Some vector functions useful for working with rotations (#9572)

* added vector.rotate

* added vector.forward_from_rotation and vector.up_from_rotation

* added vector.forward_up_to_rotatiton

* fixed some bugs and formatting with vector functions

* shortened name of some new vector functions and added documentation

* made vector.rotate not require a unit vector as axis

* fixed crash with vector.forward_up_to_rot

* renamed new vector functions, made vector.rotate apply a rotation matrix, old vector.rotate is now called vector.rotate_around_axis

* documented vector function changes

* removed some whitespace to appease luacheck

* implemented and fixed optimization of vector.rotate_around_axis by SmallJoker

* added some unit tests for rotation vector functions

* clarified that rotation vectors are in radians and according to the left hand rule

* hopefully appeased luacheck

* renamed rotation_to_horizontal to forward_at_rotation, rotation_to_vertical to up_at_rotation

* handled cases where sin or cos are 0 in rotation vector functions

* added more comments

* clarified documentation of rotation vector functions

* added more unit tests

* changed way in which vector.rotate_around_axis is adjusted for left handed coordinate systems

* made vector.rotate_around_axis actually left handed

* unrolled matrix multiplication

* removed vector.forward_at_rotation and vector.up_at_rotation

* prettified vector.rotate_around_axis, made previous commits not break anything

* removed references to removed vector.forward_at_rotation and vector.up_at_rotation

* removed documentation of removed vector functions

* clarified documentation and fixed styling of rotation vector functions

* restyled comments minorly

* spelling fixes and some hopefully better comments

* allowed 'up' to be missing from vector.directions_to_rotation and removed requirement for unit vectors as arguments

* made vector.rotate_around_axis() right handed again for consistency

* documented previous changes

* made matrix multiplication actually multiply

* renamed vector.directions_to_rotation() to vector.dir_to_rotation()

* optimized a distance comparison

* Fixed potential false positive in unit tests.

Co-authored-by: NetherEran <nethereran@hotmail.com>
This commit is contained in:
NetherEran 2020-06-09 17:38:39 +00:00 committed by GitHub
parent b16f841756
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@ -43,4 +43,146 @@ describe("vector", function()
it("add()", function()
assert.same({ x = 2, y = 4, z = 6 }, vector.add(vector.new(1, 2, 3), { x = 1, y = 2, z = 3 }))
end)
-- This function is needed because of floating point imprecision.
local function almost_equal(a, b)
if type(a) == "number" then
return math.abs(a - b) < 0.00000000001
end
return vector.distance(a, b) < 0.000000000001
end
describe("rotate_around_axis()", function()
it("rotates", function()
assert.True(almost_equal({x = -1, y = 0, z = 0},
vector.rotate_around_axis({x = 1, y = 0, z = 0}, {x = 0, y = 1, z = 0}, math.pi)))
assert.True(almost_equal({x = 0, y = 1, z = 0},
vector.rotate_around_axis({x = 0, y = 0, z = 1}, {x = 1, y = 0, z = 0}, math.pi / 2)))
assert.True(almost_equal({x = 4, y = 1, z = 1},
vector.rotate_around_axis({x = 4, y = 1, z = 1}, {x = 4, y = 1, z = 1}, math.pi / 6)))
end)
it("keeps distance to axis", function()
local rotate1 = {x = 1, y = 3, z = 1}
local axis1 = {x = 1, y = 3, z = 2}
local rotated1 = vector.rotate_around_axis(rotate1, axis1, math.pi / 13)
assert.True(almost_equal(vector.distance(axis1, rotate1), vector.distance(axis1, rotated1)))
local rotate2 = {x = 1, y = 1, z = 3}
local axis2 = {x = 2, y = 6, z = 100}
local rotated2 = vector.rotate_around_axis(rotate2, axis2, math.pi / 23)
assert.True(almost_equal(vector.distance(axis2, rotate2), vector.distance(axis2, rotated2)))
local rotate3 = {x = 1, y = -1, z = 3}
local axis3 = {x = 2, y = 6, z = 100}
local rotated3 = vector.rotate_around_axis(rotate3, axis3, math.pi / 2)
assert.True(almost_equal(vector.distance(axis3, rotate3), vector.distance(axis3, rotated3)))
end)
it("rotates back", function()
local rotate1 = {x = 1, y = 3, z = 1}
local axis1 = {x = 1, y = 3, z = 2}
local rotated1 = vector.rotate_around_axis(rotate1, axis1, math.pi / 13)
rotated1 = vector.rotate_around_axis(rotated1, axis1, -math.pi / 13)
assert.True(almost_equal(rotate1, rotated1))
local rotate2 = {x = 1, y = 1, z = 3}
local axis2 = {x = 2, y = 6, z = 100}
local rotated2 = vector.rotate_around_axis(rotate2, axis2, math.pi / 23)
rotated2 = vector.rotate_around_axis(rotated2, axis2, -math.pi / 23)
assert.True(almost_equal(rotate2, rotated2))
local rotate3 = {x = 1, y = -1, z = 3}
local axis3 = {x = 2, y = 6, z = 100}
local rotated3 = vector.rotate_around_axis(rotate3, axis3, math.pi / 2)
rotated3 = vector.rotate_around_axis(rotated3, axis3, -math.pi / 2)
assert.True(almost_equal(rotate3, rotated3))
end)
it("is right handed", function()
local v_before1 = {x = 0, y = 1, z = -1}
local v_after1 = vector.rotate_around_axis(v_before1, {x = 1, y = 0, z = 0}, math.pi / 4)
assert.True(almost_equal(vector.normalize(vector.cross(v_after1, v_before1)), {x = 1, y = 0, z = 0}))
local v_before2 = {x = 0, y = 3, z = 4}
local v_after2 = vector.rotate_around_axis(v_before2, {x = 1, y = 0, z = 0}, 2 * math.pi / 5)
assert.True(almost_equal(vector.normalize(vector.cross(v_after2, v_before2)), {x = 1, y = 0, z = 0}))
local v_before3 = {x = 1, y = 0, z = -1}
local v_after3 = vector.rotate_around_axis(v_before3, {x = 0, y = 1, z = 0}, math.pi / 4)
assert.True(almost_equal(vector.normalize(vector.cross(v_after3, v_before3)), {x = 0, y = 1, z = 0}))
local v_before4 = {x = 3, y = 0, z = 4}
local v_after4 = vector.rotate_around_axis(v_before4, {x = 0, y = 1, z = 0}, 2 * math.pi / 5)
assert.True(almost_equal(vector.normalize(vector.cross(v_after4, v_before4)), {x = 0, y = 1, z = 0}))
local v_before5 = {x = 1, y = -1, z = 0}
local v_after5 = vector.rotate_around_axis(v_before5, {x = 0, y = 0, z = 1}, math.pi / 4)
assert.True(almost_equal(vector.normalize(vector.cross(v_after5, v_before5)), {x = 0, y = 0, z = 1}))
local v_before6 = {x = 3, y = 4, z = 0}
local v_after6 = vector.rotate_around_axis(v_before6, {x = 0, y = 0, z = 1}, 2 * math.pi / 5)
assert.True(almost_equal(vector.normalize(vector.cross(v_after6, v_before6)), {x = 0, y = 0, z = 1}))
end)
end)
describe("rotate()", function()
it("rotates", function()
assert.True(almost_equal({x = -1, y = 0, z = 0},
vector.rotate({x = 1, y = 0, z = 0}, {x = 0, y = math.pi, z = 0})))
assert.True(almost_equal({x = 0, y = -1, z = 0},
vector.rotate({x = 1, y = 0, z = 0}, {x = 0, y = 0, z = math.pi / 2})))
assert.True(almost_equal({x = 1, y = 0, z = 0},
vector.rotate({x = 1, y = 0, z = 0}, {x = math.pi / 123, y = 0, z = 0})))
end)
it("is counterclockwise", function()
local v_before1 = {x = 0, y = 1, z = -1}
local v_after1 = vector.rotate(v_before1, {x = math.pi / 4, y = 0, z = 0})
assert.True(almost_equal(vector.normalize(vector.cross(v_after1, v_before1)), {x = 1, y = 0, z = 0}))
local v_before2 = {x = 0, y = 3, z = 4}
local v_after2 = vector.rotate(v_before2, {x = 2 * math.pi / 5, y = 0, z = 0})
assert.True(almost_equal(vector.normalize(vector.cross(v_after2, v_before2)), {x = 1, y = 0, z = 0}))
local v_before3 = {x = 1, y = 0, z = -1}
local v_after3 = vector.rotate(v_before3, {x = 0, y = math.pi / 4, z = 0})
assert.True(almost_equal(vector.normalize(vector.cross(v_after3, v_before3)), {x = 0, y = 1, z = 0}))
local v_before4 = {x = 3, y = 0, z = 4}
local v_after4 = vector.rotate(v_before4, {x = 0, y = 2 * math.pi / 5, z = 0})
assert.True(almost_equal(vector.normalize(vector.cross(v_after4, v_before4)), {x = 0, y = 1, z = 0}))
local v_before5 = {x = 1, y = -1, z = 0}
local v_after5 = vector.rotate(v_before5, {x = 0, y = 0, z = math.pi / 4})
assert.True(almost_equal(vector.normalize(vector.cross(v_after5, v_before5)), {x = 0, y = 0, z = 1}))
local v_before6 = {x = 3, y = 4, z = 0}
local v_after6 = vector.rotate(v_before6, {x = 0, y = 0, z = 2 * math.pi / 5})
assert.True(almost_equal(vector.normalize(vector.cross(v_after6, v_before6)), {x = 0, y = 0, z = 1}))
end)
end)
it("dir_to_rotation()", function()
-- Comparing rotations (pitch, yaw, roll) is hard because of certain ambiguities,
-- e.g. (pi, 0, pi) looks exactly the same as (0, pi, 0)
-- So instead we convert the rotation back to vectors and compare these.
local function forward_at_rot(rot)
return vector.rotate(vector.new(0, 0, 1), rot)
end
local function up_at_rot(rot)
return vector.rotate(vector.new(0, 1, 0), rot)
end
local rot1 = vector.dir_to_rotation({x = 1, y = 0, z = 0}, {x = 0, y = 1, z = 0})
assert.True(almost_equal({x = 1, y = 0, z = 0}, forward_at_rot(rot1)))
assert.True(almost_equal({x = 0, y = 1, z = 0}, up_at_rot(rot1)))
local rot2 = vector.dir_to_rotation({x = 1, y = 1, z = 0}, {x = 0, y = 0, z = 1})
assert.True(almost_equal({x = 1/math.sqrt(2), y = 1/math.sqrt(2), z = 0}, forward_at_rot(rot2)))
assert.True(almost_equal({x = 0, y = 0, z = 1}, up_at_rot(rot2)))
for i = 1, 1000 do
local rand_vec = vector.new(math.random(), math.random(), math.random())
if vector.length(rand_vec) ~= 0 then
local rot_1 = vector.dir_to_rotation(rand_vec)
local rot_2 = {
x = math.atan2(rand_vec.y, math.sqrt(rand_vec.z * rand_vec.z + rand_vec.x * rand_vec.x)),
y = -math.atan2(rand_vec.x, rand_vec.z),
z = 0
}
assert.True(almost_equal(rot_1, rot_2))
end
end
end)
end)

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@ -141,3 +141,96 @@ function vector.sort(a, b)
return {x = math.min(a.x, b.x), y = math.min(a.y, b.y), z = math.min(a.z, b.z)},
{x = math.max(a.x, b.x), y = math.max(a.y, b.y), z = math.max(a.z, b.z)}
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 = {x = math.asin(forward.y), y = -math.atan2(forward.x, forward.z), 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({x = 0, y = 1, z = 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 wether 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

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@ -3007,6 +3007,24 @@ For the following functions `x` can be either a vector or a number:
* `vector.divide(v, x)`:
* Returns a scaled vector or Schur quotient.
For the following functions `a` is an angle in radians and `r` is a rotation
vector ({x = <pitch>, y = <yaw>, z = <roll>}) where pitch, yaw and roll are
angles in radians.
* `vector.rotate(v, r)`:
* Applies the rotation `r` to `v` and returns the result.
* `vector.rotate({x = 0, y = 0, z = 1}, r)` and
`vector.rotate({x = 0, y = 1, z = 0}, r)` return vectors pointing
forward and up relative to an entity's rotation `r`.
* `vector.rotate_around_axis(v1, v2, a)`:
* Returns `v1` rotated around axis `v2` by `a` radians according to
the right hand rule.
* `vector.dir_to_rotation(direction[, up])`:
* Returns a rotation vector for `direction` pointing forward using `up`
as the up vector.
* If `up` is omitted, the roll of the returned vector defaults to zero.
* Otherwise `direction` and `up` need to be vectors in a 90 degree angle to each other.