include/linux/math.h - pub/scm/linux/kernel/git/hyperv/linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 #ifndef _LINUX_MATH_H
 #define _LINUX_MATH_H

 #include <linux/types.h>
 #include <asm/div64.h>
 #include <uapi/linux/kernel.h>

 /*
  * This looks more complex than it should be. But we need to
  * get the type for the ~ right in round_down (it needs to be
  * as wide as the result!), and we want to evaluate the macro
  * arguments just once each.
  */
 #define __round_mask(x, y) ((__typeof__(x))((y)-1))

 /**
  * round_up - round up to next specified power of 2
  * @x: the value to round
  * @y: multiple to round up to (must be a power of 2)
  *
  * Rounds @x up to next multiple of @y (which must be a power of 2).
  * To perform arbitrary rounding up, use roundup() below.
  */
 #define round_up(x, y) ((((x)-1) | __round_mask(x, y))+1)

 /**
  * round_down - round down to next specified power of 2
  * @x: the value to round
  * @y: multiple to round down to (must be a power of 2)
  *
  * Rounds @x down to next multiple of @y (which must be a power of 2).
  * To perform arbitrary rounding down, use rounddown() below.
  */
 #define round_down(x, y) ((x) & ~__round_mask(x, y))

 #define DIV_ROUND_UP __KERNEL_DIV_ROUND_UP

 #define DIV_ROUND_DOWN_ULL(ll, d) \
 	({ unsigned long long _tmp = (ll); do_div(_tmp, d); _tmp; })

 #define DIV_ROUND_UP_ULL(ll, d) \
 	DIV_ROUND_DOWN_ULL((unsigned long long)(ll) + (d) - 1, (d))

 #if BITS_PER_LONG == 32
 # define DIV_ROUND_UP_SECTOR_T(ll,d) DIV_ROUND_UP_ULL(ll, d)
 #else
 # define DIV_ROUND_UP_SECTOR_T(ll,d) DIV_ROUND_UP(ll,d)
 #endif

 /**
  * roundup - round up to the next specified multiple
  * @x: the value to up
  * @y: multiple to round up to
  *
  * Rounds @x up to next multiple of @y. If @y will always be a power
  * of 2, consider using the faster round_up().
  */
 #define roundup(x, y) (					\
 {							\
 	typeof(y) __y = y;				\
 	(((x) + (__y - 1)) / __y) * __y;		\
 }							\
 )
 /**
  * rounddown - round down to next specified multiple
  * @x: the value to round
  * @y: multiple to round down to
  *
  * Rounds @x down to next multiple of @y. If @y will always be a power
  * of 2, consider using the faster round_down().
  */
 #define rounddown(x, y) (				\
 {							\
 	typeof(x) __x = (x);				\
 	__x - (__x % (y));				\
 }							\
 )

 /*
  * Divide positive or negative dividend by positive or negative divisor
  * and round to closest integer. Result is undefined for negative
  * divisors if the dividend variable type is unsigned and for negative
  * dividends if the divisor variable type is unsigned.
  */
 #define DIV_ROUND_CLOSEST(x, divisor)(			\
 {							\
 	typeof(x) __x = x;				\
 	typeof(divisor) __d = divisor;			\
 	(((typeof(x))-1) > 0 ||				\
 	 ((typeof(divisor))-1) > 0 ||			\
 	 (((__x) > 0) == ((__d) > 0))) ?		\
 		(((__x) + ((__d) / 2)) / (__d)) :	\
 		(((__x) - ((__d) / 2)) / (__d));	\
 }							\
 )
 /*
  * Same as above but for u64 dividends. divisor must be a 32-bit
  * number.
  */
 #define DIV_ROUND_CLOSEST_ULL(x, divisor)(		\
 {							\
 	typeof(divisor) __d = divisor;			\
 	unsigned long long _tmp = (x) + (__d) / 2;	\
 	do_div(_tmp, __d);				\
 	_tmp;						\
 }							\
 )

 #define __STRUCT_FRACT(type)				\
 struct type##_fract {					\
 	__##type numerator;				\
 	__##type denominator;				\
 };
 __STRUCT_FRACT(s16)
 __STRUCT_FRACT(u16)
 __STRUCT_FRACT(s32)
 __STRUCT_FRACT(u32)
 #undef __STRUCT_FRACT

 /* Calculate "x * n / d" without unnecessary overflow or loss of precision. */
 #define mult_frac(x, n, d)	\
 ({				\
 	typeof(x) x_ = (x);	\
 	typeof(n) n_ = (n);	\
 	typeof(d) d_ = (d);	\
 				\
 	typeof(x_) q = x_ / d_;	\
 	typeof(x_) r = x_ % d_;	\
 	q * n_ + r * n_ / d_;	\
 })

 #define sector_div(a, b) do_div(a, b)

 /**
  * abs - return absolute value of an argument
  * @x: the value.  If it is unsigned type, it is converted to signed type first.
  *     char is treated as if it was signed (regardless of whether it really is)
  *     but the macro's return type is preserved as char.
  *
  * Return: an absolute value of x.
  */
 #define abs(x)	__abs_choose_expr(x, long long,				\
 		__abs_choose_expr(x, long,				\
 		__abs_choose_expr(x, int,				\
 		__abs_choose_expr(x, short,				\
 		__abs_choose_expr(x, char,				\
 		__builtin_choose_expr(					\
 			__builtin_types_compatible_p(typeof(x), char),	\
 			(char)({ signed char __x = (x); __x<0?-__x:__x; }), \
 			((void)0)))))))

 #define __abs_choose_expr(x, type, other) __builtin_choose_expr(	\
 	__builtin_types_compatible_p(typeof(x),   signed type) ||	\
 	__builtin_types_compatible_p(typeof(x), unsigned type),		\
 	({ signed type __x = (x); __x < 0 ? -__x : __x; }), other)

 /**
  * abs_diff - return absolute value of the difference between the arguments
  * @a: the first argument
  * @b: the second argument
  *
  * @a and @b have to be of the same type. With this restriction we compare
  * signed to signed and unsigned to unsigned. The result is the subtraction
  * the smaller of the two from the bigger, hence result is always a positive
  * value.
  *
  * Return: an absolute value of the difference between the @a and @b.
  */
 #define abs_diff(a, b) ({			\
 	typeof(a) __a = (a);			\
 	typeof(b) __b = (b);			\
 	(void)(&__a == &__b);			\
 	__a > __b ? (__a - __b) : (__b - __a);	\
 })

 /**
  * reciprocal_scale - "scale" a value into range [0, ep_ro)
  * @val: value
  * @ep_ro: right open interval endpoint
  *
  * Perform a "reciprocal multiplication" in order to "scale" a value into
  * range [0, @ep_ro), where the upper interval endpoint is right-open.
  * This is useful, e.g. for accessing a index of an array containing
  * @ep_ro elements, for example. Think of it as sort of modulus, only that
  * the result isn't that of modulo. ;) Note that if initial input is a
  * small value, then result will return 0.
  *
  * Return: a result based on @val in interval [0, @ep_ro).
  */
 static inline u32 reciprocal_scale(u32 val, u32 ep_ro)
 {
 	return (u32)(((u64) val * ep_ro) >> 32);
 }

 u64 int_pow(u64 base, unsigned int exp);
 unsigned long int_sqrt(unsigned long);

 #if BITS_PER_LONG < 64
 u32 int_sqrt64(u64 x);
 #else
 static inline u32 int_sqrt64(u64 x)
 {
 	return (u32)int_sqrt(x);
 }
 #endif

 #endif	/* _LINUX_MATH_H */
	/* SPDX-License-Identifier: GPL-2.0 */
	#ifndef _LINUX_MATH_H
	#define _LINUX_MATH_H

	#include <linux/types.h>
	#include <asm/div64.h>
	#include <uapi/linux/kernel.h>

	/*
	* This looks more complex than it should be. But we need to
	* get the type for the ~ right in round_down (it needs to be
	* as wide as the result!), and we want to evaluate the macro
	* arguments just once each.
	*/
	#define __round_mask(x, y) ((__typeof__(x))((y)-1))

	/**
	* round_up - round up to next specified power of 2
	* @x: the value to round
	* @y: multiple to round up to (must be a power of 2)
	*
	* Rounds @x up to next multiple of @y (which must be a power of 2).
	* To perform arbitrary rounding up, use roundup() below.
	*/
	#define round_up(x, y) ((((x)-1) \| __round_mask(x, y))+1)

	/**
	* round_down - round down to next specified power of 2
	* @x: the value to round
	* @y: multiple to round down to (must be a power of 2)
	*
	* Rounds @x down to next multiple of @y (which must be a power of 2).
	* To perform arbitrary rounding down, use rounddown() below.
	*/
	#define round_down(x, y) ((x) & ~__round_mask(x, y))

	#define DIV_ROUND_UP __KERNEL_DIV_ROUND_UP

	#define DIV_ROUND_DOWN_ULL(ll, d) \
	({ unsigned long long _tmp = (ll); do_div(_tmp, d); _tmp; })

	#define DIV_ROUND_UP_ULL(ll, d) \
	DIV_ROUND_DOWN_ULL((unsigned long long)(ll) + (d) - 1, (d))

	#if BITS_PER_LONG == 32
	# define DIV_ROUND_UP_SECTOR_T(ll,d) DIV_ROUND_UP_ULL(ll, d)
	#else
	# define DIV_ROUND_UP_SECTOR_T(ll,d) DIV_ROUND_UP(ll,d)
	#endif

	/**
	* roundup - round up to the next specified multiple
	* @x: the value to up
	* @y: multiple to round up to
	*
	* Rounds @x up to next multiple of @y. If @y will always be a power
	* of 2, consider using the faster round_up().
	*/
	#define roundup(x, y) ( \
	{ \
	typeof(y) __y = y; \
	(((x) + (__y - 1)) / __y) * __y; \
	} \
	)
	/**
	* rounddown - round down to next specified multiple
	* @x: the value to round
	* @y: multiple to round down to
	*
	* Rounds @x down to next multiple of @y. If @y will always be a power
	* of 2, consider using the faster round_down().
	*/
	#define rounddown(x, y) ( \
	{ \
	typeof(x) __x = (x); \
	__x - (__x % (y)); \
	} \
	)

	/*
	* Divide positive or negative dividend by positive or negative divisor
	* and round to closest integer. Result is undefined for negative
	* divisors if the dividend variable type is unsigned and for negative
	* dividends if the divisor variable type is unsigned.
	*/
	#define DIV_ROUND_CLOSEST(x, divisor)( \
	{ \
	typeof(x) __x = x; \
	typeof(divisor) __d = divisor; \
	(((typeof(x))-1) > 0 \|\| \
	((typeof(divisor))-1) > 0 \|\| \
	(((__x) > 0) == ((__d) > 0))) ? \
	(((__x) + ((__d) / 2)) / (__d)) : \
	(((__x) - ((__d) / 2)) / (__d)); \
	} \
	)
	/*
	* Same as above but for u64 dividends. divisor must be a 32-bit
	* number.
	*/
	#define DIV_ROUND_CLOSEST_ULL(x, divisor)( \
	{ \
	typeof(divisor) __d = divisor; \
	unsigned long long _tmp = (x) + (__d) / 2; \
	do_div(_tmp, __d); \
	_tmp; \
	} \
	)

	#define __STRUCT_FRACT(type) \
	struct type##_fract { \
	__##type numerator; \
	__##type denominator; \
	};
	__STRUCT_FRACT(s16)
	__STRUCT_FRACT(u16)
	__STRUCT_FRACT(s32)
	__STRUCT_FRACT(u32)
	#undef __STRUCT_FRACT

	/* Calculate "x * n / d" without unnecessary overflow or loss of precision. */
	#define mult_frac(x, n, d) \
	({ \
	typeof(x) x_ = (x); \
	typeof(n) n_ = (n); \
	typeof(d) d_ = (d); \
	\
	typeof(x_) q = x_ / d_; \
	typeof(x_) r = x_ % d_; \
	q * n_ + r * n_ / d_; \
	})

	#define sector_div(a, b) do_div(a, b)

	/**
	* abs - return absolute value of an argument
	* @x: the value. If it is unsigned type, it is converted to signed type first.
	* char is treated as if it was signed (regardless of whether it really is)
	* but the macro's return type is preserved as char.
	*
	* Return: an absolute value of x.
	*/
	#define abs(x) __abs_choose_expr(x, long long, \
	__abs_choose_expr(x, long, \
	__abs_choose_expr(x, int, \
	__abs_choose_expr(x, short, \
	__abs_choose_expr(x, char, \
	__builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(x), char), \
	(char)({ signed char __x = (x); __x<0?-__x:__x; }), \
	((void)0)))))))

	#define __abs_choose_expr(x, type, other) __builtin_choose_expr( \
	__builtin_types_compatible_p(typeof(x), signed type) \|\| \
	__builtin_types_compatible_p(typeof(x), unsigned type), \
	({ signed type __x = (x); __x < 0 ? -__x : __x; }), other)

	/**
	* abs_diff - return absolute value of the difference between the arguments
	* @a: the first argument
	* @b: the second argument
	*
	* @a and @b have to be of the same type. With this restriction we compare
	* signed to signed and unsigned to unsigned. The result is the subtraction
	* the smaller of the two from the bigger, hence result is always a positive
	* value.
	*
	* Return: an absolute value of the difference between the @a and @b.
	*/
	#define abs_diff(a, b) ({ \
	typeof(a) __a = (a); \
	typeof(b) __b = (b); \
	(void)(&__a == &__b); \
	__a > __b ? (__a - __b) : (__b - __a); \
	})

	/**
	* reciprocal_scale - "scale" a value into range [0, ep_ro)
	* @val: value
	* @ep_ro: right open interval endpoint
	*
	* Perform a "reciprocal multiplication" in order to "scale" a value into
	* range [0, @ep_ro), where the upper interval endpoint is right-open.
	* This is useful, e.g. for accessing a index of an array containing
	* @ep_ro elements, for example. Think of it as sort of modulus, only that
	* the result isn't that of modulo. ;) Note that if initial input is a
	* small value, then result will return 0.
	*
	* Return: a result based on @val in interval [0, @ep_ro).
	*/
	static inline u32 reciprocal_scale(u32 val, u32 ep_ro)
	{
	return (u32)(((u64) val * ep_ro) >> 32);
	}

	u64 int_pow(u64 base, unsigned int exp);
	unsigned long int_sqrt(unsigned long);

	#if BITS_PER_LONG < 64
	u32 int_sqrt64(u64 x);
	#else
	static inline u32 int_sqrt64(u64 x)
	{
	return (u32)int_sqrt(x);
	}
	#endif

	#endif /* _LINUX_MATH_H */