Unigine.bvec4 Struct
bvec4 Class
Properties
byte x#
The X component of the vector.
byte y#
The Y component of the vector.
byte z#
The Z component of the vector.
byte w#
The W component of the vector.
byte Minimum#
The Minimum value among all components.
byte Maximum#
The Maximum value among all components.
int Length2#
The Squared length of the vector. This method is much faster than length() — the calculation is basically the same only without the slow Sqrt call. If you are using lengths simply to compare distances, then it is faster to compare squared lengths against the squares of distances as the comparison gives the same result.
int Sum#
The Sum of vector components.
bvec4 ZERO#
The Vector, filled with zeros (0).
bvec4 ONE#
The Vector, filled with ones (1).
byte NUM_ELEMENTS#
The Number of elements in the vector.
Members
ivec4 operator* ( bvec4 v0, ivec2 v1 ) #
Multiplication.Arguments
ivec4 operator* ( bvec4 v0, ivec3 v1 ) #
Multiplication.Arguments
ivec4 operator* ( bvec4 v0, ivec4 v1 ) #
Multiplication.Arguments
ivec4 operator* ( bvec4 v0, int v1 ) #
Multiplication.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator* ( bvec4 v0, bvec4 v1 ) #
Multiplication.Arguments
bvec4 operator* ( bvec4 v0, byte v1 ) #
Multiplication.Arguments
- bvec4 v0 - First value.
- byte v1 - Second value.
ivec4 operator/ ( bvec4 v0, ivec2 v1 ) #
Division.Arguments
ivec4 operator/ ( bvec4 v0, ivec3 v1 ) #
Division.Arguments
ivec4 operator/ ( bvec4 v0, ivec4 v1 ) #
Division.Arguments
ivec4 operator/ ( bvec4 v0, int v1 ) #
Division.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator/ ( bvec4 v0, bvec4 v1 ) #
Division.Arguments
bvec4 operator/ ( bvec4 v0, byte v1 ) #
Division.Arguments
- bvec4 v0 - First value.
- byte v1 - Second value.
ivec4 operator- ( bvec4 v0, ivec2 v1 ) #
Subtraction.Arguments
ivec4 operator- ( bvec4 v0, ivec3 v1 ) #
Subtraction.Arguments
ivec4 operator- ( bvec4 v0, ivec4 v1 ) #
Subtraction.Arguments
ivec4 operator- ( bvec4 v0, int v1 ) #
Subtraction.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator- ( bvec4 v0, bvec4 v1 ) #
Subtraction.Arguments
bvec4 operator- ( bvec4 v0, byte v1 ) #
Subtraction.Arguments
- bvec4 v0 - First value.
- byte v1 - Second value.
ivec4 operator+ ( bvec4 v0, ivec2 v1 ) #
Addition.Arguments
ivec4 operator+ ( bvec4 v0, ivec3 v1 ) #
Addition.Arguments
ivec4 operator+ ( bvec4 v0, ivec4 v1 ) #
Addition.Arguments
ivec4 operator+ ( bvec4 v0, int v1 ) #
Addition.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator+ ( bvec4 v0, bvec4 v1 ) #
Addition.Arguments
bvec4 operator+ ( bvec4 v0, byte v1 ) #
Addition.Arguments
- bvec4 v0 - First value.
- byte v1 - Second value.
ivec4 operator% ( bvec4 v0, ivec2 v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
ivec4 operator% ( bvec4 v0, ivec3 v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
ivec4 operator% ( bvec4 v0, ivec4 v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
ivec4 operator% ( bvec4 v0, int v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator% ( bvec4 v0, bvec4 v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
bvec4 operator% ( bvec4 v0, byte v1 ) #
Modulo, gives the remainder of a division of two specified values.Arguments
- bvec4 v0 - First value.
- byte v1 - Second value.
bvec4 operator>> ( bvec4 v0, int v1 ) #
Bitwise right shift.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator<< ( bvec4 v0, int v1 ) #
Bitwise left shift.Arguments
- bvec4 v0 - First value.
- int v1 - Second value.
bvec4 operator++ ( bvec4 v ) #
Increment.Arguments
- bvec4 v - Value.
bvec4 operator-- ( bvec4 v ) #
Decrement.Arguments
- bvec4 v - Value.
bool operator== ( bvec4 v0, bvec4 v1 ) #
Performs equal comparison.Arguments
bool operator!= ( bvec4 v0, bvec4 v1 ) #
Not equal comparison.Arguments
bool operator> ( bvec4 v0, bvec4 v1 ) #
Greater comparison.Arguments
bool operator< ( bvec4 v0, bvec4 v1 ) #
Greater comparison.Arguments
bool operator>= ( bvec4 v0, bvec4 v1 ) #
Greater than or equal to comparison.Arguments
bool operator<= ( bvec4 v0, bvec4 v1 ) #
Less than or equal to comparison.Arguments
bool operatortrue ( bvec4 v ) #
Returns true if the operand is both, not null and not NaN.Arguments
- bvec4 v - Value.
bool operatorfalse ( bvec4 v ) #
Returns true if the operand is both, null and NaN.Arguments
- bvec4 v - Value.
void Set ( float vx, float vy, float vz, float vw ) #
Sets the value using the specified argument(s).Arguments
- float vx - New float value to be set for the first component.
- float vy - New float value to be set for the second component.
- float vz - New float value to be set for the third component.
- float vw - New float value to be set for the fourth component.
void Set ( float v ) #
Sets the value using the specified argument(s).Arguments
- float v - A float value to be used.
void Set ( float[] v ) #
Sets the value using the specified argument(s).Arguments
- float[] v - Source vector.
void Set ( vec2 v, double vz, float vw ) #
Sets the value using the specified argument(s).Arguments
- vec2 v - Source vector.
- double vz - New double value to be set for the third component.
- float vw - New float value to be set for the fourth component.
void Set ( vec3 v, double vw ) #
Sets the value using the specified argument(s).Arguments
- vec3 v - Source vector.
- double vw - New double value to be set for the fourth component.
void Set ( vec2 v ) #
Sets the value using the specified argument(s).Arguments
- vec2 v - Source vector.
void Set ( vec3 v ) #
Sets the value using the specified argument(s).Arguments
- vec3 v - Source vector.
void Set ( vec4 v ) #
Sets the value using the specified argument(s).Arguments
- vec4 v - Source vector.
void Set ( vec4 v, float scale ) #
Sets the value using the specified argument(s).Arguments
- vec4 v - Source vector.
- float scale - Scaling vector (scale.x, scale.y, scale.z).
void Set ( double vx, double vy, double vz, double vw ) #
Sets the value using the specified argument(s).Arguments
- double vx - New double value to be set for the first component.
- double vy - New double value to be set for the second component.
- double vz - New double value to be set for the third component.
- double vw - New double value to be set for the fourth component.
void Set ( double v ) #
Sets the value using the specified argument(s).Arguments
- double v - A double value to be used.
void Set ( double[] v ) #
Sets the value using the specified argument(s).Arguments
- double[] v - Source vector.
void Set ( dvec2 v, double vz, float vw ) #
Sets the value using the specified argument(s).Arguments
- dvec2 v - Source vector.
- double vz - New double value to be set for the third component.
- float vw - New float value to be set for the fourth component.
void Set ( dvec3 v, double vw ) #
Sets the value using the specified argument(s).Arguments
- dvec3 v - Source vector.
- double vw - New double value to be set for the fourth component.
void Set ( dvec2 v ) #
Sets the value using the specified argument(s).Arguments
- dvec2 v - Source vector.
void Set ( dvec3 v ) #
Sets the value using the specified argument(s).Arguments
- dvec3 v - Source vector.
void Set ( dvec4 v ) #
Sets the value using the specified argument(s).Arguments
- dvec4 v - Source vector.
void Set ( int vx, int vy, int vz, int vw ) #
Sets the value using the specified argument(s).Arguments
- int vx - New int value to be set for the first component.
- int vy - New int value to be set for the second component.
- int vz - New int value to be set for the third component.
- int vw - New int value to be set for the fourth component.
void Set ( int v ) #
Sets the value using the specified argument(s).Arguments
- int v - A int value to be used.
void Set ( int[] v ) #
Sets the value using the specified argument(s).Arguments
- int[] v - Source vector.
void Set ( ivec2 v, double vz, float vw ) #
Sets the value using the specified argument(s).Arguments
- ivec2 v - Source vector.
- double vz - New double value to be set for the third component.
- float vw - New float value to be set for the fourth component.
void Set ( ivec3 v, double vw ) #
Sets the value using the specified argument(s).Arguments
- ivec3 v - Source vector.
- double vw - New double value to be set for the fourth component.
void Set ( ivec2 v ) #
Sets the value using the specified argument(s).Arguments
- ivec2 v - Source vector.
void Set ( ivec3 v ) #
Sets the value using the specified argument(s).Arguments
- ivec3 v - Source vector.
void Set ( ivec4 v ) #
Sets the value using the specified argument(s).Arguments
- ivec4 v - Source vector.
void Set ( byte vx, byte vy, byte vz, byte vw ) #
Sets the value using the specified argument(s).Arguments
- byte vx - New byte value to be set for the first component.
- byte vy - New byte value to be set for the second component.
- byte vz - New byte value to be set for the third component.
- byte vw - New byte value to be set for the fourth component.
void Set ( byte v ) #
Sets the value using the specified argument(s).Arguments
- byte v - A byte value to be used.
void Set ( byte[] v ) #
Sets the value using the specified argument(s).Arguments
- byte[] v - Source vector.
void Set ( bvec4 v ) #
Sets the value using the specified argument(s).Arguments
- bvec4 v - Source vector.
void Clear ( ) #
Clears the value by setting all components/elements to 0.void Add ( bvec4 v ) #
Performs addition of the specified argument.Arguments
- bvec4 v - Value.
void Add ( byte v ) #
Performs addition of the specified argument.Arguments
- byte v - Value.
void Sub ( bvec4 v ) #
Subtracts each element of the specified argument from ther corresponding element.Arguments
- bvec4 v - Value.
void Sub ( byte v ) #
Subtracts each element of the specified argument from ther corresponding element.Arguments
- byte v - Value.
void Mul ( bvec4 v ) #
Multiplies the vector by the value of the specified argument.Arguments
- bvec4 v - Vector multiplier.
void Mul ( byte v ) #
Multiplies the vector by the value of the specified argument.Arguments
- byte v - A byte multiplier.
void Div ( bvec4 v ) #
Returns the result of division of the vector by the value of the specified arguments.Arguments
- bvec4 v - A bvec4 divisor value.
void Div ( byte v ) #
Returns the result of division of the vector by the value of the specified arguments.Arguments
- byte v - A byte divisor value.
bool Equals ( bvec4 other ) #
Checks if the vector and the specified argument are equal (epsilon).Arguments
- bvec4 other - Value to be checked for equality.
Return value
Return value.bool Equals ( object obj ) #
Checks if the vector and the specified argument are equal (epsilon).Arguments
- object obj
Return value
Return value.int GetHashCode ( ) #
Returns a hash code for the current object. Serves as the default hash function.Return value
Resulting int value.string ToString ( ) #
Converts the current value to a string value.Return value
Resulting string value.string ToString ( string format ) #
Converts the current value to a string value.Arguments
- string format - String formatting to be used. A format string is composed of zero or more ordinary characters (excluding %) that are copied directly to the result string and control sequences, each of which results in fetching its own parameter. Each control sequence consists of a percent sign (%) followed by one or more of these elements, in order:
- An optional number, a width specifier, that says how many characters (minimum) this conversion should result in.
- An optional precision specifier that says how many decimal digits should be displayed for floating-point numbers.
- A type specifier that says what type the argument data should be treated as. Possible types:
- c: the argument is treated as an integer and presented as a character with that ASCII value.
- d or i: the argument is treated as an integer and presented as a (signed) decimal number.
- o: the argument is treated as an integer and presented as an octal number.
- u: the argument is treated as an integer and presented as an unsigned decimal number.
- x: the argument is treated as an integer and presented as a hexadecimal number (with lower-case letters).
- X: the argument is treated as an integer and presented as a hexadecimal number (with upper-case letters).
- f: the argument is treated as a float and presented as a floating-point number.
- g: the same as e or f, the shortest one is selected.
- G: the same as E or F, the shortest one is selected.
- e: the argument is treated as using the scientific notation with lower-case 'e' (e.g. 1.2e+2).
- E: the argument is treated as using the scientific notation with upper-case 'E' (e.g. 1.2E+2).
- s: the argument is treated as and presented as a string.
- p: the argument is treated as and presented as a pointer address.
- %: a literal percent character. No argument is required.
Return value
Resulting string value.string ToString ( string format, IFormatProvider formatProvider ) #
Converts the current value to a string value.Arguments
- string format - String formatting to be used. A format string is composed of zero or more ordinary characters (excluding %) that are copied directly to the result string and control sequences, each of which results in fetching its own parameter. Each control sequence consists of a percent sign (%) followed by one or more of these elements, in order:
- An optional number, a width specifier, that says how many characters (minimum) this conversion should result in.
- An optional precision specifier that says how many decimal digits should be displayed for floating-point numbers.
- A type specifier that says what type the argument data should be treated as. Possible types:
- c: the argument is treated as an integer and presented as a character with that ASCII value.
- d or i: the argument is treated as an integer and presented as a (signed) decimal number.
- o: the argument is treated as an integer and presented as an octal number.
- u: the argument is treated as an integer and presented as an unsigned decimal number.
- x: the argument is treated as an integer and presented as a hexadecimal number (with lower-case letters).
- X: the argument is treated as an integer and presented as a hexadecimal number (with upper-case letters).
- f: the argument is treated as a float and presented as a floating-point number.
- g: the same as e or f, the shortest one is selected.
- G: the same as E or F, the shortest one is selected.
- e: the argument is treated as using the scientific notation with lower-case 'e' (e.g. 1.2e+2).
- E: the argument is treated as using the scientific notation with upper-case 'E' (e.g. 1.2E+2).
- s: the argument is treated as and presented as a string.
- p: the argument is treated as and presented as a pointer address.
- %: a literal percent character. No argument is required.
- IFormatProvider formatProvider - Provider to be used to format the value. Pass a null reference to obtain the numeric format information from the current locale setting of the operating system.
Return value
Resulting string value.IEnumerator<byte> GetEnumerator ( ) #
Returns an IEnumerator for the object.Return value
Return value.IEnumerator GetEnumerator ( ) #
Returns an IEnumerator for the object.Return value
Return value.Last update:
10.10.2022
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