minetest/builtin/common/vector.lua

425 lines
8.8 KiB
Lua

--[[
Vector helpers
Note: The vector.*-functions must be able to accept old vectors that had no metatables
]]
-- localize functions
local setmetatable = setmetatable
local math = math
vector = {}
local metatable = {}
vector.metatable = metatable
local xyz = {"x", "y", "z"}
-- only called when rawget(v, key) returns nil
function metatable.__index(v, key)
return rawget(v, xyz[key]) or vector[key]
end
-- only called when rawget(v, key) returns nil
function metatable.__newindex(v, key, value)
rawset(v, xyz[key] or key, value)
end
-- constructors
local function fast_new(x, y, z)
return setmetatable({x = x, y = y, z = z}, metatable)
end
function vector.new(a, b, c)
if a and b and c then
return fast_new(a, b, c)
end
-- deprecated, use vector.copy and vector.zero directly
if type(a) == "table" then
return vector.copy(a)
else
assert(not a, "Invalid arguments for vector.new()")
return vector.zero()
end
end
function vector.zero()
return fast_new(0, 0, 0)
end
function vector.copy(v)
assert(v.x and v.y and v.z, "Invalid vector passed to vector.copy()")
return fast_new(v.x, v.y, v.z)
end
function vector.from_string(s, init)
local x, y, z, np = string.match(s, "^%s*%(%s*([^%s,]+)%s*[,%s]%s*([^%s,]+)%s*[,%s]" ..
"%s*([^%s,]+)%s*[,%s]?%s*%)()", init)
x = tonumber(x)
y = tonumber(y)
z = tonumber(z)
if not (x and y and z) then
return nil
end
return fast_new(x, y, z), np
end
function vector.to_string(v)
return string.format("(%g, %g, %g)", v.x, v.y, v.z)
end
metatable.__tostring = vector.to_string
function vector.equals(a, b)
return a.x == b.x and
a.y == b.y and
a.z == b.z
end
metatable.__eq = vector.equals
-- unary operations
function vector.length(v)
return math.sqrt(v.x * v.x + v.y * v.y + v.z * v.z)
end
-- Note: we cannot use __len because it is already used for primitive table length
function vector.normalize(v)
local len = vector.length(v)
if len == 0 then
return fast_new(0, 0, 0)
else
return vector.divide(v, len)
end
end
function vector.floor(v)
return vector.apply(v, math.floor)
end
function vector.round(v)
return vector.apply(v, math.round)
end
function vector.ceil(v)
return vector.apply(v, math.ceil)
end
function vector.sign(v, tolerance)
return vector.apply(v, math.sign, tolerance)
end
function vector.abs(v)
return vector.apply(v, math.abs)
end
function vector.apply(v, func, ...)
return fast_new(
func(v.x, ...),
func(v.y, ...),
func(v.z, ...)
)
end
function vector.combine(a, b, func)
return fast_new(
func(a.x, b.x),
func(a.y, b.y),
func(a.z, b.z)
)
end
function vector.distance(a, b)
local x = a.x - b.x
local y = a.y - b.y
local z = a.z - b.z
return math.sqrt(x * x + y * y + z * z)
end
function vector.direction(pos1, pos2)
return vector.subtract(pos2, pos1):normalize()
end
function vector.angle(a, b)
local dotp = vector.dot(a, b)
local cp = vector.cross(a, b)
local crossplen = vector.length(cp)
return math.atan2(crossplen, dotp)
end
function vector.dot(a, b)
return a.x * b.x + a.y * b.y + a.z * b.z
end
function vector.cross(a, b)
return fast_new(
a.y * b.z - a.z * b.y,
a.z * b.x - a.x * b.z,
a.x * b.y - a.y * b.x
)
end
function metatable.__unm(v)
return fast_new(-v.x, -v.y, -v.z)
end
-- add, sub, mul, div operations
function vector.add(a, b)
if type(b) == "table" then
return fast_new(
a.x + b.x,
a.y + b.y,
a.z + b.z
)
else
return fast_new(
a.x + b,
a.y + b,
a.z + b
)
end
end
function metatable.__add(a, b)
return fast_new(
a.x + b.x,
a.y + b.y,
a.z + b.z
)
end
function vector.subtract(a, b)
if type(b) == "table" then
return fast_new(
a.x - b.x,
a.y - b.y,
a.z - b.z
)
else
return fast_new(
a.x - b,
a.y - b,
a.z - b
)
end
end
function metatable.__sub(a, b)
return fast_new(
a.x - b.x,
a.y - b.y,
a.z - b.z
)
end
function vector.multiply(a, b)
if type(b) == "table" then
return fast_new(
a.x * b.x,
a.y * b.y,
a.z * b.z
)
else
return fast_new(
a.x * b,
a.y * b,
a.z * b
)
end
end
function metatable.__mul(a, b)
if type(a) == "table" then
return fast_new(
a.x * b,
a.y * b,
a.z * b
)
else
return fast_new(
a * b.x,
a * b.y,
a * b.z
)
end
end
function vector.divide(a, b)
if type(b) == "table" then
return fast_new(
a.x / b.x,
a.y / b.y,
a.z / b.z
)
else
return fast_new(
a.x / b,
a.y / b,
a.z / b
)
end
end
function metatable.__div(a, b)
-- scalar/vector makes no sense
return fast_new(
a.x / b,
a.y / b,
a.z / b
)
end
-- misc stuff
function vector.offset(v, x, y, z)
return fast_new(
v.x + x,
v.y + y,
v.z + z
)
end
function vector.sort(a, b)
return fast_new(math.min(a.x, b.x), math.min(a.y, b.y), math.min(a.z, b.z)),
fast_new(math.max(a.x, b.x), math.max(a.y, b.y), math.max(a.z, b.z))
end
function vector.check(v)
return getmetatable(v) == metatable
end
local function sin(x)
if x % math.pi == 0 then
return 0
else
return math.sin(x)
end
end
local function cos(x)
if x % math.pi == math.pi / 2 then
return 0
else
return math.cos(x)
end
end
function vector.rotate_around_axis(v, axis, angle)
local cosangle = cos(angle)
local sinangle = sin(angle)
axis = vector.normalize(axis)
-- https://en.wikipedia.org/wiki/Rodrigues%27_rotation_formula
local dot_axis = vector.multiply(axis, vector.dot(axis, v))
local cross = vector.cross(v, axis)
return vector.new(
cross.x * sinangle + (v.x - dot_axis.x) * cosangle + dot_axis.x,
cross.y * sinangle + (v.y - dot_axis.y) * cosangle + dot_axis.y,
cross.z * sinangle + (v.z - dot_axis.z) * cosangle + dot_axis.z
)
end
function vector.rotate(v, rot)
local sinpitch = sin(-rot.x)
local sinyaw = sin(-rot.y)
local sinroll = sin(-rot.z)
local cospitch = cos(rot.x)
local cosyaw = cos(rot.y)
local cosroll = math.cos(rot.z)
-- Rotation matrix that applies yaw, pitch and roll
local matrix = {
{
sinyaw * sinpitch * sinroll + cosyaw * cosroll,
sinyaw * sinpitch * cosroll - cosyaw * sinroll,
sinyaw * cospitch,
},
{
cospitch * sinroll,
cospitch * cosroll,
-sinpitch,
},
{
cosyaw * sinpitch * sinroll - sinyaw * cosroll,
cosyaw * sinpitch * cosroll + sinyaw * sinroll,
cosyaw * cospitch,
},
}
-- Compute matrix multiplication: `matrix` * `v`
return vector.new(
matrix[1][1] * v.x + matrix[1][2] * v.y + matrix[1][3] * v.z,
matrix[2][1] * v.x + matrix[2][2] * v.y + matrix[2][3] * v.z,
matrix[3][1] * v.x + matrix[3][2] * v.y + matrix[3][3] * v.z
)
end
function vector.dir_to_rotation(forward, up)
forward = vector.normalize(forward)
local rot = vector.new(math.asin(forward.y), -math.atan2(forward.x, forward.z), 0)
if not up then
return rot
end
assert(vector.dot(forward, up) < 0.000001,
"Invalid vectors passed to vector.dir_to_rotation().")
up = vector.normalize(up)
-- Calculate vector pointing up with roll = 0, just based on forward vector.
local forwup = vector.rotate(vector.new(0, 1, 0), rot)
-- 'forwup' and 'up' are now in a plane with 'forward' as normal.
-- The angle between them is the absolute of the roll value we're looking for.
rot.z = vector.angle(forwup, up)
-- Since vector.angle never returns a negative value or a value greater
-- than math.pi, rot.z has to be inverted sometimes.
-- To determine whether this is the case, we rotate the up vector back around
-- the forward vector and check if it worked out.
local back = vector.rotate_around_axis(up, forward, -rot.z)
-- We don't use vector.equals for this because of floating point imprecision.
if (back.x - forwup.x) * (back.x - forwup.x) +
(back.y - forwup.y) * (back.y - forwup.y) +
(back.z - forwup.z) * (back.z - forwup.z) > 0.0000001 then
rot.z = -rot.z
end
return rot
end
function vector.in_area(pos, min, max)
return (pos.x >= min.x) and (pos.x <= max.x) and
(pos.y >= min.y) and (pos.y <= max.y) and
(pos.z >= min.z) and (pos.z <= max.z)
end
function vector.random_direction()
-- Generate a random direction of unit length, via rejection sampling
local x, y, z, l2
repeat -- expected less than two attempts on average (volume sphere vs. cube)
x, y, z = math.random() * 2 - 1, math.random() * 2 - 1, math.random() * 2 - 1
l2 = x*x + y*y + z*z
until l2 <= 1 and l2 >= 1e-6
-- normalize
local l = math.sqrt(l2)
return fast_new(x/l, y/l, z/l)
end
function vector.random_in_area(min, max)
return fast_new(
math.random(min.x, max.x),
math.random(min.y, max.y),
math.random(min.z, max.z)
)
end
if rawget(_G, "core") and core.set_read_vector and core.set_push_vector then
local function read_vector(v)
return v.x, v.y, v.z
end
core.set_read_vector(read_vector)
core.set_read_vector = nil
if rawget(_G, "jit") then
-- This is necessary to prevent trace aborts.
local function push_vector(x, y, z)
return (fast_new(x, y, z))
end
core.set_push_vector(push_vector)
else
core.set_push_vector(fast_new)
end
core.set_push_vector = nil
end