mirror of
https://github.com/irmen/prog8.git
synced 2024-11-04 19:05:57 +00:00
344 lines
11 KiB
Lua
344 lines
11 KiB
Lua
%import textio
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%import math
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; Even though prog8 only has support for extremely limited recursion,
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; you can write recursive algorithms with a bit of extra work by building your own explicit stack structure.
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; This program shows a depth-first maze generation algorithm (1 possible path from start to finish),
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; and a depth-first maze solver algorithm, both using a stack to store the path taken.
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; Note: this program can be compiled for multiple target systems.
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main {
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sub start() {
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repeat {
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maze.initialize()
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maze.drawStartFinish()
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maze.generate()
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maze.openpassages()
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maze.drawStartFinish()
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maze.solve()
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maze.drawStartFinish()
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txt.print(" enter=new maze")
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void cbm.CHRIN()
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}
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}
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}
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maze {
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const uword screenwidth = txt.DEFAULT_WIDTH
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const uword screenheight = txt.DEFAULT_HEIGHT
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const ubyte numCellsHoriz = (screenwidth-1) / 2
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const ubyte numCellsVert = (screenheight-1) / 2
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; maze start and finish cells
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const ubyte startCx = 0
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const ubyte startCy = 0
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const ubyte finishCx = numCellsHoriz-1
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const ubyte finishCy = numCellsVert-1
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; cell properties
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const ubyte STONE = 128
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const ubyte WALKED = 64
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const ubyte BACKTRACKED = 32
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const ubyte UP = 1
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const ubyte RIGHT = 2
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const ubyte DOWN = 4
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const ubyte LEFT = 8
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const ubyte WALLCOLOR = 12
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const ubyte EMPTYCOLOR = 0
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; unfortunately on larger screens (cx16), the number of cells exceeds 256 and doesn't fit in a regular array anymore.
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uword cells = memory("cells", numCellsHoriz*numCellsVert, 0)
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ubyte[256] cx_stack
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ubyte[256] cy_stack
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ubyte stackptr
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sub draw() {
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ubyte cx
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ubyte cy
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for cx in 0 to numCellsHoriz-1 {
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for cy in 0 to numCellsVert-1 {
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drawCell(cx, cy)
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}
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}
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}
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ubyte[4] directionflags = [LEFT,RIGHT,UP,DOWN]
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sub generate() {
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ubyte cx = startCx
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ubyte cy = startCy
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stackptr = 0
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@(celladdr(cx,cy)) &= ~STONE
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drawCell(cx, cy)
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uword cells_to_carve = numCellsHoriz * numCellsVert - 1
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repeat {
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carve_restart_after_repath:
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ubyte direction = choose_uncarved_direction()
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if direction==0 {
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;backtrack
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stackptr--
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if stackptr==255 {
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; stack empty.
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; repath if we are not done yet. (this is a workaround for the prog8 256 array lenght limit)
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if cells_to_carve {
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if repath()
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goto carve_restart_after_repath
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}
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return
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}
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cx = cx_stack[stackptr]
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cy = cy_stack[stackptr]
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} else {
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cx_stack[stackptr] = cx
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cy_stack[stackptr] = cy
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stackptr++
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if stackptr==0 {
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; stack overflow, we can't track our path any longer.
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; repath if we are not done yet. (this is a workaround for the prog8 256 array lenght limit)
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if cells_to_carve {
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if repath()
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goto carve_restart_after_repath
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}
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return
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}
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@(celladdr(cx,cy)) |= direction
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when direction {
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UP -> {
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cy--
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@(celladdr(cx,cy)) |= DOWN
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}
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RIGHT -> {
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cx++
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@(celladdr(cx,cy)) |= LEFT
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}
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DOWN -> {
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cy++
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@(celladdr(cx,cy)) |= UP
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}
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LEFT -> {
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cx--
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@(celladdr(cx,cy)) |= RIGHT
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}
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}
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@(celladdr(cx,cy)) &= ~STONE
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cells_to_carve--
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drawCell(cx, cy)
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}
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}
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sub repath() -> bool {
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; repath: try to find a new start cell with possible directions.
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; we limit our number of searches so that the algorith doesn't get stuck
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; for too long on bad rng... just accept a few unused cells in that case.
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repeat 255 {
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do {
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cx = math.rnd() % numCellsHoriz
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cy = math.rnd() % numCellsVert
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} until not @(celladdr(cx, cy)) & STONE
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if available_uncarved()
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return true
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}
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return false
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}
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sub available_uncarved() -> ubyte {
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ubyte candidates = 0
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if cx>0 and @(celladdr(cx-1, cy)) & STONE
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candidates |= LEFT
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if cx<numCellsHoriz-1 and @(celladdr(cx+1, cy)) & STONE
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candidates |= RIGHT
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if cy>0 and @(celladdr(cx, cy-1)) & STONE
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candidates |= UP
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if cy<numCellsVert-1 and @(celladdr(cx, cy+1)) & STONE
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candidates |= DOWN
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return candidates
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}
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sub choose_uncarved_direction() -> ubyte {
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ubyte candidates = available_uncarved()
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if not candidates
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return 0
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repeat {
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ubyte choice = candidates & directionflags[math.rnd() & 3]
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if choice
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return choice
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}
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}
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}
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sub openpassages() {
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; open just a few extra passages, so that multiple routes are possible in theory.
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ubyte cell
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ubyte numpassages
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ubyte cx
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ubyte cy
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do {
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do {
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cx = math.rnd() % (numCellsHoriz-2) + 1
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cy = math.rnd() % (numCellsVert-2) + 1
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} until not @(celladdr(cx, cy)) & STONE
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ubyte direction = directionflags[math.rnd() & 3]
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if not @(celladdr(cx, cy)) & direction {
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when direction {
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LEFT -> {
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if not @(celladdr(cx-1,cy)) & STONE {
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@(celladdr(cx,cy)) |= LEFT
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drawCell(cx,cy)
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numpassages++
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}
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}
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RIGHT -> {
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if not @(celladdr(cx+1,cy)) & STONE {
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@(celladdr(cx,cy)) |= RIGHT
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drawCell(cx,cy)
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numpassages++
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}
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}
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UP -> {
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if not @(celladdr(cx,cy-1)) & STONE {
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@(celladdr(cx,cy)) |= UP
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drawCell(cx,cy)
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numpassages++
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}
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}
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DOWN -> {
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if not @(celladdr(cx,cy+1)) & STONE {
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@(celladdr(cx,cy)) |= DOWN
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drawCell(cx,cy)
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numpassages++
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}
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}
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}
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}
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} until numpassages==10
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}
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sub solve() {
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ubyte cx = startCx
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ubyte cy = startCy
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const uword max_path_length = 1024
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; the path through the maze can be longer than 256 so doesn't fit in a regular array.... :(
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uword pathstack = memory("pathstack", max_path_length, 0)
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uword pathstackptr = 0
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@(celladdr(cx,cy)) |= WALKED
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txt.setcc(cx*2+1, cy*2+1, 81, 1)
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repeat {
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solve_loop:
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sys.waitvsync()
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if cx==finishCx and cy==finishCy {
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txt.home()
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txt.print("found! path length: ")
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txt.print_uw(pathstackptr)
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return
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}
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ubyte cell = @(celladdr(cx,cy))
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if cell & UP and not @(celladdr(cx,cy-1)) & (WALKED|BACKTRACKED) {
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@(pathstack + pathstackptr) = UP
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txt.setcc(cx*2+1, cy*2, 81, 3)
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cy--
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}
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else if cell & DOWN and not @(celladdr(cx,cy+1)) & (WALKED|BACKTRACKED) {
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@(pathstack + pathstackptr) = DOWN
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txt.setcc(cx*2+1, cy*2+2, 81, 3)
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cy++
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}
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else if cell & LEFT and not @(celladdr(cx-1,cy)) & (WALKED|BACKTRACKED) {
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@(pathstack + pathstackptr) = LEFT
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txt.setcc(cx*2, cy*2+1, 81, 3)
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cx--
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}
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else if cell & RIGHT and not @(celladdr(cx+1,cy)) & (WALKED|BACKTRACKED) {
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@(pathstack + pathstackptr) = RIGHT
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txt.setcc(cx*2+2, cy*2+1, 81, 3)
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cx++
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}
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else {
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; dead end, pop stack
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pathstackptr--
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if stackptr==65535 {
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txt.print("no solution?!")
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return
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}
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@(celladdr(cx,cy)) |= BACKTRACKED
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txt.setcc(cx*2+1, cy*2+1, 81, 2)
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when @(pathstack + pathstackptr) {
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UP -> {
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txt.setcc(cx*2+1, cy*2+2, 81, 9)
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cy++
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}
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DOWN -> {
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txt.setcc(cx*2+1, cy*2, 81, 9)
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cy--
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}
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LEFT -> {
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txt.setcc(cx*2+2, cy*2+1, 81, 9)
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cx++
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}
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RIGHT -> {
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txt.setcc(cx*2, cy*2+1, 81, 9)
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cx--
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}
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}
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goto solve_loop
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}
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pathstackptr++
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if pathstackptr==max_path_length {
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txt.print("stack overflow, path too long")
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return
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}
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@(celladdr(cx,cy)) |= WALKED
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txt.setcc(cx*2+1, cy*2+1, 81, 1)
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}
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}
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sub celladdr(ubyte cx, ubyte cy) -> uword {
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return cells+(numCellsHoriz as uword)*cy+cx
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}
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sub drawCell(ubyte cx, ubyte cy) {
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ubyte x = cx * 2 + 1
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ubyte y = cy * 2 + 1
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ubyte doors = @(celladdr(cx,cy))
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if doors & UP
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txt.setcc(x, y-1, ' ', EMPTYCOLOR)
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if doors & RIGHT
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txt.setcc(x+1, y, ' ', EMPTYCOLOR)
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if doors & DOWN
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txt.setcc(x, y+1, ' ', EMPTYCOLOR)
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if doors & LEFT
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txt.setcc(x-1, y, ' ', EMPTYCOLOR)
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if doors & STONE
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txt.setcc(x, y, 160, WALLCOLOR)
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else
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txt.setcc(x, y, 32, EMPTYCOLOR)
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if doors & WALKED
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txt.setcc(x, y, 81, 1)
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if doors & BACKTRACKED
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txt.setcc(x, y, 81, 2)
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}
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sub initialize() {
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sys.memset(cells, numCellsHoriz*numCellsVert, STONE)
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txt.fill_screen(160, WALLCOLOR)
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drawStartFinish()
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}
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sub drawStartFinish() {
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txt.setcc(startCx*2+1,startCy*2+1,sc:'s',5)
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txt.setcc(finishCx*2+1, finishCy*2+1, sc:'f', 13)
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}
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}
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