irrMath.h File Reference

#include "IrrCompileConfig.h"
#include "irrTypes.h"
#include <math.h>
#include <float.h>
#include <stdlib.h>
#include <limits.h>

Go to the source code of this file.

Classes

• union irr::core::FloatIntUnion32
• union irr::core::inttofloat

Namespaces

• namespace irr

  Everything in the Irrlicht Engine can be found in this namespace.

  
  

• namespace irr::core

  Basic classes such as vectors, planes, arrays, lists, and so on can be found in this namespace.

  
  

Defines

• #define AIR(x)   (IR(x)&0x7fffffff)

  Absolute integer representation of a floating-point value.
  

• #define F32_A_GREATER_B(a, b)   ((a) > (b))
• #define F32_AS_S32(f)   (*((s32 *) &(f)))
• #define F32_AS_U32(f)   (*((u32 *) &(f)))
• #define F32_AS_U32_POINTER(f)   ( ((u32 *) &(f)))
• #define F32_EQUAL_0(n)   ((n) == 0.0f)
• #define F32_EQUAL_1(n)   ((n) == 1.0f)
• #define F32_EXPON_MANTISSA   0x7FFFFFFFU
• #define F32_GREATER_0(n)   ((n) > 0.0f)
• #define F32_GREATER_EQUAL_0(n)   ((n) >= 0.0f)
• #define F32_LOWER_0(n)   ((n) < 0.0f)
• #define F32_LOWER_EQUAL_0(n)   ((n) <= 0.0f)
• #define F32_SIGN_BIT   0x80000000U
• #define F32_VALUE_0   0x00000000
• #define F32_VALUE_1   0x3f800000
• #define FLT_MAX   3.402823466E+38F
• #define FLT_MIN   1.17549435e-38F
• #define IEEE_1_0   0x3f800000

  integer representation of 1.0
  

• #define IEEE_255_0   0x437f0000

  integer representation of 255.0
  

• #define REALINLINE   inline

Functions

• template<class T > T irr::core::abs_ (const T &a)

  returns abs of two values. Own implementation to get rid of STL (VS6 problems)
  

• REALINLINE s32 irr::core::ceil32 (f32 x)
• template<class T > const T irr::core::clamp (const T &value, const T &low, const T &high)

  clamps a value between low and high
  

• REALINLINE void irr::core::clearFPUException ()
• f32 irr::core::degToRad (f32 degrees)

  Utility function to convert a degrees value to radians.
  

• f64 irr::core::degToRad (f64 degrees)

  Utility function to convert a degrees value to radians.
  

• bool irr::core::equals (const f64 a, const f64 b, const f64 tolerance=ROUNDING_ERROR_f64)

  returns if a equals b, taking possible rounding errors into account
  

• bool irr::core::equals (const f32 a, const f32 b, const f32 tolerance=ROUNDING_ERROR_f32)

  returns if a equals b, taking possible rounding errors into account
  

• bool irr::core::equals (const s32 a, const s32 b, const s32 tolerance=ROUNDING_ERROR_S32)

  returns if a equals b, taking an explicit rounding tolerance into account
  

• bool irr::core::equals (const u32 a, const u32 b, const s32 tolerance=ROUNDING_ERROR_S32)

  returns if a equals b, taking an explicit rounding tolerance into account
  

• bool irr::core::equals (const s64 a, const s64 b, const s64 tolerance=ROUNDING_ERROR_S64)

  returns if a equals b, taking an explicit rounding tolerance into account
  

• bool irr::core::equalsByUlp (f32 a, f32 b, int maxUlpDiff)

  We compare the difference in ULP's (spacing between floating-point numbers, aka ULP=1 means there exists no float between).
  

• f32 irr::core::f32_max3 (const f32 a, const f32 b, const f32 c)
• f32 irr::core::f32_min3 (const f32 a, const f32 b, const f32 c)
• REALINLINE s32 irr::core::floor32 (f32 x)
• f32 irr::core::FR (u32 x)

  Floating-point representation of an integer value.
  

• f32 irr::core::FR (s32 x)
• f32 irr::core::fract (f32 x)
• REALINLINE u32 irr::core::if_c_a_else_0 (const s32 condition, const u32 a)

  conditional set based on mask and arithmetic shift
  

• REALINLINE u32 irr::core::if_c_a_else_b (const s32 condition, const u32 a, const u32 b)

  conditional set based on mask and arithmetic shift
  

• REALINLINE u16 irr::core::if_c_a_else_b (const s16 condition, const u16 a, const u16 b)

  conditional set based on mask and arithmetic shift
  

• u32 irr::core::IR (f32 x)
• bool irr::core::isnotzero (const f32 a, const f32 tolerance=ROUNDING_ERROR_f32)

  returns if a equals not zero, taking rounding errors into account
  

• bool irr::core::iszero (const f64 a, const f64 tolerance=ROUNDING_ERROR_f64)

  returns if a equals zero, taking rounding errors into account
  

• bool irr::core::iszero (const f32 a, const f32 tolerance=ROUNDING_ERROR_f32)

  returns if a equals zero, taking rounding errors into account
  

• bool irr::core::iszero (const s32 a, const s32 tolerance=0)

  returns if a equals zero, taking rounding errors into account
  

• bool irr::core::iszero (const u32 a, const u32 tolerance=0)

  returns if a equals zero, taking rounding errors into account
  

• bool irr::core::iszero (const s64 a, const s64 tolerance=0)

  returns if a equals zero, taking rounding errors into account
  

• template<class T > T irr::core::lerp (const T &a, const T &b, const f32 t)
• template<class T > const T & irr::core::max_ (const T &a, const T &b)

  returns maximum of two values. Own implementation to get rid of the STL (VS6 problems)
  

• template<class T > const T & irr::core::max_ (const T &a, const T &b, const T &c)

  returns maximum of three values. Own implementation to get rid of the STL (VS6 problems)
  

• template<class T > const T & irr::core::min_ (const T &a, const T &b)

  returns minimum of two values. Own implementation to get rid of the STL (VS6 problems)
  

• template<class T > const T & irr::core::min_ (const T &a, const T &b, const T &c)

  returns minimum of three values. Own implementation to get rid of the STL (VS6 problems)
  

• f32 irr::core::radToDeg (f32 radians)

  Utility function to convert a radian value to degrees.
  

• f64 irr::core::radToDeg (f64 radians)

  Utility function to convert a radian value to degrees.
  

• REALINLINE f32 irr::core::reciprocal (const f32 f)
• REALINLINE f64 irr::core::reciprocal (const f64 f)
• REALINLINE f32 irr::core::reciprocal_approxim (const f32 f)
• REALINLINE f64 irr::core::reciprocal_squareroot (const f64 x)
• REALINLINE f32 irr::core::reciprocal_squareroot (const f32 f)
• REALINLINE s32 irr::core::reciprocal_squareroot (const s32 x)
• REALINLINE s32 irr::core::round32 (f32 x)
• f32 irr::core::round_ (f32 x)
• s32 irr::core::s32_clamp (s32 value, s32 low, s32 high)
• s32 irr::core::s32_max (s32 a, s32 b)
• s32 irr::core::s32_min (s32 a, s32 b)
• REALINLINE void irr::core::setbit_cond (u32 &state, s32 condition, u32 mask)
• REALINLINE f32 irr::core::squareroot (const f32 f)
• REALINLINE f64 irr::core::squareroot (const f64 f)
• REALINLINE s32 irr::core::squareroot (const s32 f)
• REALINLINE s64 irr::core::squareroot (const s64 f)
• template<class T1 , class T2 > void irr::core::swap (T1 &a, T2 &b)

  swaps the content of the passed parameters
  

Variables

• const f32 irr::core::DEGTORAD = PI / 180.0f

  32bit Constant for converting from degrees to radians
  

• const f64 irr::core::DEGTORAD64 = PI64 / 180.0

  64bit constant for converting from degrees to radians (formally known as GRAD_PI2)
  

• const f32 irr::core::HALF_PI = PI/2.0f

  Constant for half of PI.
  

• const f32 irr::core::PI = 3.14159265359f

  Constant for PI.
  

• const f64 irr::core::PI64 = 3.1415926535897932384626433832795028841971693993751

  Constant for 64bit PI.
  

• const f32 irr::core::RADTODEG = 180.0f / PI

  32bit constant for converting from radians to degrees (formally known as GRAD_PI)
  

• const f64 irr::core::RADTODEG64 = 180.0 / PI64

  64bit constant for converting from radians to degrees
  

• const f32 irr::core::RECIPROCAL_PI = 1.0f/PI

  Constant for reciprocal of PI.
  

• const f64 irr::core::RECIPROCAL_PI64 = 1.0/PI64

  Constant for 64bit reciprocal of PI.
  

• const f32 irr::core::ROUNDING_ERROR_f32 = 0.000001f
• const f64 irr::core::ROUNDING_ERROR_f64 = 0.00000001
• const s32 irr::core::ROUNDING_ERROR_S32 = 0

  Rounding error constant often used when comparing f32 values.
  

• const s64 irr::core::ROUNDING_ERROR_S64 = 0

---

Define Documentation

#define AIR

(

x

)

(IR(x)&0x7fffffff)

Absolute integer representation of a floating-point value.

Definition at line 357 of file irrMath.h.

#define F32_A_GREATER_B	(		a,
			b
	)		((a) > (b))

Definition at line 391 of file irrMath.h.

#define F32_AS_S32

(

f

)

(*((s32 *) &(f)))

Definition at line 339 of file irrMath.h.

#define F32_AS_U32

(

f

)

(*((u32 *) &(f)))

Definition at line 340 of file irrMath.h.

#define F32_AS_U32_POINTER

(

f

)

( ((u32 *) &(f)))

Definition at line 341 of file irrMath.h.

#define F32_EQUAL_0

(

n

)

((n) == 0.0f)

Definition at line 390 of file irrMath.h.

#define F32_EQUAL_1

(

n

)

((n) == 1.0f)

Definition at line 389 of file irrMath.h.

#define F32_EXPON_MANTISSA   0x7FFFFFFFU

Definition at line 346 of file irrMath.h.

#define F32_GREATER_0

(

n

)

((n) > 0.0f)

Definition at line 387 of file irrMath.h.

#define F32_GREATER_EQUAL_0

(

n

)

((n) >= 0.0f)

Definition at line 388 of file irrMath.h.

#define F32_LOWER_0

(

n

)

((n) < 0.0f)

Definition at line 385 of file irrMath.h.

#define F32_LOWER_EQUAL_0

(

n

)

((n) <= 0.0f)

Definition at line 386 of file irrMath.h.

Referenced by irr::core::triangle3d< T >::isFrontFacing(), and irr::core::plane3d< f32 >::isFrontFacing().

#define F32_SIGN_BIT   0x80000000U

Definition at line 345 of file irrMath.h.

#define F32_VALUE_0   0x00000000

Definition at line 343 of file irrMath.h.

#define F32_VALUE_1   0x3f800000

Definition at line 344 of file irrMath.h.

Referenced by irr::core::CMatrix4< T >::isIdentity_integer_base().

#define FLT_MAX   3.402823466E+38F

Definition at line 31 of file irrMath.h.

Referenced by irr::core::strtof10().

#define FLT_MIN   1.17549435e-38F

Definition at line 35 of file irrMath.h.

Referenced by irr::core::CMatrix4< T >::getInverse().

#define IEEE_1_0   0x3f800000

integer representation of 1.0

Definition at line 368 of file irrMath.h.

#define IEEE_255_0   0x437f0000

integer representation of 255.0

Definition at line 370 of file irrMath.h.

#define REALINLINE   inline

Definition at line 399 of file irrMath.h.