---@meta --- ---The `lovr.math` module provides math helpers commonly used for 3D applications. --- ---@class lovr.math lovr.math = {} --- ---Drains the temporary vector pool, invalidating existing temporary vectors. --- ---This is called automatically at the end of each frame. --- function lovr.math.drain() end --- ---Converts a color from gamma space to linear space. --- ---@overload fun(color: table):number, number, number ---@overload fun(x: number):number ---@param gr number # The red component of the gamma-space color. ---@param gg number # The green component of the gamma-space color. ---@param gb number # The blue component of the gamma-space color. ---@return number lr # The red component of the resulting linear-space color. ---@return number lg # The green component of the resulting linear-space color. ---@return number lb # The blue component of the resulting linear-space color. function lovr.math.gammaToLinear(gr, gg, gb) end --- ---Get the seed used to initialize the random generator. --- ---@return number seed # The new seed. function lovr.math.getRandomSeed() end --- ---Converts a color from linear space to gamma space. --- ---@overload fun(color: table):number, number, number ---@overload fun(x: number):number ---@param lr number # The red component of the linear-space color. ---@param lg number # The green component of the linear-space color. ---@param lb number # The blue component of the linear-space color. ---@return number gr # The red component of the resulting gamma-space color. ---@return number gg # The green component of the resulting gamma-space color. ---@return number gb # The blue component of the resulting gamma-space color. function lovr.math.linearToGamma(lr, lg, lb) end --- ---Creates a temporary 4D matrix. --- ---This function takes the same arguments as `Mat4:set`. --- function lovr.math.mat4() end --- ---Creates a new `Curve` from a list of control points. --- ---@overload fun(points: table):lovr.Curve ---@overload fun(n: number):lovr.Curve ---@param x number # The x coordinate of the first control point. ---@param y number # The y coordinate of the first control point. ---@param z number # The z coordinate of the first control point. ---@return lovr.Curve curve # The new Curve. function lovr.math.newCurve(x, y, z) end --- ---Creates a new 4D matrix. --- ---This function takes the same arguments as `Mat4:set`. --- function lovr.math.newMat4() end --- ---Creates a new quaternion. --- ---This function takes the same arguments as `Quat:set`. --- function lovr.math.newQuat() end --- ---Creates a new `RandomGenerator`, which can be used to generate random numbers. If you just want some random numbers, you can use `lovr.math.random`. Individual RandomGenerator objects are useful if you need more control over the random sequence used or need a random generator isolated from other instances. --- ---@overload fun(seed: number):lovr.RandomGenerator ---@overload fun(low: number, high: number):lovr.RandomGenerator ---@return lovr.RandomGenerator randomGenerator # The new RandomGenerator. function lovr.math.newRandomGenerator() end --- ---Creates a new 2D vector. --- ---This function takes the same arguments as `Vec2:set`. --- function lovr.math.newVec2() end --- ---Creates a new 3D vector. --- ---This function takes the same arguments as `Vec3:set`. --- function lovr.math.newVec3() end --- ---Creates a new 4D vector. --- ---This function takes the same arguments as `Vec4:set`. --- function lovr.math.newVec4() end --- ---Returns a 1D, 2D, 3D, or 4D perlin noise value. --- ---The number will be between 0 and 1, and it will always be 0.5 when the inputs are integers. --- ---@overload fun(x: number, y: number):number ---@overload fun(x: number, y: number, z: number):number ---@overload fun(x: number, y: number, z: number, w: number):number ---@param x number # The x coordinate of the input. ---@return number noise # The noise value, between 0 and 1. function lovr.math.noise(x) end --- ---Creates a temporary quaternion. --- ---This function takes the same arguments as `Quat:set`. --- function lovr.math.quat() end --- ---Returns a uniformly distributed pseudo-random number. --- ---This function has improved randomness over Lua's `math.random` and also guarantees that the sequence of random numbers will be the same on all platforms (given the same seed). --- --- ---### NOTE: ---You can set the random seed using `lovr.math.setRandomSeed`. --- ---@overload fun(high: number):number ---@overload fun(low: number, high: number):number ---@return number x # A pseudo-random number. function lovr.math.random() end --- ---Returns a pseudo-random number from a normal distribution (a bell curve). --- ---You can control the center of the bell curve (the mean value) and the overall width (sigma, or standard deviation). --- ---@param sigma? number # The standard deviation of the distribution. This can be thought of how "wide" the range of numbers is or how much variability there is. ---@param mu? number # The average value returned. ---@return number x # A normally distributed pseudo-random number. function lovr.math.randomNormal(sigma, mu) end --- ---Seed the random generator with a new seed. --- ---Each seed will cause `lovr.math.random` and `lovr.math.randomNormal` to produce a unique sequence of random numbers. --- ---This is done once automatically at startup by `lovr.run`. --- ---@param seed number # The new seed. function lovr.math.setRandomSeed(seed) end --- ---Creates a temporary 2D vector. --- ---This function takes the same arguments as `Vec2:set`. --- function lovr.math.vec2() end --- ---Creates a temporary 3D vector. --- ---This function takes the same arguments as `Vec3:set`. --- function lovr.math.vec3() end --- ---Creates a temporary 4D vector. --- ---This function takes the same arguments as `Vec4:set`. --- function lovr.math.vec4() end --- ---A Curve is an object that represents a Bézier curve in three dimensions. --- ---Curves are defined by an arbitrary number of control points (note that the curve only passes through the first and last control point). --- ---Once a Curve is created with `lovr.math.newCurve`, you can use `Curve:evaluate` to get a point on the curve or `Curve:render` to get a list of all of the points on the curve. --- ---These points can be passed directly to `lovr.graphics.points` or `lovr.graphics.line` to render the curve. --- ---Note that for longer or more complicated curves (like in a drawing application) it can be easier to store the path as several Curve objects. --- ---@class lovr.Curve local Curve = {} --- ---Inserts a new control point into the Curve at the specified index. --- --- ---### NOTE: ---An error will be thrown if the index is less than one or more than the number of control points. --- ---@param x number # The x coordinate of the control point. ---@param y number # The y coordinate of the control point. ---@param z number # The z coordinate of the control point. ---@param index? number # The index to insert the control point at. If nil, the control point is added to the end of the list of control points. function Curve:addPoint(x, y, z, index) end --- ---Returns a point on the Curve given a parameter `t` from 0 to 1. --- ---0 will return the first control point, 1 will return the last point, .5 will return a point in the "middle" of the Curve, etc. --- --- ---### NOTE: ---An error will be thrown if `t` is not between 0 and 1, or if the Curve has less than two points. --- ---@param t number # The parameter to evaluate the Curve at. ---@return number x # The x position of the point. ---@return number y # The y position of the point. ---@return number z # The z position of the point. function Curve:evaluate(t) end --- ---Returns a control point of the Curve. --- --- ---### NOTE: ---An error will be thrown if the index is less than one or more than the number of control points. --- ---@param index number # The index to retrieve. ---@return number x # The x coordinate of the control point. ---@return number y # The y coordinate of the control point. ---@return number z # The z coordinate of the control point. function Curve:getPoint(index) end --- ---Returns the number of control points in the Curve. --- ---@return number count # The number of control points. function Curve:getPointCount() end --- ---Returns a direction vector for the Curve given a parameter `t` from 0 to 1. --- ---0 will return the direction at the first control point, 1 will return the direction at the last point, .5 will return the direction at the "middle" of the Curve, etc. --- --- ---### NOTE: ---The direction vector returned by this function will have a length of one. --- ---@param t number # Where on the Curve to compute the direction. ---@return number x # The x position of the point. ---@return number y # The y position of the point. ---@return number z # The z position of the point. function Curve:getTangent(t) end --- ---Removes a control point from the Curve. --- --- ---### NOTE: ---An error will be thrown if the index is less than one or more than the number of control points. --- ---@param index number # The index of the control point to remove. function Curve:removePoint(index) end --- ---Returns a list of points on the Curve. --- ---The number of points can be specified to get a more or less detailed representation, and it is also possible to render a subsection of the Curve. --- --- ---### NOTE: ---This function will always return 2 points if the Curve is a line with only 2 control points. --- ---@param n? number # The number of points to use. ---@param t1? number # How far along the curve to start rendering. ---@param t2? number # How far along the curve to stop rendering. ---@return table t # A (flat) table of 3D points along the curve. function Curve:render(n, t1, t2) end --- ---Changes the position of a control point on the Curve. --- --- ---### NOTE: ---An error will be thrown if the index is less than one or more than the number of control points. --- ---@param index number # The index to modify. ---@param x number # The new x coordinate. ---@param y number # The new y coordinate. ---@param z number # The new z coordinate. function Curve:setPoint(index, x, y, z) end --- ---Returns a new Curve created by slicing the Curve at the specified start and end points. --- --- ---### NOTE: ---The new Curve will have the same number of control points as the existing curve. --- ---An error will be thrown if t1 or t2 are not between 0 and 1, or if the Curve has less than two points. --- ---@param t1 number # The starting point to slice at. ---@param t2 number # The ending point to slice at. ---@return lovr.Curve curve # A new Curve. function Curve:slice(t1, t2) end --- ---A `mat4` is a math type that holds 16 values in a 4x4 grid. --- ---@class lovr.Mat4 local Mat4 = {} --- ---Sets a projection matrix using raw projection angles and clipping planes. --- ---This can be used for asymmetric or oblique projections. --- ---@param left number # The left half-angle of the projection, in radians. ---@param right number # The right half-angle of the projection, in radians. ---@param up number # The top half-angle of the projection, in radians. ---@param down number # The bottom half-angle of the projection, in radians. ---@param near number # The near plane of the projection. ---@param far number # The far plane of the projection. ---@return lovr.Mat4 m # The original matrix. function Mat4:fov(left, right, up, down, near, far) end --- ---Resets the matrix to the identity, effectively setting its translation to zero, its scale to 1, and clearing any rotation. --- ---@return lovr.Mat4 m # The original matrix. function Mat4:identity() end --- ---Inverts the matrix, causing it to represent the opposite of its old transform. --- ---@return lovr.Mat4 m # The original matrix. function Mat4:invert() end --- ---Sets a view transform matrix that moves and orients camera to look at a target point. --- ---This is useful for changing camera position and orientation. The resulting Mat4 matrix can be passed to `lovr.graphics.transform()` directly (without inverting) before rendering the scene. --- ---The lookAt() function produces same result as target() after matrix inversion. --- ---@param from lovr.Vec3 # The position of the viewer. ---@param to lovr.Vec3 # The position of the target. ---@param up? lovr.Vec3 # The up vector of the viewer. ---@return lovr.Mat4 m # The original matrix. function Mat4:lookAt(from, to, up) end --- ---Multiplies this matrix by another value. --- ---Multiplying by a matrix combines their two transforms together. --- ---Multiplying by a vector applies the transformation from the matrix to the vector and returns the vector. --- --- ---### NOTE: ---When multiplying by a vec4, the vector is treated as either a point if its w component is 1, or a direction vector if the w is 0 (the matrix translation won't be applied). --- ---@overload fun(self: lovr.Mat4, v3: lovr.Vec3):lovr.Vec3 ---@overload fun(self: lovr.Mat4, v4: lovr.Vec4):lovr.Vec4 ---@param n lovr.Mat4 # The matrix. ---@return lovr.Mat4 m # The original matrix, containing the result. function Mat4:mul(n) end --- ---Sets this matrix to represent an orthographic projection, useful for 2D/isometric rendering. --- ---This can be used with `lovr.graphics.setProjection`, or it can be sent to a `Shader` for use in GLSL. --- ---@param left number # The left edge of the projection. ---@param right number # The right edge of the projection. ---@param top number # The top edge of the projection. ---@param bottom number # The bottom edge of the projection. ---@param near number # The position of the near clipping plane. ---@param far number # The position of the far clipping plane. ---@return lovr.Mat4 m # The original matrix. function Mat4:orthographic(left, right, top, bottom, near, far) end --- ---Sets this matrix to represent a perspective projection. --- ---This can be used with `lovr.graphics.setProjection`, or it can be sent to a `Shader` for use in GLSL. --- ---@param near number # The near plane. ---@param far number # The far plane. ---@param fov number # The vertical field of view (in radians). ---@param aspect number # The horizontal aspect ratio of the projection (width / height). ---@return lovr.Mat4 m # The original matrix. function Mat4:perspective(near, far, fov, aspect) end --- ---Rotates the matrix using a quaternion or an angle/axis rotation. --- ---@overload fun(self: lovr.Mat4, angle: number, ax: number, ay: number, az: number):lovr.Mat4 ---@param q lovr.Quat # The rotation to apply to the matrix. ---@return lovr.Mat4 m # The original matrix. function Mat4:rotate(q) end --- ---Scales the matrix. --- ---@overload fun(self: lovr.Mat4, sx: number, sy: number, sz: number):lovr.Mat4 ---@param scale lovr.Vec3 # The 3D scale to apply. ---@return lovr.Mat4 m # The original matrix. function Mat4:scale(scale) end --- ---Sets the components of the matrix from separate position, rotation, and scale arguments or an existing matrix. --- ---@overload fun(self: lovr.Mat4, n: lovr.mat4):lovr.Mat4 ---@overload fun(self: lovr.Mat4, position: lovr.Vec3, scale: lovr.Vec3, rotation: lovr.Quat):lovr.Mat4 ---@overload fun(self: lovr.Mat4, position: lovr.Vec3, rotation: lovr.Quat):lovr.Mat4 ---@overload fun(self: lovr.Mat4, ...):lovr.Mat4 ---@overload fun(self: lovr.Mat4, d: number):lovr.Mat4 ---@return lovr.Mat4 m # The input matrix. function Mat4:set() end --- ---Sets a model transform matrix that moves to `from` and orients model towards `to` point. --- ---This is used when rendered model should always point torwards a point of interest. The resulting Mat4 object can be used as model pose. --- ---The target() function produces same result as lookAt() after matrix inversion. --- ---@param from lovr.Vec3 # The position of the viewer. ---@param to lovr.Vec3 # The position of the target. ---@param up? lovr.Vec3 # The up vector of the viewer. ---@return lovr.Mat4 m # The original matrix. function Mat4:target(from, to, up) end --- ---Translates the matrix. --- ---@overload fun(self: lovr.Mat4, x: number, y: number, z: number):lovr.Mat4 ---@param v lovr.Vec3 # The translation vector. ---@return lovr.Mat4 m # The original matrix. function Mat4:translate(v) end --- ---Transposes the matrix, mirroring its values along the diagonal. --- ---@return lovr.Mat4 m # The original matrix. function Mat4:transpose() end --- ---Returns the components of matrix, either as 10 separated numbers representing the position, scale, and rotation, or as 16 raw numbers representing the individual components of the matrix in column-major order. --- ---@param raw boolean # Whether to return the 16 raw components. function Mat4:unpack(raw) end --- ---A `quat` is a math type that represents a 3D rotation, stored as four numbers. --- ---@class lovr.Quat local Quat = {} --- ---Conjugates the input quaternion in place, returning the input. --- ---If the quaternion is normalized, this is the same as inverting it. --- ---It negates the (x, y, z) components of the quaternion. --- ---@return lovr.Quat q # The original quaternion. function Quat:conjugate() end --- ---Creates a new temporary vec3 facing the forward direction, rotates it by this quaternion, and returns the vector. --- ---@return lovr.Vec3 v # The direction vector. function Quat:direction() end --- ---Returns the length of the quaternion. --- ---@return number length # The length of the quaternion. function Quat:length() end --- ---Multiplies this quaternion by another value. --- ---If the value is a quaternion, the rotations in the two quaternions are applied sequentially and the result is stored in the first quaternion. --- ---If the value is a vector, then the input vector is rotated by the quaternion and returned. --- ---@overload fun(self: lovr.Quat, v3: lovr.vec3):lovr.vec3 ---@param r lovr.quat # A quaternion to combine with the original. ---@return lovr.quat q # The original quaternion. function Quat:mul(r) end --- ---Adjusts the values in the quaternion so that its length becomes 1. --- --- ---### NOTE: ---A common source of bugs with quaternions is to forget to normalize them after performing a series of operations on them. --- ---Try normalizing a quaternion if some of the calculations aren't working quite right! --- ---@return lovr.Quat q # The original quaternion. function Quat:normalize() end --- ---Sets the components of the quaternion. --- ---There are lots of different ways to specify the new components, the summary is: --- ---- Four numbers can be used to specify an angle/axis rotation, similar to other LÖVR functions. ---- Four numbers plus the fifth `raw` flag can be used to set the raw values of the quaternion. ---- An existing quaternion can be passed in to copy its values. ---- A single direction vector can be specified to turn its direction (relative to the default --- forward direction of "negative z") into a rotation. ---- Two direction vectors can be specified to set the quaternion equal to the rotation between the --- two vectors. ---- A matrix can be passed in to extract the rotation of the matrix into a quaternion. --- ---@overload fun(self: lovr.Quat, r: lovr.quat):lovr.quat ---@overload fun(self: lovr.Quat, v: lovr.vec3):lovr.quat ---@overload fun(self: lovr.Quat, v: lovr.vec3, u: lovr.vec3):lovr.quat ---@overload fun(self: lovr.Quat, m: lovr.mat4):lovr.quat ---@overload fun(self: lovr.Quat):lovr.quat ---@param angle? any # The angle to use for the rotation, in radians. ---@param ax? number # The x component of the axis of rotation. ---@param ay? number # The y component of the axis of rotation. ---@param az? number # The z component of the axis of rotation. ---@param raw? boolean # Whether the components should be interpreted as raw `(x, y, z, w)` components. ---@return lovr.quat q # The original quaternion. function Quat:set(angle, ax, ay, az, raw) end --- ---Performs a spherical linear interpolation between this quaternion and another one, which can be used for smoothly animating between two rotations. --- ---The amount of interpolation is controlled by a parameter `t`. --- ---A `t` value of zero leaves the original quaternion unchanged, whereas a `t` of one sets the original quaternion exactly equal to the target. --- ---A value between `0` and `1` returns a rotation between the two based on the value. --- ---@param r lovr.Quat # The quaternion to slerp towards. ---@param t number # The lerping parameter. ---@return lovr.Quat q # The original quaternion, containing the new lerped values. function Quat:slerp(r, t) end --- ---Returns the components of the quaternion as numbers, either in an angle/axis representation or as raw quaternion values. --- ---@param raw? boolean # Whether the values should be returned as raw values instead of angle/axis. ---@return number a # The angle in radians, or the x value. ---@return number b # The x component of the rotation axis or the y value. ---@return number c # The y component of the rotation axis or the z value. ---@return number d # The z component of the rotation axis or the w value. function Quat:unpack(raw) end --- ---A RandomGenerator is a standalone object that can be used to independently generate pseudo-random numbers. If you just need basic randomness, you can use `lovr.math.random` without needing to create a random generator. --- ---@class lovr.RandomGenerator local RandomGenerator = {} --- ---Returns the seed used to initialize the RandomGenerator. --- --- ---### NOTE: ---Since the seed is a 64 bit integer, each 32 bits of the seed are returned separately to avoid precision issues. --- ---@return number low # The lower 32 bits of the seed. ---@return number high # The upper 32 bits of the seed. function RandomGenerator:getSeed() end --- ---Returns the current state of the RandomGenerator. --- ---This can be used with `RandomGenerator:setState` to reliably restore a previous state of the generator. --- --- ---### NOTE: ---The seed represents the starting state of the RandomGenerator, whereas the state represents the current state of the generator. --- ---@return string state # The serialized state. function RandomGenerator:getState() end --- ---Returns the next uniformly distributed pseudo-random number from the RandomGenerator's sequence. --- ---@overload fun(self: lovr.RandomGenerator, high: number):number ---@overload fun(self: lovr.RandomGenerator, low: number, high: number):number ---@return number x # A pseudo-random number. function RandomGenerator:random() end --- ---Returns a pseudo-random number from a normal distribution (a bell curve). --- ---You can control the center of the bell curve (the mean value) and the overall width (sigma, or standard deviation). --- ---@param sigma? number # The standard deviation of the distribution. This can be thought of how "wide" the range of numbers is or how much variability there is. ---@param mu? number # The average value returned. ---@return number x # A normally distributed pseudo-random number. function RandomGenerator:randomNormal(sigma, mu) end --- ---Seed the RandomGenerator with a new seed. --- ---Each seed will cause the RandomGenerator to produce a unique sequence of random numbers. --- --- ---### NOTE: ---For precise 64 bit seeds, you should specify the lower and upper 32 bits of the seed separately. Otherwise, seeds larger than 2^53 will start to lose precision. --- ---@overload fun(self: lovr.RandomGenerator, low: number, high: number) ---@param seed number # The random seed. function RandomGenerator:setSeed(seed) end --- ---Sets the state of the RandomGenerator, as previously obtained using `RandomGenerator:getState`. This can be used to reliably restore a previous state of the generator. --- --- ---### NOTE: ---The seed represents the starting state of the RandomGenerator, whereas the state represents the current state of the generator. --- ---@param state string # The serialized state. function RandomGenerator:setState(state) end --- ---A vector object that holds two numbers. --- ---@class lovr.Vec2 local Vec2 = {} --- ---Adds a vector or a number to the vector. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):lovr.Vec2 ---@param u lovr.Vec2 # The other vector. ---@return lovr.Vec2 v # The original vector. function Vec2:add(u) end --- ---Returns the distance to another vector. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):number ---@param u lovr.Vec2 # The vector to measure the distance to. ---@return number distance # The distance to `u`. function Vec2:distance(u) end --- ---Divides the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):lovr.Vec2 ---@param u lovr.Vec2 # The other vector to divide the components by. ---@return lovr.Vec2 v # The original vector. function Vec2:div(u) end --- ---Returns the dot product between this vector and another one. --- --- ---### NOTE: ---This is computed as: --- --- dot = v.x * u.x + v.y * u.y --- ---The vectors are not normalized before computing the dot product. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):number ---@param u lovr.Vec2 # The vector to compute the dot product with. ---@return number dot # The dot product between `v` and `u`. function Vec2:dot(u) end --- ---Returns the length of the vector. --- --- ---### NOTE: ---The length is equivalent to this: --- --- math.sqrt(v.x * v.x + v.y * v.y) --- ---@return number length # The length of the vector. function Vec2:length() end --- ---Performs a linear interpolation between this vector and another one, which can be used to smoothly animate between two vectors, based on a parameter value. --- ---A parameter value of `0` will leave the vector unchanged, a parameter value of `1` will set the vector to be equal to the input vector, and a value of `.5` will set the components to be halfway between the two vectors. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):lovr.Vec2 ---@return lovr.Vec2 v # The original vector, containing the new lerped values. function Vec2:lerp() end --- ---Multiplies the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):lovr.Vec2 ---@param u lovr.Vec2 # The other vector to multiply the components by. ---@return lovr.Vec2 v # The original vector. function Vec2:mul(u) end --- ---Adjusts the values in the vector so that its direction stays the same but its length becomes 1. --- ---@return lovr.Vec2 v # The original vector. function Vec2:normalize() end --- ---Sets the components of the vector, either from numbers or an existing vector. --- ---@overload fun(self: lovr.Vec2, u: lovr.Vec2):lovr.Vec2 ---@param x? number # The new x value of the vector. ---@param y? number # The new y value of the vector. ---@return lovr.Vec2 v # The input vector. function Vec2:set(x, y) end --- ---Subtracts a vector or a number from the vector. --- ---@overload fun(self: lovr.Vec2, x: number, y: number):lovr.Vec2 ---@param u lovr.Vec2 # The other vector. ---@return lovr.Vec2 v # The original vector. function Vec2:sub(u) end --- ---Returns the 2 components of the vector as numbers. --- ---@return number x # The x value. ---@return number y # The y value. function Vec2:unpack() end --- ---A vector object that holds three numbers. --- ---@class lovr.Vec3 local Vec3 = {} --- ---Adds a vector or a number to the vector. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):lovr.Vec3 ---@param u lovr.Vec3 # The other vector. ---@return lovr.Vec3 v # The original vector. function Vec3:add(u) end --- ---Sets this vector to be equal to the cross product between this vector and another one. --- ---The new `v` will be perpendicular to both the old `v` and `u`. --- --- ---### NOTE: ---The vectors are not normalized before or after computing the cross product. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):lovr.Vec3 ---@param u lovr.Vec3 # The vector to compute the cross product with. ---@return lovr.Vec3 v # The original vector, with the cross product as its values. function Vec3:cross(u) end --- ---Returns the distance to another vector. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):number ---@param u lovr.Vec3 # The vector to measure the distance to. ---@return number distance # The distance to `u`. function Vec3:distance(u) end --- ---Divides the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):lovr.Vec3 ---@param u lovr.Vec3 # The other vector to divide the components by. ---@return lovr.Vec3 v # The original vector. function Vec3:div(u) end --- ---Returns the dot product between this vector and another one. --- --- ---### NOTE: ---This is computed as: --- --- dot = v.x * u.x + v.y * u.y + v.z * u.z --- ---The vectors are not normalized before computing the dot product. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):number ---@param u lovr.Vec3 # The vector to compute the dot product with. ---@return number dot # The dot product between `v` and `u`. function Vec3:dot(u) end --- ---Returns the length of the vector. --- --- ---### NOTE: ---The length is equivalent to this: --- --- math.sqrt(v.x * v.x + v.y * v.y + v.z * v.z) --- ---@return number length # The length of the vector. function Vec3:length() end --- ---Performs a linear interpolation between this vector and another one, which can be used to smoothly animate between two vectors, based on a parameter value. --- ---A parameter value of `0` will leave the vector unchanged, a parameter value of `1` will set the vector to be equal to the input vector, and a value of `.5` will set the components to be halfway between the two vectors. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number, t: number):lovr.Vec3 ---@param u lovr.Vec3 # The vector to lerp towards. ---@param t number # The lerping parameter. ---@return lovr.Vec3 v # The original vector, containing the new lerped values. function Vec3:lerp(u, t) end --- ---Multiplies the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):lovr.Vec3 ---@param u lovr.Vec3 # The other vector to multiply the components by. ---@return lovr.Vec3 v # The original vector. function Vec3:mul(u) end --- ---Adjusts the values in the vector so that its direction stays the same but its length becomes 1. --- ---@return lovr.Vec3 v # The original vector. function Vec3:normalize() end --- ---Sets the components of the vector, either from numbers or an existing vector. --- ---@overload fun(self: lovr.Vec3, u: lovr.Vec3):lovr.Vec3 ---@overload fun(self: lovr.Vec3, m: lovr.Mat4):lovr.Vec3 ---@param x? number # The new x value of the vector. ---@param y? number # The new y value of the vector. ---@param z? number # The new z value of the vector. ---@return lovr.Vec3 v # The input vector. function Vec3:set(x, y, z) end --- ---Subtracts a vector or a number from the vector. --- ---@overload fun(self: lovr.Vec3, x: number, y: number, z: number):lovr.Vec3 ---@param u lovr.Vec3 # The other vector. ---@return lovr.Vec3 v # The original vector. function Vec3:sub(u) end --- ---Returns the 3 components of the vector as numbers. --- ---@return number x # The x value. ---@return number y # The y value. ---@return number z # The z value. function Vec3:unpack() end --- ---A vector object that holds four numbers. --- ---@class lovr.Vec4 local Vec4 = {} --- ---Adds a vector or a number to the vector. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):lovr.Vec4 ---@param u lovr.Vec4 # The other vector. ---@return lovr.Vec4 v # The original vector. function Vec4:add(u) end --- ---Returns the distance to another vector. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):number ---@param u lovr.Vec4 # The vector to measure the distance to. ---@return number distance # The distance to `u`. function Vec4:distance(u) end --- ---Divides the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):lovr.Vec4 ---@param u lovr.Vec4 # The other vector to divide the components by. ---@return lovr.Vec4 v # The original vector. function Vec4:div(u) end --- ---Returns the dot product between this vector and another one. --- --- ---### NOTE: ---This is computed as: --- --- dot = v.x * u.x + v.y * u.y + v.z * u.z + v.w * u.w --- ---The vectors are not normalized before computing the dot product. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):number ---@param u lovr.Vec4 # The vector to compute the dot product with. ---@return number dot # The dot product between `v` and `u`. function Vec4:dot(u) end --- ---Returns the length of the vector. --- --- ---### NOTE: ---The length is equivalent to this: --- --- math.sqrt(v.x * v.x + v.y * v.y * v.z + v.z + v.w * v.w) --- ---@return number length # The length of the vector. function Vec4:length() end --- ---Performs a linear interpolation between this vector and another one, which can be used to smoothly animate between two vectors, based on a parameter value. --- ---A parameter value of `0` will leave the vector unchanged, a parameter value of `1` will set the vector to be equal to the input vector, and a value of `.5` will set the components to be halfway between the two vectors. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number, t: number):lovr.Vec4 ---@param u lovr.Vec4 # The vector to lerp towards. ---@param t number # The lerping parameter. ---@return lovr.Vec4 v # The original vector, containing the new lerped values. function Vec4:lerp(u, t) end --- ---Multiplies the vector by a vector or a number. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):lovr.Vec4 ---@param u lovr.Vec4 # The other vector to multiply the components by. ---@return lovr.Vec4 v # The original vector. function Vec4:mul(u) end --- ---Adjusts the values in the vector so that its direction stays the same but its length becomes 1. --- ---@return lovr.Vec4 v # The original vector. function Vec4:normalize() end --- ---Sets the components of the vector, either from numbers or an existing vector. --- ---@overload fun(self: lovr.Vec4, u: lovr.Vec4):lovr.Vec4 ---@param x? number # The new x value of the vector. ---@param y? number # The new y value of the vector. ---@param z? number # The new z value of the vector. ---@param w? number # The new w value of the vector. ---@return lovr.Vec4 v # The input vector. function Vec4:set(x, y, z, w) end --- ---Subtracts a vector or a number from the vector. --- ---@overload fun(self: lovr.Vec4, x: number, y: number, z: number, w: number):lovr.Vec4 ---@param u lovr.Vec4 # The other vector. ---@return lovr.Vec4 v # The original vector. function Vec4:sub(u) end --- ---Returns the 4 components of the vector as numbers. --- ---@return number x # The x value. ---@return number y # The y value. ---@return number z # The z value. ---@return number w # The w value. function Vec4:unpack() end --- ---LÖVR has math objects for vectors, matrices, and quaternions, collectively called "vector objects". --- ---Vectors are useful because they can represent a multidimensional quantity (like a 3D position) using just a single value. --- --- ---### NOTE: ---Most LÖVR functions that accept positions, orientations, transforms, velocities, etc. also accept vector objects, so they can be used interchangeably with numbers: --- --- function lovr.draw() --- -- position and size are vec3's, rotation is a quat --- lovr.graphics.box('fill', position, size, rotation) --- end --- ---### Temporary vs. Permanent --- ---Vectors can be created in two different ways: **permanent** and **temporary**. --- ---**Permanent** vectors behave like normal Lua values. --- ---They are individual objects that are garbage collected when no longer needed. --- ---They're created using the usual `lovr.math.new` syntax: --- --- self.position = lovr.math.newVec3(x, y, z) --- ---**Temporary** vectors are created from a shared pool of vector objects. --- ---This makes them faster because they use temporary memory and do not need to be garbage collected. --- ---To make a temporary vector, leave off the `new` prefix: --- --- local position = lovr.math.vec3(x, y, z) --- ---As a further shorthand, these vector constructors are placed on the global scope. --- ---If you prefer to keep the global scope clean, this can be configured using the `t.math.globals` flag in `lovr.conf`. --- --- local position = vec3(x1, y1, z1) + vec3(x2, y2, z2) --- ---Temporary vectors, with all their speed, come with an important restriction: they can only be used during the frame in which they were created. --- ---Saving them into variables and using them later on will throw an error: --- --- local position = vec3(1, 2, 3) --- --- function lovr.update(dt) --- -- Reusing a temporary vector across frames will error: --- position:add(vec3(dt)) --- end --- ---It's possible to overflow the temporary vector pool. --- ---If that happens, `lovr.math.drain` can be used to periodically drain the pool, invalidating any existing temporary vectors. --- ---### Metamethods --- ---Vectors have metamethods, allowing them to be used using the normal math operators like `+`, `-`, `*`, `/`, etc. --- --- print(vec3(2, 4, 6) * .5 + vec3(10, 20, 30)) --- ---These metamethods will create new temporary vectors. --- ---### Components and Swizzles --- ---The raw components of a vector can be accessed like normal fields: --- --- print(vec3(1, 2, 3).z) --> 3 --- print(mat4()[16]) --> 1 --- ---Also, multiple fields can be accessed and combined into a new (temporary) vector, called swizzling: --- --- local position = vec3(10, 5, 1) --- print(position.xy) --> vec2(10, 5) --- print(position.xyy) --> vec3(10, 5, 5) --- print(position.zyxz) --> vec4(1, 5, 10, 1) --- ---The following fields are supported for vectors: --- ---- `x`, `y`, `z`, `w` ---- `r`, `g`, `b`, `a` ---- `s`, `t`, `p`, `q` --- ---Quaternions support `x`, `y`, `z`, and `w`. --- ---Matrices use numbers for accessing individual components in "column-major" order. --- ---All fields can also be assigned to. --- --- -- Swap the components of a 2D vector --- v.xy = v.yx --- ---The `unpack` function can be used (on any vector type) to access all of the individual components of a vector object. --- ---For quaternions you can choose whether you want to unpack the angle/axis representation or the raw quaternion components. --- ---Similarly, matrices support raw unpacking as well as decomposition into translation/scale/rotation values. --- ---@class lovr.Vectors local Vectors = {}