christoph/lua-computercraft
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This commit is contained in:
Christoph Urlacher
2025-10-07 14:52:17 +02:00
parent b71267bf42
commit a5b159fca4
10 changed files with 1169 additions and 1178 deletions
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9
.luarc.json Normal file
View File

@ -0,0 +1,9 @@
{
"diagnostics.globals": [
"printError",
"turtle",
"shell",
"peripheral",
"parallel"
]
}

83
controller/audio_controller.lua
View File

@ -1,5 +1,4 @@
local dfpwm = require("cc.audio.dfpwm")
local Direction = require("lib.direction")
---@alias AudioControllerConfig {buffer_length_seconds: number}
@ -9,88 +8,80 @@ local Direction = require("lib.direction")
local AudioController = {}
AudioController.__index = AudioController
---@return AudioController
function AudioController:Create()
local t = {}
setmetatable(t, AudioController)
local t = {}
setmetatable(t, AudioController)
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
t.config = {
buffer_length_seconds = 1,
}
t.play = false
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
t.config = {
buffer_length_seconds = 1
}
t.play = false
return t
return t
end
-----------------------------------------------------------------------------------------------
-- Audio Methods
-----------------------------------------------------------------------------------------------
function AudioController:PlayAudio(filename)
self.play = true
self.play = true
local decoder = dfpwm.make_decoder()
while self.play do
for chunk in io.lines(("audio/%s.dfpwm"):format(filename), self.config.buffer_length_seconds * 1024) do
if not self.play then
break
end
local decoder = dfpwm.make_decoder()
while self.play do
for chunk in io.lines(("audio/%s.dfpwm"):format(filename), self.config.buffer_length_seconds * 1024) do
if not self.play then
break
end
local buffer = decoder(chunk)
local buffer = decoder(chunk)
while not self:GetSpeaker().playAudio(buffer) do
---@diagnostic disable-next-line: undefined-field
os.pullEvent("speaker_audio_empty")
end
end
end
while not self:GetSpeaker().playAudio(buffer) do
if not self.play then
break
end
---@diagnostic disable-next-line: undefined-field
os.pullEvent("speaker_audio_empty")
end
end
end
end
function AudioController:PlayAudioFactory(filename)
local function play()
self:PlayAudio(filename)
end
local function play()
self:PlayAudio(filename)
end
return play
return play
end
-----------------------------------------------------------------------------------------------
-- Management Methods
-----------------------------------------------------------------------------------------------
---@return table | nil
function AudioController:GetSpeaker()
return peripheral.find("speaker")
return peripheral.find("speaker")
end
function AudioController:StopPlaying()
self.play = false
self:GetSpeaker().stop()
self.play = false
self:GetSpeaker().stop()
end
-----------------------------------------------------------------------------------------------
-- Main Method
-----------------------------------------------------------------------------------------------
function AudioController:Run()
-- self:Configure()
-- self:Configure()
self:PlayAudio("bangarang")
self:PlayAudio("bangarang")
end
return AudioController

454
controller/excavation_controller.lua
View File

@ -11,322 +11,320 @@ local AudioController = require("controller.audio_controller")
local ExcavationController = {}
ExcavationController.__index = ExcavationController
---@return ExcavationController
function ExcavationController:Create()
local t = {}
setmetatable(t, ExcavationController)
local t = {}
setmetatable(t, ExcavationController)
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
t.controller = TurtleController:Create()
t.audio = AudioController:Create()
t.config = {
slice_length = 0,
slice_height = 0,
center_slice_width = 0,
slice_width = 0,
slice_padding = 0,
slices_left = 0,
slices_right = 0,
}
t.controller = TurtleController:Create()
t.audio = AudioController:Create()
t.config = {
slice_length = 0,
slice_height = 0,
center_slice_width = 0,
slice_width = 0,
slice_padding = 0,
slices_left = 0,
slices_right = 0,
}
return t
return t
end
-----------------------------------------------------------------------------------------------
-- Behavior Methods
-----------------------------------------------------------------------------------------------
---Excavates a single 1x1/1x2 tunnel of configured length.
---Will leave the turtle wherever it ends up.
---Only unstocks/refuels if required.
---@param mine_above boolean
---@param mine_below boolean
function ExcavationController:Excavate_1x1or2or3xL(mine_above, mine_below)
self.controller:EnableMiningForward()
if mine_above then
self.controller:EnableMiningAbove()
end
if mine_below then
self.controller:EnableMiningBelow()
end
self.controller:EnableMiningForward()
if mine_above then
self.controller:EnableMiningAbove()
end
if mine_below then
self.controller:EnableMiningBelow()
end
self.controller:MoveForward(self.config.slice_length)
self.controller:MoveForward(self.config.slice_length)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:DisableMiningBelow()
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:DisableMiningBelow()
end
---Excavates a single 1xH partial slice of configured length.
---Will leave the turtle in its starting position.
---Only unstocks/refuels if required.
function ExcavationController:Excavate_1xHxL()
self.controller:StorePosition()
self.controller:StorePosition()
-- We can mine 2 blocks heigh in a single go
local number_of_1x3xL = math.floor(self.config.slice_height / 3)
-- We can mine 2 blocks heigh in a single go
local number_of_1x3xL = math.floor(self.config.slice_height / 3)
-- Prepare for mining the blocks below the turtle
if number_of_1x3xL > 0 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(1)
self.controller:DisableMiningAbove()
end
-- Prepare for mining the blocks below the turtle
if number_of_1x3xL > 0 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(1)
self.controller:DisableMiningAbove()
end
-- Mine 1x3xL
for i = 1,number_of_1x3xL do
self:Excavate_1x1or2or3xL(true, true)
-- Mine 1x3xL
for i = 1, number_of_1x3xL do
self:Excavate_1x1or2or3xL(true, true)
self.controller:TurnRelative(2)
self.controller:TurnRelative(2)
-- Don't move upwards in the last iteration so we can decide
-- how much to move depending on how much we still have to excavate
if i == number_of_1x3xL then
break
end
-- Don't move upwards in the last iteration so we can decide
-- how much to move depending on how much we still have to excavate
if i == number_of_1x3xL then
break
end
self.controller:EnableMiningAbove()
self.controller:MoveVertical(4)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
end
self.controller:EnableMiningAbove()
self.controller:MoveVertical(4)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
end
-- Mine remaining 1x2xL or 1x1xL
if self.config.slice_height % 3 == 2 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(3)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
-- Mine remaining 1x2xL or 1x1xL
if self.config.slice_height % 3 == 2 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(3)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
self:Excavate_1x1or2or3xL(true, false)
elseif self.config.slice_height % 3 == 1 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(3)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
self:Excavate_1x1or2or3xL(true, false)
elseif self.config.slice_height % 3 == 1 then
self.controller:EnableMiningAbove()
self.controller:MoveVertical(3)
self.controller:MoveVertical(-1)
self.controller:DisableMiningAbove()
self:Excavate_1x1or2or3xL(false, false)
end
self:Excavate_1x1or2or3xL(false, false)
end
self.controller:EnableMiningBelow()
self.controller:MoveBack()
self.controller:DisableMiningBelow()
self.controller:EnableMiningBelow()
self.controller:MoveBack()
self.controller:DisableMiningBelow()
end
---Excavates a single WxH slice of configured length (EAST to WEST).
---Will leave the turtle in its starting position.
---Only unstocks/refuels if required.
---@param center_slice boolean | nil
function ExcavationController:Excavate_WxHxL(center_slice)
self.controller:StorePosition()
self.controller:StorePosition()
center_slice = center_slice or false
local width = center_slice and self.config.center_slice_width or self.config.slice_width
center_slice = center_slice or false
local width = center_slice and self.config.center_slice_width or self.config.slice_width
for i = 1,width do
self:Excavate_1xHxL()
for i = 1, width do
self:Excavate_1xHxL()
if i == width then
break
end
if i == width then
break
end
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(1)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(1)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:MoveBack()
self.controller:MoveBack()
end
---Excavates all slices.
---Will leave the turtle refueled and unstocked in its 0x0x0 position.
function ExcavationController:Excavate()
-- Enter excavation area
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(1)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
-- Enter excavation area
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(1)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
-- Excavate center slice (start from right/back/bottom)
-- Uneven center widths will be centered, even center widths will have a block more on the right
print("Excavating center slice...")
local center_width_right = math.floor(self.config.center_slice_width / 2)
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.EAST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_right)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
self:Excavate_WxHxL(true)
self.controller:MoveBack() -- (0, 0, 1)
-- Excavate center slice (start from right/back/bottom)
-- Uneven center widths will be centered, even center widths will have a block more on the right
print("Excavating center slice...")
local center_width_right = math.floor(self.config.center_slice_width / 2)
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.EAST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_right)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
self:Excavate_WxHxL(true)
self.controller:MoveBack() -- (0, 0, 1)
if self.config.slices_right > 0 then
-- Move to right slices starting location
local padded_width_right = self.config.slices_right * (self.config.slice_width + self.config.slice_padding)
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.EAST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_right + padded_width_right)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
if self.config.slices_right > 0 then
-- Move to right slices starting location
local padded_width_right = self.config.slices_right * (self.config.slice_width + self.config.slice_padding)
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.EAST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_right + padded_width_right)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
-- Excavate right slices
print("Excavating right slices")
for i = 1,self.config.slices_right do
self:Excavate_WxHxL()
-- Excavate right slices
print("Excavating right slices")
for i = 1, self.config.slices_right do
self:Excavate_WxHxL()
if i == self.config.slices_right then
break
end
if i == self.config.slices_right then
break
end
-- Move to the next slice
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_width + self.config.slice_padding)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:MoveBack() -- (0, 0, 1)
end
-- Move to the next slice
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_width + self.config.slice_padding)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:MoveBack() -- (0, 0, 1)
end
if self.config.slices_left > 0 then
-- Move to left slices starting location
local center_width_left = self.config.center_slice_width - center_width_right
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_left)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
if self.config.slices_left > 0 then
-- Move to left slices starting location
local center_width_left = self.config.center_slice_width - center_width_right
self.controller:StorePosition()
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(center_width_left)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
-- Excavate left slices
print("Excavate left slices")
for i = 1,self.config.slices_left do
-- Move to the next slice
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_padding)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
-- Excavate left slices
print("Excavate left slices")
for i = 1, self.config.slices_left do
-- Move to the next slice
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_padding)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
self:Excavate_WxHxL()
self:Excavate_WxHxL()
if i == self.config.slices_left then
break
end
if i == self.config.slices_left then
break
end
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_width)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:MoveBack() -- (0, 0, 1)
end
self.controller:TurnToDirection(Direction.WEST)
self.controller:EnableMiningForward()
self.controller:EnableMiningAbove()
self.controller:MoveForward(self.config.slice_width)
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:TurnToDirection(Direction.NORTH)
end
self.controller:MoveBack() -- (0, 0, 1)
end
-- Finish up
self.controller:MoveToPosition(0, 0, 0, self.controller.config.storage_direction)
self.controller:DropInventory()
self.controller:TurnToDirection(Direction.NORTH)
self.audio:StopPlaying()
-- Finish up
self.controller:MoveToPosition(0, 0, 0, self.controller.config.storage_direction)
self.controller:DropInventory()
self.controller:TurnToDirection(Direction.NORTH)
self.audio:StopPlaying()
end
-----------------------------------------------------------------------------------------------
-- Management Methods
-----------------------------------------------------------------------------------------------
function ExcavationController:Configure()
local config_complete = false
local config_complete = false
while not config_complete do
print("How long should each slice be?")
self.config.slice_length = tonumber(io.read()) or 3
while not config_complete do
print("How long should each slice be?")
self.config.slice_length = tonumber(io.read()) or 3
print("How high should each slice be?")
self.config.slice_height = tonumber(io.read()) or 3
print("How high should each slice be?")
self.config.slice_height = tonumber(io.read()) or 3
print("How wide should the center slice be?")
self.config.center_slice_width = tonumber(io.read()) or 1
print("How wide should the center slice be?")
self.config.center_slice_width = tonumber(io.read()) or 1
print("How wide should the other slices be?")
self.config.slice_width = tonumber(io.read()) or 1
print("How wide should the other slices be?")
self.config.slice_width = tonumber(io.read()) or 1
print("How many blocks should remain between each slice?")
self.config.slice_padding = tonumber(io.read()) or 0
print("How many blocks should remain between each slice?")
self.config.slice_padding = tonumber(io.read()) or 0
print("How many slices should the turtle mine to its right?")
self.config.slices_right = tonumber(io.read()) or 1
print("How many slices should the turtle mine to its right?")
self.config.slices_right = tonumber(io.read()) or 1
print("How many slices should the turtle mine to its left?")
self.config.slices_left = tonumber(io.read()) or 1
print("How many slices should the turtle mine to its left?")
self.config.slices_left = tonumber(io.read()) or 1
local padded_width_left = self.config.slices_left * (self.config.slice_width + self.config.slice_padding)
local padded_width_right = self.config.slices_right * (self.config.slice_width + self.config.slice_padding)
local padded_width = padded_width_left + padded_width_right + self.config.center_slice_width
local mined_width_left = self.config.slices_left * self.config.slice_width
local mined_width_right = self.config.slices_right * self.config.slice_width
local mined_width = mined_width_left + mined_width_right + self.config.center_slice_width
local padded_width_left = self.config.slices_left * (self.config.slice_width + self.config.slice_padding)
local padded_width_right = self.config.slices_right * (self.config.slice_width + self.config.slice_padding)
local padded_width = padded_width_left + padded_width_right + self.config.center_slice_width
local mined_width_left = self.config.slices_left * self.config.slice_width
local mined_width_right = self.config.slices_right * self.config.slice_width
local mined_width = mined_width_left + mined_width_right + self.config.center_slice_width
print("Configuration complete!")
print(("Mining area spans %d x %d x %d (width x height x forward), totalling %d blocks."):format(
padded_width, self.config.slice_height, self.config.slice_length, padded_width * self.config.slice_height * self.config.slice_length
))
print(("Turtle will mine %d block wide slices (%d wide in the center) with %d blocks of padding, totalling %d mined blocks."):format(
self.config.slice_width, self.config.center_slice_width, self.config.slice_padding, mined_width * self.config.slice_height * self.config.slice_length
))
print("Do you want to accept the configuration (enter 1, otherwise 0)?")
config_complete = tonumber(io.read()) == 1
end
print("Configuration complete!")
print(
("Mining area spans %d x %d x %d (width x height x forward), totalling %d blocks."):format(
padded_width,
self.config.slice_height,
self.config.slice_length,
padded_width * self.config.slice_height * self.config.slice_length
)
)
print(
("Turtle will mine %d block wide slices (%d wide in the center) with %d blocks of padding, totalling %d mined blocks."):format(
self.config.slice_width,
self.config.center_slice_width,
self.config.slice_padding,
mined_width * self.config.slice_height * self.config.slice_length
)
)
print("Do you want to accept the configuration (enter 1, otherwise 0)?")
config_complete = tonumber(io.read()) == 1
end
end
-----------------------------------------------------------------------------------------------
-- Main Method
-----------------------------------------------------------------------------------------------
function ExcavationController:Run()
self.controller:Configure()
self:Configure()
self.controller:Configure()
self:Configure()
-- Consume our starting fuel and refuel to the full amount
turtle.select(1)
turtle.refuel()
self.controller:RefuelIfEmpty()
-- Consume our starting fuel and refuel to the full amount
turtle.select(1)
turtle.refuel()
self.controller:RefuelIfEmpty()
parallel.waitForAll(function() self:Excavate() end, self.audio:PlayAudioFactory("bangarang"))
parallel.waitForAll(function()
self:Excavate()
end, self.audio:PlayAudioFactory("bangarang"))
end
return ExcavationController

313
controller/testing_controller.lua
View File

@ -6,206 +6,215 @@ local TurtleController = require("controller.turtle_controller")
local TestingController = {}
TestingController.__index = TestingController
---@return TestingController
function TestingController:Create()
local t = {}
setmetatable(t, TestingController)
local t = {}
setmetatable(t, TestingController)
t.controller = TurtleController:Create()
t.controller = TurtleController:Create()
return t
return t
end
-----------------------------------------------------------------------------------------------
-- Behavior Methods
-----------------------------------------------------------------------------------------------
function TestingController:TestRelativeMovementWithRelativeRotation()
print("Testing relative movement with relative rotation...")
print("Testing relative movement with relative rotation...")
-- N: BackCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnRelative(1) -- E: FrontCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnRelative(2) -- W: FrontRight (Center)
self.controller:MoveVertical(3)
self.controller:TurnRelative(8) -- W: FrontRight (Top)
self.controller:MoveForward(3)
self.controller:TurnRelative(3) -- S: FrontCenter (Top)
self.controller:MoveForward(3)
self.controller:TurnRelative(9) -- W: BackCenter (Top)
self.controller:MoveVertical(-3)
self.controller:TurnRelative(1) -- N: BackCenter (Center)
-- N: BackCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnRelative(1) -- E: FrontCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnRelative(2) -- W: FrontRight (Center)
self.controller:MoveVertical(3)
self.controller:TurnRelative(8) -- W: FrontRight (Top)
self.controller:MoveForward(3)
self.controller:TurnRelative(3) -- S: FrontCenter (Top)
self.controller:MoveForward(3)
self.controller:TurnRelative(9) -- W: BackCenter (Top)
self.controller:MoveVertical(-3)
self.controller:TurnRelative(1) -- N: BackCenter (Center)
print("The turtle should be in its original location.")
print(("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x, self.controller.position.y, self.controller.position.z, self.controller.position.dir
))
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print(
("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x,
self.controller.position.y,
self.controller.position.z,
self.controller.position.dir
)
)
print("Press Enter to continue")
_ = io.read()
end
function TestingController:TestRelativeMovementWithAbsoluteRotation()
print("Testing relative movement with absolute rotation...")
print("Testing relative movement with absolute rotation...")
-- N: BackCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.EAST) -- E: FrontCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.WEST) -- W: FrontRight (Center)
self.controller:MoveVertical(3)
self.controller:TurnToDirection(Direction.WEST) -- W: FrontRight (Top)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.SOUTH) -- S: FrontCenter (Top)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.WEST) -- W: BackCenter (Top)
self.controller:MoveVertical(-3)
self.controller:TurnToDirection(Direction.NORTH) -- N: BackCenter (Center)
-- N: BackCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.EAST) -- E: FrontCenter (Center)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.WEST) -- W: FrontRight (Center)
self.controller:MoveVertical(3)
self.controller:TurnToDirection(Direction.WEST) -- W: FrontRight (Top)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.SOUTH) -- S: FrontCenter (Top)
self.controller:MoveForward(3)
self.controller:TurnToDirection(Direction.WEST) -- W: BackCenter (Top)
self.controller:MoveVertical(-3)
self.controller:TurnToDirection(Direction.NORTH) -- N: BackCenter (Center)
print("The turtle should be in its original location.")
print(("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x, self.controller.position.y, self.controller.position.z, self.controller.position.dir
))
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print(
("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x,
self.controller.position.y,
self.controller.position.z,
self.controller.position.dir
)
)
print("Press Enter to continue")
_ = io.read()
end
function TestingController:TestAbsoluteMovementWithoutStack()
print("Testing absolute movement without stack...")
print("Testing absolute movement without stack...")
-- N: BackCenter (Center)
self.controller:MoveToPosition(0, 0, 3, Direction.EAST) -- E: FrontCenter (Center)
self.controller:MoveToPosition(3, 0, 3, Direction.WEST) -- W: FrontRight (Center)
self.controller:MoveToPosition(3, 3, 3, Direction.WEST) -- W: FrontRight (Top)
self.controller:MoveToPosition(0, 3, 3, Direction.SOUTH) -- S: FrontCenter (Top)
self.controller:MoveToPosition(0, 3, 0, Direction.WEST) -- W: BackCenter (Top)
self.controller:MoveToPosition(0, 0, 0, Direction.NORTH) -- N: BackCenter (Center)
-- N: BackCenter (Center)
self.controller:MoveToPosition(0, 0, 3, Direction.EAST) -- E: FrontCenter (Center)
self.controller:MoveToPosition(3, 0, 3, Direction.WEST) -- W: FrontRight (Center)
self.controller:MoveToPosition(3, 3, 3, Direction.WEST) -- W: FrontRight (Top)
self.controller:MoveToPosition(0, 3, 3, Direction.SOUTH) -- S: FrontCenter (Top)
self.controller:MoveToPosition(0, 3, 0, Direction.WEST) -- W: BackCenter (Top)
self.controller:MoveToPosition(0, 0, 0, Direction.NORTH) -- N: BackCenter (Center)
print("The turtle should be in its original location.")
print(("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x, self.controller.position.y, self.controller.position.z, self.controller.position.dir
))
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print(
("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x,
self.controller.position.y,
self.controller.position.z,
self.controller.position.dir
)
)
print("Press Enter to continue")
_ = io.read()
end
function TestingController:TestAbsoluteMovementWithStack()
print("Testing absolute movement with stack...")
print("Testing absolute movement with stack...")
-- N: BotCenter (Center)
self.controller:MoveToPosition(0, 0, 3, Direction.EAST) -- E: TopCenter (Center)
self.controller:MoveBack() -- N: BotCenter (Center)
self.controller:MoveToPosition(3, 3, 3, Direction.WEST) -- W: TopRight (Top)
self.controller:MoveBack() -- N: BotCenter (Center)
-- N: BotCenter (Center)
self.controller:MoveToPosition(0, 0, 3, Direction.EAST) -- E: TopCenter (Center)
self.controller:MoveBack() -- N: BotCenter (Center)
self.controller:MoveToPosition(3, 3, 3, Direction.WEST) -- W: TopRight (Top)
self.controller:MoveBack() -- N: BotCenter (Center)
print("The turtle should be in its original location.")
print(("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x, self.controller.position.y, self.controller.position.z, self.controller.position.dir
))
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print(
("The turtle has internal position (%d, %d, %d) and internal direction %d"):format(
self.controller.position.x,
self.controller.position.y,
self.controller.position.z,
self.controller.position.dir
)
)
print("Press Enter to continue")
_ = io.read()
end
function TestingController:TestUnstocking()
print("Testing inventory unloading...")
print("Testing inventory unloading...")
self.controller:MoveToPosition(3, 0, 3, Direction.WEST)
print("Please fill the entire inventory with items.")
print("Press Enter to continue")
_ = io.read()
self.controller:UnstockIfFull(true)
print("Press Enter to continue")
_ = io.read()
self.controller:MoveBack()
self.controller:MoveToPosition(3, 0, 3, Direction.WEST)
print("Please fill the entire inventory with items.")
print("Press Enter to continue")
_ = io.read()
self.controller:UnstockIfFull(true)
print("Press Enter to continue")
_ = io.read()
self.controller:MoveBack()
print("The turtle should be in its original location.")
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print("Press Enter to continue")
_ = io.read()
end
function TestingController:TestRefueling()
print("Testing refueling...")
print("Testing refueling...")
self.controller:MoveToPosition(3, 0, 3, Direction.WEST)
print("Please fill multiple inventory slots with items.")
print("Press Enter to continue")
_ = io.read()
self.controller:RefuelIfEmpty(true)
print("Press Enter to continue")
_ = io.read()
self.controller:MoveBack()
self.controller:MoveToPosition(3, 0, 3, Direction.WEST)
print("Please fill multiple inventory slots with items.")
print("Press Enter to continue")
_ = io.read()
self.controller:RefuelIfEmpty(true)
print("Press Enter to continue")
_ = io.read()
self.controller:MoveBack()
print("The turtle should be in its original location.")
print("Press Enter to continue")
_ = io.read()
print("The turtle should be in its original location.")
print("Press Enter to continue")
_ = io.read()
end
-----------------------------------------------------------------------------------------------
-- Main Method
-----------------------------------------------------------------------------------------------
function TestingController:Run()
self.controller:Configure()
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:DisableMiningBelow()
self.controller:Configure()
self.controller:DisableMiningForward()
self.controller:DisableMiningAbove()
self.controller:DisableMiningBelow()
print("There are multiple tests available:")
print("1: Relative movement with relative rotation")
print("2: Relative movement with absolute rotation")
print("3: Absolute movement without stack")
print("4: Absolute movement with stack")
print("5: All movement tests")
print("6: Unloading")
print("7: Refueling")
print("8: All non-movement tests")
print("9: All tests")
print("There are multiple tests available:")
print("1: Relative movement with relative rotation")
print("2: Relative movement with absolute rotation")
print("3: Absolute movement without stack")
print("4: Absolute movement with stack")
print("5: All movement tests")
print("6: Unloading")
print("7: Refueling")
print("8: All non-movement tests")
print("9: All tests")
local choice = 0
while choice < 1 or choice > 9 do
print("Choose a test by entering its number:")
choice = tonumber(io.read()) or 0
end
local choice = 0
while choice < 1 or choice > 9 do
print("Choose a test by entering its number:")
choice = tonumber(io.read()) or 0
end
if choice == 1 then
self:TestRelativeMovementWithRelativeRotation()
elseif choice == 2 then
self:TestRelativeMovementWithAbsoluteRotation()
elseif choice == 3 then
self:TestAbsoluteMovementWithoutStack()
elseif choice == 4 then
self:TestAbsoluteMovementWithStack()
elseif choice == 5 then
self:TestRelativeMovementWithRelativeRotation()
self:TestRelativeMovementWithAbsoluteRotation()
self:TestAbsoluteMovementWithoutStack()
self:TestAbsoluteMovementWithStack()
elseif choice == 6 then
self:TestUnstocking()
elseif choice == 7 then
self:TestRefueling()
elseif choice == 8 then
self:TestUnstocking()
self:TestRefueling()
elseif choice == 9 then
self:TestRelativeMovementWithRelativeRotation()
self:TestRelativeMovementWithAbsoluteRotation()
self:TestAbsoluteMovementWithoutStack()
self:TestAbsoluteMovementWithStack()
self:TestUnstocking()
self:TestRefueling()
end
if choice == 1 then
self:TestRelativeMovementWithRelativeRotation()
elseif choice == 2 then
self:TestRelativeMovementWithAbsoluteRotation()
elseif choice == 3 then
self:TestAbsoluteMovementWithoutStack()
elseif choice == 4 then
self:TestAbsoluteMovementWithStack()
elseif choice == 5 then
self:TestRelativeMovementWithRelativeRotation()
self:TestRelativeMovementWithAbsoluteRotation()
self:TestAbsoluteMovementWithoutStack()
self:TestAbsoluteMovementWithStack()
elseif choice == 6 then
self:TestUnstocking()
elseif choice == 7 then
self:TestRefueling()
elseif choice == 8 then
self:TestUnstocking()
self:TestRefueling()
elseif choice == 9 then
self:TestRelativeMovementWithRelativeRotation()
self:TestRelativeMovementWithAbsoluteRotation()
self:TestAbsoluteMovementWithoutStack()
self:TestAbsoluteMovementWithStack()
self:TestUnstocking()
self:TestRefueling()
end
end
return TestingController

543
controller/turtle_controller.lua
View File

@ -14,125 +14,117 @@ local Stack = require("lib.stack")
local TurtleController = {}
TurtleController.__index = TurtleController
---@return TurtleController
function TurtleController:Create()
local t = {}
setmetatable(t, TurtleController)
local t = {}
setmetatable(t, TurtleController)
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
-----------------------------------------------------------------------------------------------
-- Fields
-----------------------------------------------------------------------------------------------
t.config = {
fuel_direction = Direction.EAST,
fuel_name = turtle.getItemDetail(1) == nil and "" or turtle.getItemDetail(1).name,
refuel_amount = 500,
refuel_safety_margin = 160,
storage_direction = Direction.WEST,
}
t.position = Position:Empty()
t.last_positions = Stack:Create()
t.mine_forward = false
t.mine_above = false
t.mine_below = false
t.config = {
fuel_direction = Direction.EAST,
fuel_name = turtle.getItemDetail(1) == nil and "" or turtle.getItemDetail(1).name,
refuel_amount = 500,
refuel_safety_margin = 160,
storage_direction = Direction.WEST,
}
t.position = Position:Empty()
t.last_positions = Stack:Create()
t.mine_forward = false
t.mine_above = false
t.mine_below = false
return t
return t
end
-----------------------------------------------------------------------------------------------
-- Movement Methods
-----------------------------------------------------------------------------------------------
---Positive numbers turn clockwise, negative numbers turn counterclockwise
---@param number_of_turns number
function TurtleController:TurnRelative(number_of_turns)
if number_of_turns % 4 == 0 then
return
end
if number_of_turns % 4 == 0 then
return
end
-- Turn turtle
local turns = number_of_turns % 4
if turns == 3 then
-- print(("Turtle is turning by %d (shortened to %d)..."):format(number_of_turns, -1))
-- Turn turtle
local turns = number_of_turns % 4
if turns == 3 then
-- print(("Turtle is turning by %d (shortened to %d)..."):format(number_of_turns, -1))
-- If we're rotating by 3, we could turn faster by rotating by 1 in the opposite direction
turtle.turnLeft()
else
-- print(("Turtle is turning by %d (shortened to %d)..."):format(number_of_turns, turns))
-- If we're rotating by 3, we could turn faster by rotating by 1 in the opposite direction
turtle.turnLeft()
else
-- print(("Turtle is turning by %d (shortened to %d)..."):format(number_of_turns, turns))
for _ = 1,turns do
turtle.turnRight()
end
end
for _ = 1, turns do
turtle.turnRight()
end
end
-- Update current_position
self.position.dir = (self.position.dir + number_of_turns) % 4
-- Update current_position
self.position.dir = (self.position.dir + number_of_turns) % 4
end
---@param direction Direction
function TurtleController:TurnToDirection(direction)
if self.position.dir == direction then
return
end
if self.position.dir == direction then
return
end
self:TurnRelative(direction - self.position.dir)
self:TurnRelative(direction - self.position.dir)
end
---Move forward by a number of blocks depending on the current rotation
---@param number_of_blocks number
---@param skip_unstocking boolean | nil
---@param skip_refueling boolean | nil
function TurtleController:MoveForward(number_of_blocks, skip_unstocking, skip_refueling)
skip_unstocking = skip_unstocking or false
skip_refueling = skip_refueling or false
if number_of_blocks == 0 then
return
end
skip_unstocking = skip_unstocking or false
skip_refueling = skip_refueling or false
if number_of_blocks == 0 then
return
end
-- print(("Turtle is moving forward by %d blocks..."):format(number_of_blocks))
-- print(("Turtle is moving forward by %d blocks..."):format(number_of_blocks))
for _ = 1,math.abs(number_of_blocks) do
if not skip_refueling then
self:RefuelIfEmpty()
end
if not skip_unstocking then
self:UnstockIfFull()
end
for _ = 1, math.abs(number_of_blocks) do
if not skip_refueling then
self:RefuelIfEmpty()
end
if not skip_unstocking then
self:UnstockIfFull()
end
-- Mine/Move
if self.mine_forward then
while not turtle.forward() do
turtle.dig()
end
elseif not turtle.forward() then
error("Turtle failed to move forward!")
end
if self.mine_above then
turtle.digUp()
end
if self.mine_below then
turtle.digDown()
end
-- Mine/Move
if self.mine_forward then
while not turtle.forward() do
turtle.dig()
end
elseif not turtle.forward() then
error("Turtle failed to move forward!")
end
if self.mine_above then
turtle.digUp()
end
if self.mine_below then
turtle.digDown()
end
-- Update current position
if self.position.dir == Direction.NORTH then
self.position.z = self.position.z + 1
elseif self.position.dir == Direction.SOUTH then
self.position.z = self.position.z - 1
elseif self.position.dir == Direction.EAST then
self.position.x = self.position.x + 1
elseif self.position.dir == Direction.WEST then
self.position.x = self.position.x - 1
end
end
-- Update current position
if self.position.dir == Direction.NORTH then
self.position.z = self.position.z + 1
elseif self.position.dir == Direction.SOUTH then
self.position.z = self.position.z - 1
elseif self.position.dir == Direction.EAST then
self.position.x = self.position.x + 1
elseif self.position.dir == Direction.WEST then
self.position.x = self.position.x - 1
end
end
end
---Positive numbers move up, negative numbers move down.
@ -140,52 +132,50 @@ end
---@param skip_unstocking boolean | nil
---@param skip_refueling boolean | nil
function TurtleController:MoveVertical(number_of_blocks, skip_unstocking, skip_refueling)
skip_unstocking = skip_unstocking or false
skip_refueling = skip_refueling or false
if number_of_blocks == 0 then
return
end
skip_unstocking = skip_unstocking or false
skip_refueling = skip_refueling or false
if number_of_blocks == 0 then
return
end
-- print(("Turtle is moving vertically by %d blocks..."):format(number_of_blocks))
-- print(("Turtle is moving vertically by %d blocks..."):format(number_of_blocks))
local move_function = number_of_blocks > 0 and turtle.up or turtle.down
local mine_function = number_of_blocks > 0 and turtle.digUp or turtle.digDown
local mine_enabled = number_of_blocks > 0 and self.mine_above or self.mine_below
local move_function = number_of_blocks > 0 and turtle.up or turtle.down
local mine_function = number_of_blocks > 0 and turtle.digUp or turtle.digDown
local mine_enabled = number_of_blocks > 0 and self.mine_above or self.mine_below
for _ = 1,math.abs(number_of_blocks) do
if not skip_refueling then
self:RefuelIfEmpty()
end
if not skip_unstocking then
self:UnstockIfFull()
end
for _ = 1, math.abs(number_of_blocks) do
if not skip_refueling then
self:RefuelIfEmpty()
end
if not skip_unstocking then
self:UnstockIfFull()
end
-- Mine
if mine_enabled then
mine_function()
end
-- Mine
if mine_enabled then
mine_function()
end
-- Move
if not move_function() then
error("Turtle failed to move vertically!")
end
-- Move
if not move_function() then
error("Turtle failed to move vertically!")
end
-- Update current position
if number_of_blocks > 0 then
self.position.y = self.position.y + 1
elseif number_of_blocks < 0 then
self.position.y = self.position.y - 1
end
end
-- Update current position
if number_of_blocks > 0 then
self.position.y = self.position.y + 1
elseif number_of_blocks < 0 then
self.position.y = self.position.y - 1
end
end
end
---Stores the current position on the stack so we can return using TurtleController:MoveBack()
function TurtleController:StorePosition()
self.last_positions:Push(Position:Copy(self.position))
self.last_positions:Push(Position:Copy(self.position))
end
---Move to an absolute position. Stores the current position on the stack so we can return using TurtleController:MoveBack()
---@param x number The EAST/WEST axis (grows from WEST to EAST)
---@param y number The UP/DOWN axis (grows from DOWN to UP)
@ -194,40 +184,39 @@ end
---@param skip_unstocking boolean | nil
---@param skip_refueling boolean | nil
function TurtleController:MoveToPosition(x, y, z, dir, skip_unstocking, skip_refueling)
-- print(("Turtle is moving to (%d, %d, %d)..."):format(x, y, z))
-- print(("Turtle is moving to (%d, %d, %d)..."):format(x, y, z))
-- Store the current position on the stack, so we can return using TurtleController:MoveBack()
self.last_positions:Push(Position:Copy(self.position))
-- Store the current position on the stack, so we can return using TurtleController:MoveBack()
self.last_positions:Push(Position:Copy(self.position))
-- EAST/WEST axis (do first to not interfere with chests)
if self.position.x > x then
self:TurnToDirection(Direction.WEST)
elseif self.position.x < x then
self:TurnToDirection(Direction.EAST)
end
self:MoveForward(math.abs(x - self.position.x), skip_unstocking, skip_refueling)
-- EAST/WEST axis (do first to not interfere with chests)
if self.position.x > x then
self:TurnToDirection(Direction.WEST)
elseif self.position.x < x then
self:TurnToDirection(Direction.EAST)
end
self:MoveForward(math.abs(x - self.position.x), skip_unstocking, skip_refueling)
-- NORTH/SOUTH axis
if self.position.z > z then
self:TurnToDirection(Direction.SOUTH)
elseif self.position.z < z then
self:TurnToDirection(Direction.NORTH)
end
self:MoveForward(math.abs(z - self.position.z), skip_unstocking, skip_refueling)
-- NORTH/SOUTH axis
if self.position.z > z then
self:TurnToDirection(Direction.SOUTH)
elseif self.position.z < z then
self:TurnToDirection(Direction.NORTH)
end
self:MoveForward(math.abs(z - self.position.z), skip_unstocking, skip_refueling)
-- UP/DOWN axis
self:MoveVertical(y - self.position.y, skip_unstocking, skip_refueling)
-- UP/DOWN axis
self:MoveVertical(y - self.position.y, skip_unstocking, skip_refueling)
-- Direction
self:TurnToDirection(dir or Direction.NORTH)
-- Direction
self:TurnToDirection(dir or Direction.NORTH)
-- Sanity check
if not(self.position.x == x and self.position.y == y and self.position.z == z and self.position.dir == dir) then
error("TurtleController:MoveToPosition failed to move to target position!")
end
-- Sanity check
if not (self.position.x == x and self.position.y == y and self.position.z == z and self.position.dir == dir) then
error("TurtleController:MoveToPosition failed to move to target position!")
end
end
---Move by a vector. Stores the current position on the stack so we can return using TurtleController:MoveBack()
---@param x number The EAST/WEST axis (grows from WEST to EAST)
---@param y number The UP/DOWN axis (grows from DOWN to UP)
@ -236,227 +225,233 @@ end
---@param skip_unstocking boolean | nil
---@param skip_refueling boolean | nil
function TurtleController:MoveByVector(x, y, z, dir, skip_unstocking, skip_refueling)
self:MoveToPosition(self.position.x + x, self.position.y + y, self.position.z + z, dir, skip_unstocking, skip_refueling)
self:MoveToPosition(
self.position.x + x,
self.position.y + y,
self.position.z + z,
dir,
skip_unstocking,
skip_refueling
)
end
---Move to the previously stored position and pop this position from the stack.
---@param skip_unstocking boolean | nil
---@param skip_refueling boolean | nil
function TurtleController:MoveBack(skip_unstocking, skip_refueling)
local last_position = self.last_positions:Pop()
local last_position = self.last_positions:Pop()
if last_position == nil then
error("Failed to obtain last_position to move back!")
else
self:MoveToPosition(last_position.x, last_position.y, last_position.z, last_position.dir, skip_unstocking, skip_refueling)
if last_position == nil then
error("Failed to obtain last_position to move back!")
else
self:MoveToPosition(
last_position.x,
last_position.y,
last_position.z,
last_position.dir,
skip_unstocking,
skip_refueling
)
-- Pop the stack because MoveToPosition pushes our current position
self.last_positions:Pop()
end
-- Pop the stack because MoveToPosition pushes our current position
self.last_positions:Pop()
end
end
-----------------------------------------------------------------------------------------------
-- Inventory Methods
-----------------------------------------------------------------------------------------------
---@return boolean
function TurtleController:HasFuel()
local level = turtle.getFuelLevel()
local distance_home = self.position.x + self.position.y + self.position.z
local level = turtle.getFuelLevel()
local distance_home = self.position.x + self.position.y + self.position.z
return level > distance_home + self.config.refuel_safety_margin
return level > distance_home + self.config.refuel_safety_margin
end
---@return boolean
function TurtleController:HasInventorySpace()
for slot = 1,16 do
if turtle.getItemDetail(slot) == nil then
return true
end
end
for slot = 1, 16 do
if turtle.getItemDetail(slot) == nil then
return true
end
end
return false
return false
end
---@param slot number
---@param count number
---@return boolean
function TurtleController:SuckItem(slot, count)
local previous_slot = turtle.getSelectedSlot()
local previous_slot = turtle.getSelectedSlot()
turtle.select(slot or 1)
local sucked = turtle.suck(count)
turtle.select(slot or 1)
local sucked = turtle.suck(count)
turtle.select(previous_slot)
turtle.select(previous_slot)
return sucked
return sucked
end
---@param slot number
---@param count number
---@return boolean
function TurtleController:DropItem(slot, count)
local previous_slot = turtle.getSelectedSlot()
local previous_slot = turtle.getSelectedSlot()
turtle.select(slot or 1)
local dropped = turtle.drop(count)
turtle.select(slot or 1)
local dropped = turtle.drop(count)
turtle.select(previous_slot)
turtle.select(previous_slot)
return dropped
return dropped
end
function TurtleController:DropInventory()
print("Dropping inventory into chest...")
print("Dropping inventory into chest...")
for slot = 1,16 do
turtle.select(slot)
turtle.drop()
end
for slot = 1, 16 do
turtle.select(slot)
turtle.drop()
end
turtle.select(1)
turtle.select(1)
end
---@param skip_inventory_check boolean | nil
function TurtleController:UnstockIfFull(skip_inventory_check)
skip_inventory_check = skip_inventory_check or false
if not skip_inventory_check and self:HasInventorySpace() then
return
end
if skip_inventory_check then
print(("HasInventorySpace() returned %s"):format(self:HasInventorySpace()))
end
skip_inventory_check = skip_inventory_check or false
if not skip_inventory_check and self:HasInventorySpace() then
return
end
if skip_inventory_check then
print(("HasInventorySpace() returned %s"):format(self:HasInventorySpace()))
end
print("Turtle is unstocking...")
print("Turtle is unstocking...")
self:MoveToPosition(0, 0, 0, self.config.storage_direction, true, true)
self:DropInventory()
self:RefuelIfEmpty()
self:MoveToPosition(0, 0, 0, self.config.storage_direction, true, true)
self:DropInventory()
self:RefuelIfEmpty()
self:MoveBack(true, true)
self:MoveBack(true, true)
end
---@param skip_fuel_check boolean | nil
function TurtleController:RefuelIfEmpty(skip_fuel_check)
skip_fuel_check = skip_fuel_check or false
if not skip_fuel_check and self:HasFuel() then
return
end
if skip_fuel_check then
print(("HasFuel() returned %s"):format(self:HasFuel()))
end
skip_fuel_check = skip_fuel_check or false
if not skip_fuel_check and self:HasFuel() then
return
end
if skip_fuel_check then
print(("HasFuel() returned %s"):format(self:HasFuel()))
end
print("Turtle is refueling...")
print("Turtle is refueling...")
-- Clear our inventory into the storage chest
self:MoveToPosition(0, 0, 0, self.config.storage_direction, true, true)
self:DropInventory()
-- Clear our inventory into the storage chest
self:MoveToPosition(0, 0, 0, self.config.storage_direction, true, true)
self:DropInventory()
-- Prepare refueling
self:TurnToDirection(self.config.fuel_direction)
turtle.select(1)
-- Prepare refueling
self:TurnToDirection(self.config.fuel_direction)
turtle.select(1)
-- Include the distance to the last position when refueling
-- to keep the amount of work done between refuelings constant
local target_fuel_level = self.config.refuel_amount
local last_position = self.last_positions:Peek()
if last_position == nil then
error("Failed to obtain last_position while refueling!")
else
target_fuel_level = target_fuel_level + last_position.x + last_position.y + last_position.z
end
-- Include the distance to the last position when refueling
-- to keep the amount of work done between refuelings constant
local target_fuel_level = self.config.refuel_amount
local last_position = self.last_positions:Peek()
if last_position == nil then
error("Failed to obtain last_position while refueling!")
else
target_fuel_level = target_fuel_level + last_position.x + last_position.y + last_position.z
end
-- Refuel until we hit the refuel_amount
local before_level = turtle.getFuelLevel()
repeat
if not self:SuckItem(1, 1) then
error("Failed to suck fuel out of fuel chest!")
end
turtle.refuel()
until turtle.getFuelLevel() >= target_fuel_level
local after_level = turtle.getFuelLevel()
-- Refuel until we hit the refuel_amount
local before_level = turtle.getFuelLevel()
repeat
if not self:SuckItem(1, 1) then
error("Failed to suck fuel out of fuel chest!")
end
turtle.refuel()
until turtle.getFuelLevel() >= target_fuel_level
local after_level = turtle.getFuelLevel()
self:MoveBack(true, true)
self:MoveBack(true, true)
print(("Refuelled %d units, current level is %d (old level was %d)"):format(after_level - before_level, after_level, before_level))
print(
("Refuelled %d units, current level is %d (old level was %d)"):format(
after_level - before_level,
after_level,
before_level
)
)
end
-----------------------------------------------------------------------------------------------
-- Management Methods
-----------------------------------------------------------------------------------------------
function TurtleController:Configure()
local config_complete = false
local config_complete = false
while not config_complete do
-- Check for valid fuel
while self.config.fuel_name == "" do
print("Please put valid fuel into the first slot and press Enter!")
local _ = io.read()
self.config.fuel_name = turtle.getItemDetail(1) == nil and "" or turtle.getItemDetail(1).name
end
while not config_complete do
-- Check for valid fuel
while self.config.fuel_name == "" do
print("Please put valid fuel into the first slot and press Enter!")
local _ = io.read()
self.config.fuel_name = turtle.getItemDetail(1) == nil and "" or turtle.getItemDetail(1).name
end
print("A chest with fuel has to be placed beside the turtle's starting position. Is this chest...")
print(("...right of the turtle (enter %d)?"):format(Direction.EAST))
print(("...behind the turtle (enter %d)?"):format(Direction.SOUTH))
print(("...left of the turtle (enter %d)?"):format(Direction.WEST))
print("By default, the chest is assumed on the left.")
self.config.fuel_direction = tonumber(io.read()) or Direction.WEST
print("A chest with fuel has to be placed beside the turtle's starting position. Is this chest...")
print(("...right of the turtle (enter %d)?"):format(Direction.EAST))
print(("...behind the turtle (enter %d)?"):format(Direction.SOUTH))
print(("...left of the turtle (enter %d)?"):format(Direction.WEST))
print("By default, the chest is assumed on the left.")
self.config.fuel_direction = tonumber(io.read()) or Direction.WEST
print("A chest to store mined blocks has to be placed beside the turtle's starting position. Is this chest...")
print(("...right of the turtle (enter %d)?"):format(Direction.EAST))
print(("...behind the turtle (enter %d)?"):format(Direction.SOUTH))
print(("...left of the turtle (enter %d)?"):format(Direction.WEST))
print("By default, the chest is assumed on the right.")
self.config.storage_direction = tonumber(io.read()) or Direction.EAST
print("A chest to store mined blocks has to be placed beside the turtle's starting position. Is this chest...")
print(("...right of the turtle (enter %d)?"):format(Direction.EAST))
print(("...behind the turtle (enter %d)?"):format(Direction.SOUTH))
print(("...left of the turtle (enter %d)?"):format(Direction.WEST))
print("By default, the chest is assumed on the right.")
self.config.storage_direction = tonumber(io.read()) or Direction.EAST
print("Configuration complete!")
print(("Turtle will consume \"%s\" for fuel. Put the desired fuel into the first slot to change."):format(self.config.fuel_name))
print("Do you want to accept the configuration (enter 1, otherwise 0)?")
config_complete = tonumber(io.read()) == 1
end
print("Configuration complete!")
print(
('Turtle will consume "%s" for fuel. Put the desired fuel into the first slot to change.'):format(
self.config.fuel_name
)
)
print("Do you want to accept the configuration (enter 1, otherwise 0)?")
config_complete = tonumber(io.read()) == 1
end
end
function TurtleController:EnableMiningForward()
self.mine_forward = true
self.mine_forward = true
end
function TurtleController:DisableMiningForward()
self.mine_forward = false
self.mine_forward = false
end
function TurtleController:EnableMiningAbove()
self.mine_above = true
self.mine_above = true
end
function TurtleController:DisableMiningAbove()
self.mine_above = false
self.mine_above = false
end
function TurtleController:EnableMiningBelow()
self.mine_below = true
self.mine_below = true
end
function TurtleController:DisableMiningBelow()
self.mine_below = false
self.mine_below = false
end
return TurtleController

8
lib/direction.lua
View File

@ -1,9 +1,9 @@
---@enum Direction
local Direction = {
NORTH = 0,
EAST = 1,
SOUTH = 2,
WEST = 3
NORTH = 0,
EAST = 1,
SOUTH = 2,
WEST = 3,
}
return Direction

55
lib/position.lua
View File

@ -8,18 +8,17 @@ local Direction = require("lib.direction")
local Position = {}
Position.__index = Position
---@return Position
function Position:Empty()
local t = {}
setmetatable(t, Position)
local t = {}
setmetatable(t, Position)
t.x = 0
t.y = 0
t.z = 0
t.dir = Direction.NORTH
t.x = 0
t.y = 0
t.z = 0
t.dir = Direction.NORTH
return t
return t
end
---@param x number
@ -28,43 +27,43 @@ end
---@param dir Direction
---@return Position
function Position:Create(x, y, z, dir)
local t = {}
setmetatable(t, Position)
local t = {}
setmetatable(t, Position)
t.x = x
t.y = y
t.z = z
t.dir = dir or Direction.NORTH
t.x = x
t.y = y
t.z = z
t.dir = dir or Direction.NORTH
return t
return t
end
---@param other Position
---@return Position
function Position:Copy(other)
local t = {}
setmetatable(t, Position)
local t = {}
setmetatable(t, Position)
t.x = other.x
t.y = other.y
t.z = other.z
t.dir = other.dir
t.x = other.x
t.y = other.y
t.z = other.z
t.dir = other.dir
return t
return t
end
---@param other Position
function Position:Add(other)
self.x = self.x + other.x
self.y = self.y + other.y
self.z = self.z + other.z
self.x = self.x + other.x
self.y = self.y + other.y
self.z = self.z + other.z
end
---@param other Position
function Position:Subtract(other)
self.x = self.x - other.x
self.y = self.y - other.y
self.z = self.z - other.z
self.x = self.x - other.x
self.y = self.y - other.y
self.z = self.z - other.z
end
return Position

52
lib/stack.lua
View File

@ -1,61 +1,53 @@
local Position = require("lib.position")
---@class Stack
---@field elements Position[]
local Stack = {}
Stack.__index = Stack
---@return Stack
function Stack:Create()
-- stack table
local t = {}
setmetatable(t, Stack)
-- stack table
local t = {}
setmetatable(t, Stack)
-- entry table
t.elements = {}
-- entry table
t.elements = {}
return t
return t
end
---@param element Position
function Stack:Push(element)
if element == nil or element == {} then
printError("Failed to push empty element to the stack!")
return
end
if element == nil or element == {} then
printError("Failed to push empty element to the stack!")
return
end
table.insert(self.elements, element)
table.insert(self.elements, element)
end
---@return Position | nil
function Stack:Pop()
if self:Count() == 0 then
printError("Failed to pop element from the empty stack!")
return nil
end
if self:Count() == 0 then
printError("Failed to pop element from the empty stack!")
return nil
end
return table.remove(self.elements)
return table.remove(self.elements)
end
---@return Position | nil
function Stack:Peek()
if self:Count() == 0 then
printError("Failed to peek element from the empty stack!")
return nil
end
if self:Count() == 0 then
printError("Failed to peek element from the empty stack!")
return nil
end
return self.elements[#self.elements]
return self.elements[#self.elements]
end
---@return number
function Stack:Count()
return #self.elements
return #self.elements
end
return Stack

12
main.lua
View File

@ -2,11 +2,10 @@ local TestingController = require("controller.testing_controller")
local ExcavationController = require("controller.excavation_controller")
local AudioController = require("controller.audio_controller")
local controllers = {
TestingController:Create(),
ExcavationController:Create(),
AudioController:Create(),
TestingController:Create(),
ExcavationController:Create(),
AudioController:Create(),
}
print("Multiple controllers are available:")
@ -16,13 +15,12 @@ print("3: Play Bangarang")
local choice = 0
while choice < 1 or choice > #controllers do
print("Choose a controller by entering its number:")
choice = tonumber(io.read()) or 0
print("Choose a controller by entering its number:")
choice = tonumber(io.read()) or 0
end
controllers[choice]:Run()
-- TODO: StackOverflow once the inventory is full, unstocking doesn't work...
-- Is the InventoryFull check wrong?
-- TODO: Test if there's a chest when dropping/sucking/mining (don't mine chests!)