hedgewars/uLandGenMaze.pas
author Wuzzy <Wuzzy2@mail.ru>
Fri, 09 Mar 2018 19:05:59 +0100
changeset 13145 5083fb0a2992
parent 11051 3996500fd1e5
child 15929 128ace913837
permissions -rw-r--r--
A Classic Fairytale: Harden all missions against missing campaign variables in team file and assume default values This assumes the worst case in which the team file is missing all campaign variables except Progress. This has been successfully tested with all 10 missions and still generates a logical storyline. By default, the game assumes: - The cyborg's offer in mission 2 was refused - The traitor in mission 5 was killed As a consequence, missions 8 and 10 use the princessScene cut scene.

{$INCLUDE "options.inc"}

unit uLandGenMaze;

interface

procedure GenMaze;

implementation

uses uRandom, uLandOutline, uLandTemplates, uVariables, uFloat, uConsts, uLandGenTemplateBased, uUtils;

type direction = record x, y: LongInt; end;
const DIR_N: direction = (x: 0; y: -1);
    DIR_E: direction = (x: 1; y: 0);
    DIR_S: direction = (x: 0; y: 1);
    DIR_W: direction = (x: -1; y: 0);

operator = (const a, b: direction) c: Boolean;
begin
    c := (a.x = b.x) and (a.y = b.y);
end;

const small_cell_size = 128;
    medium_cell_size = 192;
    large_cell_size = 256;
    braidness = 10;

type
   cell_t = record x,y         : LongInt
        end;

var x, y               : LongInt;
    cellsize               : LongInt; //selected by the user in the gui
    seen_cells_x, seen_cells_y : LongInt; //number of cells that can be visited by the generator, that is every second cell in x and y direction. the cells between there are walls that will be removed when we move from one cell to another
    num_edges_x, num_edges_y   : LongInt; //number of resulting edges that need to be vertexificated
    num_cells_x, num_cells_y   : LongInt; //actual number of cells, depending on cell size


    seen_list              : array of array of LongInt;
    xwalls             : array of array of Boolean;
    ywalls             : array of array of Boolean;
    x_edge_list            : array of array of Boolean;
    y_edge_list            : array of array of Boolean;
    maze               : array of array of Boolean;

    pa                 : TPixAr;
    num_vertices           : LongInt;
    off_y              : LongInt;
    num_steps              : LongInt;
    current_step           : LongInt;

    step_done              : array of Boolean;

    done               : Boolean;

{   last_cell              : array 0..3 of record x, y :LongInt ; end;
    came_from              : array of array of record x, y: LongInt; end;
    came_from_pos          : array of LongInt;
}
    last_cell : array of cell_t;
    came_from : array of array of cell_t;
    came_from_pos: array of LongInt;

    maze_inverted                      : Boolean;

function when_seen(x: LongInt; y: LongInt): LongInt;
begin
if (x < 0) or (x >= seen_cells_x) or (y < 0) or (y >= seen_cells_y) then
    when_seen := current_step
else
    when_seen := seen_list[x, y];
end;

function is_x_edge(x, y: LongInt): Boolean;
begin
if (x < 0) or (x > num_edges_x) or (y < 0) or (y > num_cells_y) then
    is_x_edge := false
else
    is_x_edge := x_edge_list[x, y];
end;

function is_y_edge(x, y: LongInt): Boolean;
begin
if (x < 0) or (x > num_cells_x) or (y < 0) or (y > num_edges_y) then
    is_y_edge := false
else
    is_y_edge := y_edge_list[x, y];
end;

procedure see_cell;
var dir: direction;
    tries: LongInt;
    x, y: LongInt;
    found_cell: Boolean;
    next_dir_clockwise: Boolean;

begin
x := last_cell[current_step].x;
y := last_cell[current_step].y;
seen_list[x, y] := current_step;
case GetRandom(4) of
    0: dir := DIR_N;
    1: dir := DIR_E;
    2: dir := DIR_S;
    3: dir := DIR_W;
end;
tries := 0;
found_cell := false;
if getrandom(2) = 1 then
    next_dir_clockwise := true
else
    next_dir_clockwise := false;

while (tries < 5) and (not found_cell) do
begin
    if when_seen(x + dir.x, y + dir.y) = current_step then //we are seeing ourselves, try another direction
    begin
        //we have already seen the target cell, decide if we should remove the wall anyway
        //(or put a wall there if maze_inverted, but we are not doing that right now)
        if (not maze_inverted) and (GetRandom(braidness) = 0) then
        //or just warn that inverted+braid+indestructible terrain != good idea
        begin
            case dir.x of

                -1:
                if x > 0 then
                    ywalls[x-1, y] := false;
                1:
                if x < seen_cells_x - 1 then
                    ywalls[x, y] := false;
            end;
            case dir.y of
                -1:
                if y > 0 then
                    xwalls[x, y-1] := false;
                1:
                if y < seen_cells_y - 1 then
                    xwalls[x, y] := false;
            end;
        end;
        if next_dir_clockwise then
        begin
            if dir = DIR_N then
                dir := DIR_E
            else if dir = DIR_E then
                dir := DIR_S
            else if dir = DIR_S then
                dir := DIR_W
            else
                dir := DIR_N;
        end
        else
        begin
            if dir = DIR_N then
                dir := DIR_W
            else if dir = DIR_E then
                dir := DIR_N
            else if dir = DIR_S then
                dir := DIR_E
            else
                dir := DIR_S;
        end
    end
    else if when_seen(x + dir.x, y + dir.y) = -1 then //cell was not seen yet, go there
        begin
        case dir.y of
            -1: xwalls[x, y-1] := false;
            1: xwalls[x, y] := false;
        end;
        case dir.x of
            -1: ywalls[x-1, y] := false;
            1: ywalls[x, y] := false;
        end;
        last_cell[current_step].x := x+dir.x;
        last_cell[current_step].y := y+dir.y;
        came_from_pos[current_step] := came_from_pos[current_step] + 1;
        came_from[current_step, came_from_pos[current_step]].x := x;
        came_from[current_step, came_from_pos[current_step]].y := y;
        found_cell := true;
        end
    else //we are seeing someone else, quit
        begin
        step_done[current_step] := true;
        found_cell := true;
        end;

    tries := tries + 1;
end;
if not found_cell then
    begin
    last_cell[current_step].x := came_from[current_step, came_from_pos[current_step]].x;
    last_cell[current_step].y := came_from[current_step, came_from_pos[current_step]].y;
    came_from_pos[current_step] := came_from_pos[current_step] - 1;

    if came_from_pos[current_step] >= 0 then
        see_cell()

    else
        step_done[current_step] := true;
    end;
end;

procedure add_vertex(x, y: LongInt);
var tmp_x, tmp_y, nx, ny: LongInt;
begin
    if x = NTPX then
    begin
        if pa.ar[num_vertices - 6].x = NTPX then
        begin
            num_vertices := num_vertices - 6;
        end
        else
        begin
            pa.ar[num_vertices].x := NTPX;
            pa.ar[num_vertices].y := 0;
        end
    end
    else
    begin
        if maze_inverted or (x mod 2 = 0) then
            tmp_x := cellsize
        else
            tmp_x := cellsize * 2 div 3;

        if maze_inverted or (y mod 2 = 0) then
            tmp_y := cellsize
        else
            tmp_y := cellsize * 2 div 3;

        nx:= (x-1)*cellsize + tmp_x;
        ny:= (y-1)*cellsize + tmp_y + off_y;

        if num_vertices > 2 then
            if ((pa.ar[num_vertices - 2].x = pa.ar[num_vertices - 1].x) and (pa.ar[num_vertices - 1].x = nx))
                or ((pa.ar[num_vertices - 2].y = pa.ar[num_vertices - 1].y) and (pa.ar[num_vertices - 1].y = ny))
                then
                dec(num_vertices);

        pa.ar[num_vertices].x := nx;
        pa.ar[num_vertices].y := ny;
    end;

    num_vertices := num_vertices + 1;
end;

procedure add_edge(x, y: LongInt; dir: direction);
var i: LongInt;
begin
if dir = DIR_N then
    begin
    dir := DIR_W
    end
else if dir = DIR_E then
    begin
    dir := DIR_N
    end
else if dir = DIR_S then
    begin
    dir := DIR_E
    end
else
    begin
    dir := DIR_S;
    end;

for i := 0 to 3 do
    begin
    if dir = DIR_N then
        dir := DIR_E
    else if dir = DIR_E then
        dir := DIR_S
    else if dir = DIR_S then
        dir := DIR_W
    else
        dir := DIR_N;

    if (dir = DIR_N) and is_x_edge(x, y) then
        begin
            x_edge_list[x, y] := false;
            add_vertex(x+1, y);
            add_edge(x, y-1, DIR_N);
            break;
        end;

    if (dir = DIR_E) and is_y_edge(x+1, y) then
        begin
            y_edge_list[x+1, y] := false;
            add_vertex(x+2, y+1);
            add_edge(x+1, y, DIR_E);
            break;
        end;

    if (dir = DIR_S) and is_x_edge(x, y+1) then
        begin
            x_edge_list[x, y+1] := false;
            add_vertex(x+1, y+2);
            add_edge(x, y+1, DIR_S);
            break;
        end;

    if (dir = DIR_W) and is_y_edge(x, y) then
        begin
            y_edge_list[x, y] := false;
            add_vertex(x, y+1);
            add_edge(x-1, y, DIR_W);
            break;
        end;
    end;

end;

procedure GenMaze;
var i: Longword;
begin
case cTemplateFilter of
    0: begin
       cellsize := small_cell_size;
       maze_inverted := false;
       minDistance:= max(cFeatureSize*8,32);
       dabDiv:= 150;
       end;
    1: begin
       cellsize := medium_cell_size;
       minDistance:= max(cFeatureSize*6,20);
       maze_inverted := false;
       dabDiv:= 100;
       end;
    2: begin
       cellsize := large_cell_size;
       minDistance:= max(cFeatureSize*5,12);
       maze_inverted := false;
       dabDiv:= 90;
       end;
    3: begin
       cellsize := small_cell_size;
       minDistance:= max(cFeatureSize*8,32);
       maze_inverted := true;
       dabDiv:= 130;
       end;
    4: begin
       cellsize := medium_cell_size;
       minDistance:= max(cFeatureSize*6,20);
       maze_inverted := true;
       dabDiv:= 100;
       end;
    5: begin
       cellsize := large_cell_size;
       minDistance:= max(cFeatureSize*5,12);
       maze_inverted := true;
       dabDiv:= 85;
       end;
    end;

num_cells_x := LAND_WIDTH div cellsize;
if not odd(num_cells_x) then
    num_cells_x := num_cells_x - 1; //needs to be odd

num_cells_y := LAND_HEIGHT div cellsize;
if not odd(num_cells_y) then
    num_cells_y := num_cells_y - 1;

num_edges_x := num_cells_x - 1;
num_edges_y := num_cells_y - 1;

seen_cells_x := num_cells_x div 2;
seen_cells_y := num_cells_y div 2;

if maze_inverted then
    num_steps := 3 //TODO randomize, between 3 and 5?
else
    num_steps := 1;

SetLength(step_done, num_steps);
SetLength(last_cell, num_steps);
SetLength(came_from_pos, num_steps);
SetLength(came_from, num_steps, num_cells_x*num_cells_y);

done := false;

for current_step := 0 to num_steps - 1 do
    begin
    step_done[current_step] := false;
    came_from_pos[current_step] := 0;
    end;

current_step := 0;


SetLength(seen_list, seen_cells_x, seen_cells_y);
SetLength(xwalls, seen_cells_x, seen_cells_y - 1);
SetLength(ywalls, seen_cells_x - 1, seen_cells_y);
SetLength(x_edge_list, num_edges_x, num_cells_y);
SetLength(y_edge_list, num_cells_x, num_edges_y);
SetLength(maze, num_cells_x, num_cells_y);


num_vertices := 0;

playHeight := num_cells_y * cellsize;
playWidth := num_cells_x * cellsize;
off_y := LAND_HEIGHT - playHeight;

for x := 0 to playWidth do
    for y := 0 to off_y - 1 do
        Land[y, x] := 0;

for x := 0 to playWidth do
    for y := off_y to LAND_HEIGHT - 1 do
        Land[y, x] := lfBasic;

for y := 0 to num_cells_y - 1 do
    for x := 0 to num_cells_x - 1 do
        maze[x, y] := false;

for x := 0 to seen_cells_x - 1 do
    for y := 0 to seen_cells_y - 2 do
        xwalls[x, y] := true;

for x := 0 to seen_cells_x - 2 do
    for y := 0 to seen_cells_y - 1 do
        ywalls[x, y] := true;

for x := 0 to seen_cells_x - 1 do
    for y := 0 to seen_cells_y - 1 do
        seen_list[x, y] := -1;

for x := 0 to num_edges_x - 1 do
    for y := 0 to num_cells_y - 1 do
        x_edge_list[x, y] := false;

for x := 0 to num_cells_x - 1 do
    for y := 0 to num_edges_y - 1 do
        y_edge_list[x, y] := false;

for current_step := 0 to num_steps-1 do
    begin
    x := GetRandom(seen_cells_x - 1) div LongWord(num_steps);
    last_cell[current_step].x := x + current_step * seen_cells_x div num_steps;
    last_cell[current_step].y := GetRandom(seen_cells_y);
end;

while not done do
    begin
    done := true;
    for current_step := 0 to num_steps-1 do
        begin
        if not step_done[current_step] then
            begin
            see_cell;
            done := false;
            end;
        end;
    end;

for x := 0 to seen_cells_x - 1 do
    for y := 0 to seen_cells_y - 1 do
        if seen_list[x, y] > -1 then
            maze[(x+1)*2-1, (y+1)*2-1] := true;

for x := 0 to seen_cells_x - 1 do
    for y := 0 to seen_cells_y - 2 do
        if not xwalls[x, y] then
            maze[x*2 + 1, y*2 + 2] := true;


for x := 0 to seen_cells_x - 2 do
     for y := 0 to seen_cells_y - 1 do
        if not ywalls[x, y] then
            maze[x*2 + 2, y*2 + 1] := true;

for x := 0 to num_edges_x - 1 do
    for y := 0 to num_cells_y - 1 do
        if maze[x, y] xor maze[x+1, y] then
            x_edge_list[x, y] := true
        else
            x_edge_list[x, y] := false;

for x := 0 to num_cells_x - 1 do
    for y := 0 to num_edges_y - 1 do
        if maze[x, y] xor maze[x, y+1] then
            y_edge_list[x, y] := true
        else
            y_edge_list[x, y] := false;

for x := 0 to num_edges_x - 1 do
    for y := 0 to num_cells_y - 1 do
        if x_edge_list[x, y] then
            begin
            x_edge_list[x, y] := false;
            add_vertex(x+1, y+1);
            add_vertex(x+1, y);
            add_edge(x, y-1, DIR_N);
            add_vertex(NTPX, 0);
            end;

pa.count := num_vertices;

leftX:= 0;
rightX:= playWidth;
topY:= off_y;

// fill point
pa.ar[pa.Count].x:= 1;
pa.ar[pa.Count].y:= 1 + off_y;

{
for i:= 0 to pa.Count - 1 do
    begin
        system.writeln(pa.ar[i].x, ', ', pa.ar[i].y);
    end;
}

// divide while it divides
repeat
    i:= pa.Count;
    DivideEdges(1, pa)
until i = pa.Count;

// make it smooth
BezierizeEdge(pa, _0_2);

DrawEdge(pa, 0);

if maze_inverted then
    FillLand(1, 1 + off_y, 0, 0)
else
    begin
    x := 0;
    while Land[cellsize div 2 + cellsize + off_y, x] = lfBasic do
        x := x + 1;
    while Land[cellsize div 2 + cellsize + off_y, x] = 0 do
        x := x + 1;
    FillLand(x+1, cellsize div 2 + cellsize + off_y, 0, 0);
    end;

MaxHedgehogs:= 32;
if (GameFlags and gfDisableGirders) <> 0 then
    hasGirders:= false
else
    hasGirders := true;

hasBorder := false;
end;

end.