def add_noise(self): libtcod.heightmap_normalize(self.hm, 0, 1) self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.noise_set_type(self.noise, libtcod.NOISE_PERLIN) libtcod.heightmap_add_fbm(self.hm, self.noise, 1, 1, 1, 1, 8, 0.5, 0.5) libtcod.heightmap_normalize(self.hm, 0, 255)
def add_landmass(self): print 'Creating landmass....' t0 = libtcod.sys_elapsed_seconds() for i in range(int(game.WORLDMAP_WIDTH * 0.55)): radius = self.randomize('float', 50 * (1.0 - 0.7), 50 * (1.0 + 0.7), 3) x = self.randomize('int', 0, game.WORLDMAP_WIDTH, 3) y = self.randomize('int', 0, game.WORLDMAP_HEIGHT, 3) libtcod.heightmap_add_hill(game.heightmap, x, y, radius, 0.3) libtcod.heightmap_normalize(game.heightmap) libtcod.heightmap_add_fbm(game.heightmap, self.noise, 6.5, 6.5, 0, 0, 8.0, 1.0, 4.0) libtcod.heightmap_normalize(game.heightmap) t1 = libtcod.sys_elapsed_seconds() print ' done! (%.3f seconds)' % (t1 - t0)
def Percipitaion(preciphm, temphm): libtcod.heightmap_add(preciphm, 2) for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): temp = libtcod.heightmap_get_value(temphm, x, y) precip = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(preciphm, precip, 2, 2, 0, 0, 32, 1, 1) libtcod.heightmap_normalize(preciphm, 0.0, 1.0) return
def Percipitaion(preciphm): libtcod.heightmap_add(preciphm, 2) for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): if y > WORLD_HEIGHT/2 - WORLD_HEIGHT/10 and y < WORLD_HEIGHT/2 + WORLD_HEIGHT/10: val = y val = abs(y - WORLD_HEIGHT/2) libtcod.heightmap_set_value(preciphm, x, y, val/4) precip = libtcod.noise_new(2,libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(preciphm,precip ,8, 8, 0, 0, 32, 1, 1) libtcod.heightmap_normalize(preciphm, 0.0, 1.0) return
def generate_land(self,hm): print hm.w, hm.h #self.noise = perlin_noise.PerlinNoiseGenerator() #self.noise.generate_noise(self.w, self.h, 1, 16) #print str(self.noise.noise[1][1]) self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.5, 0.8) print "scale", str(libtcod.heightmap_get_value(hm, 1, 1)) self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.noise_set_type(self.noise, libtcod.NOISE_PERLIN) libtcod.heightmap_scale_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.5, 0.8) # self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) # libtcod.heightmap_add_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.8, 0.5) # libtcod.heightmap_normalize(hm, 0, 255) print "normalized", str(libtcod.heightmap_get_value(hm, 1, 1)) return hm
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 generate_land(self, hm): print hm.w, hm.h #self.noise = perlin_noise.PerlinNoiseGenerator() #self.noise.generate_noise(self.w, self.h, 1, 16) #print str(self.noise.noise[1][1]) self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.5, 0.8) print "scale", str(libtcod.heightmap_get_value(hm, 1, 1)) self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.noise_set_type(self.noise, libtcod.NOISE_PERLIN) libtcod.heightmap_scale_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.5, 0.8) # self.noise = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) # libtcod.heightmap_add_fbm(hm, self.noise, 1, 1, 0, 0, 8, 0.8, 0.5) # libtcod.heightmap_normalize(hm, 0, 255) print "normalized", str(libtcod.heightmap_get_value(hm, 1, 1)) return hm
def make_heightmap(size, seed): # Gradient generated by distance to the northeast corner (creates northeast ocean). gradient1 = lt.heightmap_new(size, size) for col in xrange(size): for row in xrange(size): distance = ((row - size) ** 2 + col ** 2) ** 0.5 lt.heightmap_set_value(gradient1, row, col, distance) lt.heightmap_clamp(gradient1, mi=0, ma=WORLD_SIZE) lt.heightmap_scale(gradient1, 2) # Similar gradient, but cube root (creates mountains around edge). gradient2 = lt.heightmap_new(size, size) for col in xrange(size): for row in xrange(size): distance = ((row - size) ** 2 + col ** 2) ** 0.33 lt.heightmap_set_value(gradient2, row, col, distance) lt.heightmap_clamp(gradient2, mi=0, ma=WORLD_SIZE / 6) lt.heightmap_scale(gradient2, 5) # Height map based on Perlin noise. heightmap = lt.heightmap_new(size, size) random = lt.random_new() if seed: random = lt.random_new_from_seed(seed) perlin = lt.noise_new(2, h=2, l=2, random=random) lt.heightmap_add_fbm(heightmap, perlin, mulx=3, muly=3, addx=0, addy=0, octaves=8, delta=50, scale=100) # Add in gradients. lt.heightmap_add_hm(heightmap, gradient1, heightmap) lt.heightmap_add_hm(heightmap, gradient2, heightmap) lt.heightmap_normalize(heightmap, mi=-100, ma=105) lt.heightmap_clamp(heightmap, mi=-50, ma=100) lt.heightmap_normalize(heightmap, mi=-100, ma=100) visualize(heightmap) return heightmap
def buildMap(hm) : libtcod.heightmap_add_fbm(hm,noise,3.83,3.83,400,0,4.93,1,0.35) libtcod.heightmap_normalize(hm)
def MasterWorldGen( ): #------------------------------------------------------- * MASTER GEN * ------------------------------------------------------------- print ' * World Gen START * ' starttime = time.time() #Heightmap hm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) for i in range(50): libtcod.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(200): libtcod.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 -' libtcod.heightmap_normalize(hm, 0.0, 1.0) noisehm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) noise2d = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(noisehm, noise2d, 4, 4, 0, 0, 32, 1, 1) libtcod.heightmap_normalize(noisehm, 0.0, 1.0) libtcod.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 -' libtcod.heightmap_rain_erosion(hm, WORLD_WIDTH * WORLD_HEIGHT, 0.07, 0, 0) print '- Erosion -' libtcod.heightmap_clamp(hm, 0.0, 1.0) #Temperature temp = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Temperature(temp, hm) libtcod.heightmap_normalize(temp, 0.0, 0.8) print '- Temperature Calculation -' #Precipitation preciphm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Percipitaion(preciphm, temp) libtcod.heightmap_normalize(preciphm, 0.0, 0.8) print '- Percipitaion Calculation -' #Drainage drainhm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) drain = libtcod.noise_new(2, libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(drainhm, drain, 2, 2, 0, 0, 32, 1, 1) libtcod.heightmap_normalize(drainhm, 0.0, 0.8) 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)] #100x100 array for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): World[x][y] = Tile(libtcod.heightmap_get_value(hm, x, y), libtcod.heightmap_get_value(temp, x, y), libtcod.heightmap_get_value(preciphm, x, y), libtcod.heightmap_get_value(drainhm, x, y), 0) print '- Tiles Initialized -' #Prosperity Prosperity(World) print '- Prosperity Calculation -' #Biome info to Tile for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): if World[x][y].height > 0.2: World[x][y].biomeID = 3 if randint(1, 10) < 3: World[x][y].biomeID = 5 if World[x][y].height > 0.4: World[x][y].biomeID = 14 if randint(1, 10) < 3: World[x][y].biomeID = 5 if World[x][y].height > 0.5: World[x][y].biomeID = 8 if randint(1, 10) < 3: World[x][y].biomeID = 14 if World[x][y].temp <= 0.5 and World[x][y].precip >= 0.5: World[x][y].biomeID = 5 if randint(1, 10) < 3: World[x][y].biomeID = 14 if World[x][y].temp >= 0.5 and World[x][y].precip >= 0.7: World[x][y].biomeID = 6 if World[x][y].precip >= 0.7 and World[x][ y].height > 0.2 and World[x][y].height <= 0.4: World[x][y].biomeID = 2 if World[x][y].temp > 0.75 and World[x][y].precip < 0.35: World[x][y].biomeID = 4 if World[x][y].temp <= 0.22 and World[x][y].height > 0.2: World[x][y].biomeID = randint(11, 13) if World[x][y].temp <= 0.3 and World[x][y].temp > 0.2 and World[x][ y].height > 0.2 and World[x][y].precip >= 0.6: World[x][y].biomeID = 7 if World[x][y].height > 0.75: World[x][y].biomeID = 9 if World[x][y].height > 0.999: World[x][y].biomeID = 10 if World[x][y].height <= 0.2: World[x][y].biomeID = 0 if World[x][y].height <= 0.1: World[x][y].biomeID = 0 print '- BiomeIDs Atributed -' #River Gen for x in range(5): RiverGen(World) print '- River Gen -' #Free Heightmaps libtcod.heightmap_delete(hm) libtcod.heightmap_delete(temp) libtcod.heightmap_delete(noisehm) print ' * Biomes/Rivers Sorted *' return World
def MasterWorldGen(): #------------------------------------------------------- * MASTER GEN * ------------------------------------------------------------- print ' * World Gen START * ' starttime = time.time() #Heightmap hm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) for i in range(50): libtcod.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(200): libtcod.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 -' libtcod.heightmap_normalize(hm, 0.0, 1.0) noisehm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) noise2d = libtcod.noise_new(2,libtcod.NOISE_DEFAULT_HURST, libtcod.NOISE_DEFAULT_LACUNARITY) libtcod.heightmap_add_fbm(noisehm, noise2d,4, 4, 0, 0, 64, 1, 1) libtcod.heightmap_normalize(noisehm, 0.0, 1.0) libtcod.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 -' libtcod.heightmap_rain_erosion(hm, WORLD_WIDTH*WORLD_HEIGHT ,0.07,0,0) print '- Erosion -' libtcod.heightmap_clamp(hm, 0.0, 1.0) #Temperature temp = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Temperature(temp,hm) libtcod.heightmap_normalize(temp, 0.0, 0.8) print '- Temperature Calculation -' #Precipitation preciphm = libtcod.heightmap_new(WORLD_WIDTH, WORLD_HEIGHT) Percipitaion(preciphm) libtcod.heightmap_normalize(preciphm, 0.0, 0.8) print '- Percipitaion Calculation -' # VOLCANISM - RARE AT SEA FOR NEW ISLANDS (?) RARE AT MOUNTAINS > 0.9 (?) RARE AT TECTONIC BORDERS (?) #Initialize Tiles with Map values World = [[0 for y in range(WORLD_HEIGHT)] for x in range(WORLD_WIDTH)] #100x100 array for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): World[x][y] = Tile(libtcod.heightmap_get_value(hm, x, y), libtcod.heightmap_get_value(temp, x, y), libtcod.heightmap_get_value(preciphm, x, y), 0) print '- Tiles Initialized -' # - Biome info to Tiles - for x in xrange(WORLD_WIDTH): for y in xrange(WORLD_HEIGHT): if World[x][y].height > 0.2: World[x][y].biomeID = 3 if randint(1,10) < 3: World[x][y].biomeID = 5 if World[x][y].height > 0.4: World[x][y].biomeID = 14 if randint(1,10) < 3: World[x][y].biomeID = 5 if World[x][y].height > 0.5: World[x][y].biomeID = 8 if randint(1,10) < 3: World[x][y].biomeID = 14 if World[x][y].temp <= 0.5 and World[x][y].precip >= 0.5: World[x][y].biomeID = 5 if randint(1,10) < 3: World[x][y].biomeID = 14 if World[x][y].temp >= 0.5 and World[x][y].precip >= 0.7: World[x][y].biomeID = 6 if World[x][y].precip >= 0.7 and World[x][y].height > 0.2 and World[x][y].height <= 0.4: World[x][y].biomeID = 2 if World[x][y].temp > 0.75 and World[x][y].precip < 0.35: World[x][y].biomeID = 4 if World[x][y].temp <= 0.22 and World[x][y].height > 0.2: World[x][y].biomeID = randint(11,13) if World[x][y].temp <= 0.3 and World[x][y].temp > 0.2 and World[x][y].height > 0.2 and World[x][y].precip >= 0.6: World[x][y].biomeID = 7 if World[x][y].height > 0.75: World[x][y].biomeID = 9 if World[x][y].height > 0.999: World[x][y].biomeID = 10 if World[x][y].height <= 0.2: World[x][y].biomeID = 0 if World[x][y].height <= 0.1: World[x][y].biomeID = 0 print '- BiomeIDs Atributed -' #River Gen for x in range(2): RiverGen(hm, World) print '- River Gen -' #Free Heightmaps libtcod.heightmap_delete(hm) libtcod.heightmap_delete(temp) libtcod.heightmap_delete(noisehm) elapsed_time = time.time() - starttime print ' * World Gen DONE * in: ',elapsed_time,' seconds' return World