def test_heightmap(): hmap = libtcodpy.heightmap_new(16, 16) repr(hmap) noise = libtcodpy.noise_new(2) # basic operations libtcodpy.heightmap_set_value(hmap, 0, 0, 1) libtcodpy.heightmap_add(hmap, 1) libtcodpy.heightmap_scale(hmap, 1) libtcodpy.heightmap_clear(hmap) libtcodpy.heightmap_clamp(hmap, 0, 0) libtcodpy.heightmap_copy(hmap, hmap) libtcodpy.heightmap_normalize(hmap) libtcodpy.heightmap_lerp_hm(hmap, hmap, hmap, 0) libtcodpy.heightmap_add_hm(hmap, hmap, hmap) libtcodpy.heightmap_multiply_hm(hmap, hmap, hmap) # modifying the heightmap libtcodpy.heightmap_add_hill(hmap, 0, 0, 4, 1) libtcodpy.heightmap_dig_hill(hmap, 0, 0, 4, 1) libtcodpy.heightmap_rain_erosion(hmap, 1, 1, 1) libtcodpy.heightmap_kernel_transform(hmap, 3, [-1, 1, 0], [0, 0, 0], [.33, .33, .33], 0, 1) libtcodpy.heightmap_add_voronoi(hmap, 10, 3, [1,3,5]) libtcodpy.heightmap_add_fbm(hmap, noise, 1, 1, 1, 1, 4, 1, 1) libtcodpy.heightmap_scale_fbm(hmap, noise, 1, 1, 1, 1, 4, 1, 1) libtcodpy.heightmap_dig_bezier(hmap, [0, 16, 16, 0], [0, 0, 16, 16], 1, 1, 1, 1) # read data libtcodpy.heightmap_get_value(hmap, 0, 0) libtcodpy.heightmap_get_interpolated_value(hmap, 0, 0) libtcodpy.heightmap_get_slope(hmap, 0, 0) libtcodpy.heightmap_get_normal(hmap, 0, 0, 0) libtcodpy.heightmap_count_cells(hmap, 0, 0) libtcodpy.heightmap_has_land_on_border(hmap, 0) libtcodpy.heightmap_get_minmax(hmap) libtcodpy.noise_delete(noise) libtcodpy.heightmap_delete(hmap)
def test_heightmap(): hmap = libtcodpy.heightmap_new(16, 16) repr(hmap) noise = libtcodpy.noise_new(2) # basic operations libtcodpy.heightmap_set_value(hmap, 0, 0, 1) libtcodpy.heightmap_add(hmap, 1) libtcodpy.heightmap_scale(hmap, 1) libtcodpy.heightmap_clear(hmap) libtcodpy.heightmap_clamp(hmap, 0, 0) libtcodpy.heightmap_copy(hmap, hmap) libtcodpy.heightmap_normalize(hmap) libtcodpy.heightmap_lerp_hm(hmap, hmap, hmap, 0) libtcodpy.heightmap_add_hm(hmap, hmap, hmap) libtcodpy.heightmap_multiply_hm(hmap, hmap, hmap) # modifying the heightmap libtcodpy.heightmap_add_hill(hmap, 0, 0, 4, 1) libtcodpy.heightmap_dig_hill(hmap, 0, 0, 4, 1) libtcodpy.heightmap_rain_erosion(hmap, 1, 1, 1) libtcodpy.heightmap_kernel_transform(hmap, 3, [-1, 1, 0], [0, 0, 0], [.33, .33, .33], 0, 1) libtcodpy.heightmap_add_voronoi(hmap, 10, 3, [1, 3, 5]) libtcodpy.heightmap_add_fbm(hmap, noise, 1, 1, 1, 1, 4, 1, 1) libtcodpy.heightmap_scale_fbm(hmap, noise, 1, 1, 1, 1, 4, 1, 1) libtcodpy.heightmap_dig_bezier(hmap, [0, 16, 16, 0], [0, 0, 16, 16], 1, 1, 1, 1) # read data libtcodpy.heightmap_get_value(hmap, 0, 0) libtcodpy.heightmap_get_interpolated_value(hmap, 0, 0) libtcodpy.heightmap_get_slope(hmap, 0, 0) libtcodpy.heightmap_get_normal(hmap, 0, 0, 0) libtcodpy.heightmap_count_cells(hmap, 0, 0) libtcodpy.heightmap_has_land_on_border(hmap, 0) libtcodpy.heightmap_get_minmax(hmap) libtcodpy.noise_delete(noise) libtcodpy.heightmap_delete(hmap)
def MasterWorldGen(): # ------------------------------------------------------- * MASTER GEN * ------------------------------------------------------------- print(" * World Gen START * ") starttime = time.time() # Heightmap hm = tcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) for i in range(250): tcod.heightmap_add_hill( hm, randint(WORLD_WIDTH / 10, WORLD_WIDTH - WORLD_WIDTH / 10), randint(WORLD_HEIGHT / 10, WORLD_HEIGHT - WORLD_HEIGHT / 10), randint(12, 16), randint(6, 10), ) print("- Main Hills -") for i in range(1000): tcod.heightmap_add_hill( hm, randint(WORLD_WIDTH / 10, WORLD_WIDTH - WORLD_WIDTH / 10), randint(WORLD_HEIGHT / 10, WORLD_HEIGHT - WORLD_HEIGHT / 10), randint(2, 4), randint(6, 10), ) print("- Small Hills -") tcod.heightmap_normalize(hm, 0.0, 1.0) noisehm = tcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) noise2d = tcod.noise_new( 2, tcod.NOISE_DEFAULT_HURST, tcod.NOISE_DEFAULT_LACUNARITY ) # tcod.heightmap_add_fbm(noisehm, noise2d,6, 6, 0, 0, 32, 1, 1) tcod.heightmap_normalize(noisehm, 0.0, 1.0) # tcod.heightmap_multiply_hm(hm, noisehm, hm) print("- Apply Simplex -") PoleGen(hm, 0) print("- South Pole -") PoleGen(hm, 1) print("- North Pole -") TectonicGen(hm, 0) TectonicGen(hm, 1) print("- Tectonic Gen -") tcod.heightmap_rain_erosion(hm, WORLD_WIDTH * WORLD_HEIGHT, 0.07, 0, 0) print("- Erosion -") tcod.heightmap_clamp(hm, 0.0, 1.0) # Temperature temp = tcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Temperature(temp, hm) tcod.heightmap_normalize(temp, 0.0, 1.0) print("- Temperature Calculation -") # Precipitation preciphm = tcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Percipitaion(preciphm, temp) tcod.heightmap_normalize(preciphm, 0.0, 1.0) print("- Percipitaion Calculation -") # Drainage drainhm = tcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) drain = tcod.noise_new( 2, tcod.NOISE_DEFAULT_HURST, tcod.NOISE_DEFAULT_LACUNARITY ) # tcod.heightmap_add_fbm(drainhm,drain ,2, 2, 0, 0, 32, 1, 1) tcod.heightmap_normalize(drainhm, 0.0, 1.0) print("- Drainage Calculation -") # VOLCANISM - RARE AT SEA FOR NEW ISLANDS (?) RARE AT MOUNTAINS > 0.9 (?) RARE AT TECTONIC BORDERS (?) elapsed_time = time.time() - starttime print(" * World Gen DONE * in: ", elapsed_time, " seconds") # Initialize Tiles with Map values World = [[0 for y in range(WORLD_HEIGHT)] for x in range(WORLD_WIDTH)] for x in range(WORLD_WIDTH): for y in range(WORLD_HEIGHT): World[x][y] = Tile( tcod.heightmap_get_value(hm, x, y), tcod.heightmap_get_value(temp, x, y), tcod.heightmap_get_value(preciphm, x, y), tcod.heightmap_get_value(drainhm, x, y), 0, ) print("- Tiles Initialized -") # Prosperity Prosperity(World) print("- Prosperity Calculation -") # Biome info to Tile for x in range(WORLD_WIDTH): for y in range(WORLD_HEIGHT): if ( World[x][y].precip >= 0.10 and World[x][y].precip < 0.33 and World[x][y].drainage < 0.5 ): World[x][y].biomeID = 3 if randint(1, 2) == 2: World[x][y].biomeID = 16 if World[x][y].precip >= 0.10 and World[x][y].precip > 0.33: World[x][y].biomeID = 2 if World[x][y].precip >= 0.66: World[x][y].biomeID = 1 if ( World[x][y].precip >= 0.33 and World[x][y].precip < 0.66 and World[x][y].drainage >= 0.33 ): World[x][y].biomeID = 15 if randint(1, 5) == 5: World[x][y].biomeID = 5 if ( World[x][y].temp > 0.2 and World[x][y].precip >= 0.66 and World[x][y].drainage > 0.33 ): World[x][y].biomeID = 5 if World[x][y].precip >= 0.75: World[x][y].biomeID = 6 if randint(1, 5) == 5: World[x][y].biomeID = 15 if ( World[x][y].precip >= 0.10 and World[x][y].precip < 0.33 and World[x][y].drainage >= 0.5 ): World[x][y].biomeID = 16 if randint(1, 2) == 2: World[x][y].biomeID = 14 if World[x][y].precip < 0.10: World[x][y].biomeID = 4 if World[x][y].drainage > 0.5: World[x][y].biomeID = 16 if randint(1, 2) == 2: World[x][y].biomeID = 14 if World[x][y].drainage >= 0.66: World[x][y].biomeID = 8 if World[x][y].height <= 0.2: World[x][y].biomeID = 0 if World[x][y].temp <= 0.2 and World[x][y].height > 0.15: World[x][y].biomeID = randint(11, 13) if World[x][y].height > 0.6: World[x][y].biomeID = 9 if World[x][y].height > 0.9: World[x][y].biomeID = 10 print("- BiomeIDs Atributed -") # River Gen for x in range(1): RiverGen(World) print("- River Gen -") # Free Heightmaps tcod.heightmap_delete(hm) tcod.heightmap_delete(temp) tcod.heightmap_delete(noisehm) print(" * Biomes/Rivers Sorted *") return World