.
				Only the sign (i.e. positive, zero, or negative) of the result is
				guaranteed.

	S64And, S64Or, S64Eor and S64Not
	
				Return Boolean (1 or 0) depending on the outcome of the logical
				operation.

	S64BitwiseAnd, S64BitwiseOr, S64BitwiseEor and S64BitwiseNot
	
				Return the Bitwise result.
				
	S64ShiftRight and S64ShiftLeft
	
				The lower 7 bits of the shift argument determines the amount of 
				shifting.  S64ShiftRight is an arithmetic shift while U64ShiftRight
				is a logical shift.

	SInt64ToLongDouble
				
				Converts SInt64 to long double.  Note all SInt64s fit exactly into 
				long doubles, thus, the binary -> decimal conversion routines
				in fp.h can be used to achieve SInt64 -> long double -> decimal
				conversions.
				
	LongDoubleToSInt64
	
				Converts a long double to a SInt64.  Any decimal string that fits
				into a SInt64 can be converted exactly into a long double, using the
				conversion routines found in fp.h.  Then this routine can be used
				to complete the conversion to SInt64.
				
	SInt64ToWide
	
				Converts a SInt64 to a wide struct.  If SInt64 is implemented
				as a typedef of wide, the marco does nothing. If SInt64 is 
				implememnted as a long long, it casts the long long into a 
				wide struct.
	
	WideToSInt64
	
				Converts a wide struct into a SInt64.  If SInt64 is implemented
				as a typedef of wide, the marco does nothing. If SInt64 is 
				implememnted as a long long, it reads the struct into a long long.
	
	
	The corresponding UInt64 routines are also included.
	
--------------------------------------------------------------------------------*/


#if TYPE_LONGLONG 

#define S64Max() 9223372036854775807
#define S64Min() (-S64Max() - 1)
#define S64Add(x, y) ((x) + (y))
#define S64Subtract(x, y) ((x) - (y))
#define S64Negate(x) (-(x))
#define S64Absolute(x) absll((x))
#define S64Multiply(x, y) ((x) * (y))
#define S64Div(x, y) ((x) / (y))
#define S64Mod(x, y) ((x) % (y))
#define S64Set(x) ((SInt64) (x))
#define S64SetU(x) ((SInt64) (x))
#define S32Set(x) ((SInt32) (x))
#define S64Compare(x, y) ((int)((x) - (y)))
#define S64And(x, y) ((Boolean)((x) && (y)))
#define S64Or(x, y) ((Boolean)((x) || (y)))
#define S64Eor(x, y) ((Boolean)((x) ^ (y)))
#define S64Not(x) ((Boolean)(!(x)))
#define S64BitwiseAnd(x, y) ((x) & (y))
#define S64BitwiseOr(x, y) ((x) | (y))
#define S64BitwiseEor(x, y) (((x) & (~(y))) | ((~(x)) & (y)))
#define S64BitwiseNot(x) (~(x))
#define S64ShiftRight(x, y) ((x) >> (y))
#define S64ShiftLeft(x, y) ((x) << (y))
#define SInt64ToLongDouble(x) ((long double)(x))
#define LongDoubleToSInt64(x) ((SInt64)(x))

#define U64Max() 0xffffffffffffffff
#define U64Add(x, y) ((x) + (y))
#define U64Subtract(x, y) ((x) - (y))
#define U64Multiply(x, y) ((x) * (y))
#define U64Div(x, y) ((x) / (y))
#define U64Mod(x, y) ((x) % (y))
#define U64Set(x) ((UInt64) (x))
#define U64SetU(x) ((UInt64) (x))
#define U32SetU(x) ((UInt32) (x))
#define U64Compare(x, y) ((int)((x) - (y)))
#define U64And(x, y) ((Boolean)((x) && (y)))
#define U64Or(x, y) ((Boolean)((x) || (y)))
#define U64Eor(x, y) ((Boolean)((x) ^ (y)))
#define U64Not(x) ((Boolean)(!(x)))
#define U64BitwiseAnd(x, y) ((x) & (y))
#define U64BitwiseOr(x, y) ((x) | (y))
#define U64BitwiseEor(x, y) (((x) & (~(y))) | ((~(x)) & (y)))
#define U64BitwiseNot(x) (~(x))
#define U64ShiftRight(x, y) ((x) >> (y))
#define U64ShiftLeft(x, y) ((x) << (y))
#define UInt64ToLongDouble(x) ((long double)(x))
#define LongDoubleToUInt64(x) ((UInt64)(x))
#define UInt64ToSInt64(x) ((SInt64)(x))
#define SInt64ToUInt64(x) ((UInt64)(x))

#else  

EXTERN_API_C( SInt64 ) S64Max(void );

EXTERN_API_C( SInt64 ) S64Min(void );

EXTERN_API_C( SInt64 ) S64Add(SInt64 x, SInt64 y);

EXTERN_API_C( SInt64 ) S64Subtract(SInt64 left, SInt64 right);

EXTERN_API_C( SInt64 ) S64Negate(SInt64 value);

EXTERN_API_C( SInt64 ) S64Absolute(SInt64 value);

EXTERN_API_C( SInt64 ) S64Multiply(SInt64 xparam, SInt64 yparam);

#define S64Div(dividend, divisor) S64Divide(dividend, divisor, NULL)

EXTERN_API_C( SInt64 ) S64Divide(SInt64 dividend, SInt64 divisor, SInt64 *remainder);

EXTERN_API_C( SInt64 ) S64Set(SInt32 value);

EXTERN_API_C( SInt64 ) S64SetU(UInt32 value);

EXTERN_API_C( SInt32 ) S32Set(SInt64 value);

EXTERN_API_C( int ) S64Compare(SInt64 left, SInt64 right);

EXTERN_API_C( Boolean ) S64And(SInt64 left, SInt64 right);

EXTERN_API_C( Boolean ) S64Or(SInt64 left, SInt64 right);

EXTERN_API_C( Boolean ) S64Eor(SInt64 left, SInt64 right);

EXTERN_API_C( Boolean ) S64Not(SInt64 value);

EXTERN_API_C( SInt64 ) S64BitwiseAnd(SInt64 left, SInt64 right);

EXTERN_API_C( SInt64 ) S64BitwiseOr(SInt64 left, SInt64 right);

EXTERN_API_C( SInt64 ) S64BitwiseEor(SInt64 left, SInt64 right);

EXTERN_API_C( SInt64 ) S64BitwiseNot(SInt64 value);

EXTERN_API_C( SInt64 ) S64ShiftRight(SInt64 value, UInt32 shift);

EXTERN_API_C( SInt64 ) S64ShiftLeft(SInt64 value, UInt32 shift);

/*
	"long double" means 128 bit type on PowerPC and 80-bit type on 68K
*/
EXTERN_API_C( long double ) SInt64ToLongDouble(SInt64 value);

EXTERN_API_C( SInt64 ) LongDoubleToSInt64(long double value);

EXTERN_API_C( UInt64 ) U64Max(void );

EXTERN_API_C( UInt64 ) U64Add(UInt64 x, UInt64 y);

EXTERN_API_C( UInt64 ) U64Subtract(UInt64 left, UInt64 right);

EXTERN_API_C( UInt64 ) U64Multiply(UInt64 xparam, UInt64 yparam);

#define U64Div(dividend, divisor) U64Divide(dividend, divisor, NULL)

EXTERN_API_C( UInt64 ) U64Divide(UInt64 dividend, UInt64 divisor, UInt64 *remainder);

EXTERN_API_C( UInt64 ) U64Set(SInt32 value);

EXTERN_API_C( UInt64 ) U64SetU(UInt32 value);

EXTERN_API_C( UInt32 ) U32SetU(UInt64 value);

EXTERN_API_C( int ) U64Compare(UInt64 left, UInt64 right);

EXTERN_API_C( Boolean ) U64And(UInt64 left, UInt64 right);

EXTERN_API_C( Boolean ) U64Or(UInt64 left, UInt64 right);

EXTERN_API_C( Boolean ) U64Eor(UInt64 left, UInt64 right);

EXTERN_API_C( Boolean ) U64Not(UInt64 value);

EXTERN_API_C( UInt64 ) U64BitwiseAnd(UInt64 left, UInt64 right);

EXTERN_API_C( UInt64 ) U64BitwiseOr(UInt64 left, UInt64 right);

EXTERN_API_C( UInt64 ) U64BitwiseEor(UInt64 left, UInt64 right);

EXTERN_API_C( UInt64 ) U64BitwiseNot(UInt64 value);

EXTERN_API_C( UInt64 ) U64ShiftRight(UInt64 value, UInt32 shift);

EXTERN_API_C( UInt64 ) U64ShiftLeft(UInt64 value, UInt32 shift);

/*
	"long double" means 128 bit type on PowerPC and 80-bit type on 68K
*/
EXTERN_API_C( long double ) UInt64ToLongDouble(UInt64 value);

EXTERN_API_C( UInt64 ) LongDoubleToUInt64(long double value);

EXTERN_API_C( SInt64 ) UInt64ToSInt64(UInt64 value);

EXTERN_API_C( UInt64 ) SInt64ToUInt64(SInt64 value);

#endif /* TYPE_LONGLONG */

/* 
	Functions to convert between [Unsigned]Wide and [S|U]Int64 types.
	
	These functions are necessary if source code which uses both
	wide and SInt64 is to compile under a compiler that supports
	long long.
*/
#if TYPE_LONGLONG 
	#define SInt64ToWide(x) 		(*((wide*)(&x)))
	#define WideToSInt64(x) 		(*((SInt64*)(&x)))
	#define UInt64ToUnsignedWide(x) (*((UnsignedWide*)(&x)))
	#define UnsignedWideToUInt64(x) (*((UInt64*)(&x)))
#else
	#define SInt64ToWide(x) 		(x)
	#define WideToSInt64(x) 		(x)
	#define UInt64ToUnsignedWide(x) (x)
	#define UnsignedWideToUInt64(x) (x)
#endif




#if PRAGMA_STRUCT_ALIGN
	#pragma options align=reset
#elif PRAGMA_STRUCT_PACKPUSH
	#pragma pack(pop)
#elif PRAGMA_STRUCT_PACK
	#pragma pack()
#endif

#ifdef PRAGMA_IMPORT_OFF
#pragma import off
#elif PRAGMA_IMPORT
#pragma import reset
#endif

#ifdef __cplusplus
}
#endif

#endif /* __MATH64__ */