이미지 숨기기


15

이 도전에서는 사진 내에서 특정 카메라 (실제 카메라로 촬영)를 찾아야합니다.

(R, G, B) 튜플과 이미지가 전달되고 이미지에서 주어진 RGB 색상과 일치하는 점 (x, y)을 반환해야합니다 . 이미지에 색상과 일치하는 여러 점이있을 수 있습니다. 1 만 찾으면됩니다.

문제는 당신이 그것을 할 필요가있다 가능한 몇 픽셀로 읽는 동안 . 점수는 모든 테스트 사례에서 읽은 총 픽셀 수입니다.

원하는 경우 픽셀에서 처리하지 않는 한 전체 이미지를 RGB 값의 배열로 읽을 수 있습니다. 나는 효율성을 위해 이것을 순수하게 허용합니다. 예를 들어, 파이썬에서는 list(Image.open("image_name+".jpg").convert("RGB").getdata())괜찮습니다.

하드 코딩 위치는 허용되지 않습니다. 알고리즘은 아래 나열된 테스트 사례 이상으로 잘 작동해야합니다. 테스트 사례간에 데이터를 저장할 수 없습니다. <10이미지에 드물게 ( ) 나타나는 RGB 값을 선택했습니다 (알고리즘에 차이가있는 경우). 알고리즘에서 임의성을 사용하는 경우 점수가 일정하도록 시드를 설정하십시오.

이미지는 Github 에서 찾을 수 있습니다

테스트 사례 :

image_name: 
(r, g, b) [all possible answers]

barn:
(143,91,33) [(887,1096),(2226,1397),(2007,1402),(2161,1508),(1187,1702)]
(53,35,59) [(1999,1260)]
(20,24,27) [(1328,1087),(154,1271)]
(167,148,176) [(1748,1204)]
(137,50,7) [(596,1498)]
(116,95,94) [(1340,1123)]
(72,49,59) [(1344,857),(1345,858),(1380,926),(1405,974),(1480,1117)]
(211,163,175) [(1963,745)]
(30,20,0) [(1609,1462),(1133,1477),(1908,1632)]
(88,36,23) [(543,1494),(431,1575)]
daisy:
(21,57,91) [(1440,1935),(2832,2090),(2232,2130),(1877,2131),(1890,2132)]
(201,175,140) [(1537,1749),(2319,1757)]
(169,160,0) [(2124,759)]
(113,123,114) [(1012,994),(2134,1060),(1803,1183),(1119,1335)]
(225,226,231) [(3207,829),(3256,889),(3257,889),(1434,981),(2599,1118),(2656,1348),(2656,1351)]
(17,62,117) [(2514,3874),(2336,3885)]
(226,225,204) [(3209,812)]
(119,124,146) [(2151,974),(2194,1021),(2194,1022),(2202,1034),(2812,1500)]
(2,63,120) [(2165,3881),(2326,3882),(2330,3882),(2228,3887)]
(200,167,113) [(1453,1759)]
dandelion:
(55,2,46) [(667,825),(668,825)]
(95,37,33) [(1637,1721),(1625,1724),(1405,1753),(2026,2276),(2016,2298)]
(27,41,50) [(1267,126),(424,519),(2703,1323),(1804,3466)]
(58,92,129) [(2213,3274)]
(136,159,105) [(1300,2363),(2123,2645),(1429,3428),(1430,3432),(1417,3467),(1393,3490),(1958,3493)]
(152,174,63) [(2256,2556)]
(78,49,19) [(2128,2836)]
(217,178,205) [(2736,3531)]
(69,95,130) [(870,305),(493,460),(2777,1085),(2791,1292),(2634,3100)]
(150,171,174) [(2816,1201),(2724,2669),(1180,2706),(1470,3215),(1471,3215)]
gerbera:
(218,186,171) [(4282,1342)]
(180,153,40) [(4596,1634),(4369,1682),(4390,1708),(4367,1750)]
(201,179,119) [(4282,1876),(4479,1928)]
(116,112,149) [(5884,252),(4168,371),(4169,372),(4164,384),(5742,576)]
(222,176,65) [(4232,1548)]
(108,129,156) [(5341,3574),(5339,3595),(5302,3734)]
(125,99,48) [(4548,1825),(4136,1932),(5054,2013),(5058,2023),(5058,2035),(5055,2050),(5031,2073)]
(170,149,32) [(4461,1630),(4520,1640)]
(156,185,203) [(3809,108)]
(103,67,17) [(4844,1790)]
hot-air:
(48,21,36) [(1992,1029),(2005,1030),(2015,1034),(2018,1036)]
(104,65,36) [(3173,1890),(3163,1893)]
(169,89,62) [(4181,931),(4210,938),(4330,1046),(4171,1056),(3117,1814)]
(68,59,60) [(1872,220),(1874,220),(1878,220),(1696,225),(3785,429)]
(198,96,74) [(4352,1057)]
(136,43,53) [(1700,931)]
(82,42,32) [(4556,961),(4559,973),(4563,989),(4563,990),(4441,1004),(4387,1126),(4378,1128)]
(192,132,72) [(1399,900),(3105,1822),(3104,1824),(3105,1824),(3107,1826),(3107,1827),(3104,1839),(3119,1852)]
(146,21,63) [(1716,993)]
(125,64,36) [(4332,937)]
in-input:
(204,90,1) [(1526,1997),(1385,2145),(4780,2807),(4788,3414)]
(227,163,53) [(1467,1739),(2414,1925),(2441,2198),(134,2446)]
(196,179,135) [(3770,2740),(1110,3012),(3909,3216),(1409,3263),(571,3405)]
(208,59,27) [(1134,1980),(4518,2108),(4515,2142)]
(149,70,1) [(4499,1790),(2416,2042),(1338,2150),(3731,2408),(3722,2409),(4400,3618)]
(168,3,7) [(987,402),(951,432),(1790,1213),(1790,1214),(1848,1217),(4218,1840),(4344,1870),(1511,1898)]
(218,118,4) [(3857,1701),(1442,1980),(1411,2156),(25,2606)]
(127,153,4) [(3710,2813)]
(224,230,246) [(2086,160),(2761,222),(4482,1442)]
(213,127,66) [(4601,1860),(4515,2527),(4757,2863)]
klatschmohn:
(170,133,19) [(1202,2274),(1202,2275),(957,2493),(1034,2633),(3740,3389),(3740,3391),(3683,3439)]
(162,92,4) [(489,2854)]
(159,175,104) [(3095,2475),(3098,2481)]
(199,139,43) [(1956,3055)]
(171,169,170) [(3669,1487),(3674,1490),(3701,1507)]
(184,115,58) [(1958,2404)]
(228,169,5) [(1316,2336),(1317,2336)]
(179,165,43) [(3879,2380),(1842,2497),(1842,2498)]
(67,21,6) [(1959,2197),(2157,2317),(2158,2317),(2158,2318),(2116,2373)]
(213,100,106) [(1303,1816)]
tajinaste-rojo:
(243,56,99) [(1811,2876),(1668,4141),(2089,4518),(1981,4732),(1659,4778),(2221,5373),(1779,5598),(2210,5673),(2373,5860)]
(147,157,210) [(1835,1028),(1431,3358)]
(114,37,19) [(1792,3572),(1818,3592)]
(108,117,116) [(2772,4722),(1269,5672),(2512,5811),(2509,5830),(2186,5842),(2186,5846),(2190,5851),(2211,5884)]
(214,197,93) [(1653,4386)]
(163,102,101) [(2226,2832),(2213,3683),(1894,4091),(1875,4117)]
(192,192,164) [(2175,2962),(2206,3667),(2315,3858),(1561,3977),(3039,5037),(3201,5641)]
(92,118,45) [(1881,1704),(1983,1877),(2254,2126),(3753,5862),(3766,5883)]
(145,180,173) [(1826,1585)]
(181,124,105) [(1969,3892)]
turret-arch:
(116,70,36) [(384,648),(516,669)]
(121,115,119) [(2419,958)]
(183,222,237) [(172,601),(183,601),(110,611),(111,617)]
(237,136,82) [(2020,282),(676,383),(748,406),(854,482),(638,497),(647,661),(1069,838),(1809,895),(1823,911)]
(193,199,215) [(1567,919),(1793,1047)]
(33,30,25) [(1307,861),(309,885),(1995,895),(504,1232),(2417,1494)]
(17,23,39) [(1745,1033),(788,1090),(967,1250)]
(192,139,95) [(1445,1337)]
(176,125,98) [(1197,1030)]
(178,83,0) [(2378,1136)]
water-lilies:
(86,140,80) [(2322,2855),(4542,3005),(4540,3006),(4577,3019)]
(218,124,174) [(1910,2457)]
(191,77,50) [(2076,1588)]
(197,211,186) [(4402,1894)]
(236,199,181) [(2154,1836)]
(253,242,162) [(1653,1430)]
(114,111,92) [(1936,2499)]
(111,93,27) [(2301,2423),(2127,2592),(2137,2717),(2147,2717)]
(139,92,102) [(1284,2243),(1297,2258)]
(199,157,117) [(3096,993)]

2
테스트 할 이미지에 상관 관계가 있습니까? (이미지가 노이즈 일 수 있습니다) 그렇지 않은 경우 올바른 픽셀을 선택할 때까지 반드시 유일한 방법은 샘플링입니까?
Blue

2
@muddyfish 이미지가 너무 거기에, 실물의 실제 카메라로 촬영하는 것입니다 찾을 수 최적화. 귀하의 알고리즘은 내가 제공하는 특정 색상이 아니라 이미지를 타겟팅해야합니다.
Nathan Merrill

"가능한 한 적은 픽셀을 읽는 동안"이것을 어떻게 결정합니까?
David

라이브러리와 언어의 차이로 인해 "액세스"로 간주되는 메소드를 정의 할 수 없습니다. 특히 무엇을 생각하고 있습니까?
Nathan Merrill

솔루션에서 확인한 픽셀 수를 출력해야합니까?
trichoplax

답변:


5

파이썬, 점수 : 14,035,624

먼저, 코드는 다음과 같습니다.

from heapq import heappush, heappop
from PIL import Image
import random

random.seed(1)


def dist(x, y):
    return sum([(x[i] - y[i]) ** 2 for i in range(3)])


def gradient_descent(image_name, c):
    im = Image.open(image_name + '.jpg').convert('RGB')
    L = im.load()
    sx, sy = im.size
    heap = []
    visited = set()
    count = 0
    points = []
    for i in range(0, sx, sx / 98):
        for j in range(0, sy, sy / 98):
            points.append((i, j))
    for x in points:
        heappush(heap, [dist(c, L[x[0], x[1]]), [x[0], x[1]]])
        visited.add((x[0], x[1]))

    while heap:
        if count % 10 == 0:
            x = random.random()
            if x < 0.5:
                n = heap.pop(random.randint(10, 100))
            else:
                n = heappop(heap)
        else:
            n = heappop(heap)
        x, y = n[1]
        c_color = L[x, y]
        count += 1

        if c_color == c:
            p = float(len(visited)) / (sx * sy) * 100
            print('count: {}, percent: {}, position: {}'.format(len(visited), p, (x, y)))
            return len(visited)

        newpoints = []
        newpoints.append((x + 1, y))
        newpoints.append((x - 1, y))
        newpoints.append((x, y + 1))
        newpoints.append((x, y - 1))
        newpoints.append((x + 1, y + 1))
        newpoints.append((x + 1, y - 1))
        newpoints.append((x - 1, y + 1))
        newpoints.append((x - 1, y - 1))

        for p in newpoints:
            if p not in visited:
                try:
                    d = dist(c, L[p[0], p[1]])
                    heappush(heap, [d, [p[0], p[1]]])
                    visited.add(p)
                except IndexError:
                    pass

다음은 알고리즘이 픽셀을 검사하는 방법을 보여주는 gif입니다.

따라서이 코드가 수행하는 작업은 다음과 같습니다. 변수 heap는 이미지에서 좌표 의 우선 순위 대기열 이며 해당 (x, y)좌표에서 색상의 유클리드 거리를 대상 색상으로 정렬합니다. 10,200 포인트로 초기화되어 전체 이미지에 균등하게 분배됩니다.

힙이 초기화되면 대상 색상까지의 최소 거리로 포인트를 팝합니다. 해당 지점의 색상이 0보다 큰 거리를 갖는 경우, 즉 해당 지점의 색상이 대상 색상이 아닌 경우 주변 점 8을에 추가합니다 heap. 주어진 점이 두 번 이상 고려되지 않도록하기 위해 visited지금까지 조사 된 모든 점의 집합 인 variable을 유지합니다 .

경우에 따라 최소 색 거리로 직접 점을 찍는 대신 대기열 상단 근처 에서 다른 점을 임의로 선택합니다 . 이것은 꼭 필요한 것은 아니지만 테스트에서 총 점수에서 약 1,000,000 픽셀을 깎습니다. 대상 색상을 찾으면 visited세트 의 길이를 반환합니다 .

@ Karl Napf와 마찬가지로 지정된 색상이 이미지에없는 테스트 사례를 무시했습니다. 이 답변을 위해 만든 GitHub 리포지토리 에서 모든 테스트 사례를 실행하는 드라이버 프로그램을 찾을 수 있습니다 .

각 특정 테스트 사례의 결과는 다음과 같습니다.

barn
color: (143, 91, 33), count: 20388 / 0.452483465755%, position: (612, 1131)
color: (53, 35, 59), count: 99606 / 2.21061742643%, position: (1999, 1260)
color: (72, 49, 59), count: 705215 / 15.6512716943%, position: (1405, 974)

daisy
color: (21, 57, 91), count: 37393 / 0.154770711039%, position: (1877, 2131)
color: (169, 160, 0), count: 10659 / 0.0441179100089%, position: (2124, 759)
color: (113, 123, 114), count: 674859 / 2.79326096545%, position: (1119, 1335)
color: (225, 226, 231), count: 15905 / 0.0658312560927%, position: (3256, 889)
color: (17, 62, 117), count: 15043 / 0.0622634131029%, position: (2514, 3874)
color: (226, 225, 204), count: 138610 / 0.573710808362%, position: (1978, 1179)
color: (119, 124, 146), count: 390486 / 1.61623287435%, position: (2357, 917)
color: (2, 63, 120), count: 10063 / 0.0416510487306%, position: (2324, 3882)
color: (200, 167, 113), count: 16393 / 0.06785110224%, position: (1453, 1759)

dandelion
color: (95, 37, 33), count: 10081 / 0.0686342592593%, position: (1625, 1724)
color: (27, 41, 50), count: 2014910 / 13.7180691721%, position: (1267, 126)
color: (58, 92, 129), count: 48181 / 0.328029684096%, position: (1905, 756)
color: (136, 159, 105), count: 10521 / 0.0716299019608%, position: (1416, 3467)
color: (152, 174, 63), count: 10027 / 0.0682666122004%, position: (2256, 2558)
color: (69, 95, 130), count: 201919 / 1.37472086057%, position: (2708, 2943)
color: (150, 171, 174), count: 29714 / 0.202301198257%, position: (1180, 2706)

gerbera
color: (180, 153, 40), count: 21904 / 0.0906612910062%, position: (4459, 1644)
color: (116, 112, 149), count: 14896 / 0.0616549758413%, position: (5884, 252)
color: (222, 176, 65), count: 76205 / 0.315414704215%, position: (4313, 2097)
color: (108, 129, 156), count: 12273 / 0.0507983027994%, position: (5302, 3734)
color: (125, 99, 48), count: 26968 / 0.111621333814%, position: (5054, 2013)
color: (170, 149, 32), count: 89591 / 0.370819746281%, position: (4478, 1647)
color: (156, 185, 203), count: 177373 / 0.734151989118%, position: (4096, 368)
color: (103, 67, 17), count: 11035 / 0.0456741849093%, position: (4844, 1790)

hot-air
color: (48, 21, 36), count: 49711 / 0.24902994992%, position: (1990, 1095)
color: (104, 65, 36), count: 9927 / 0.0497298447599%, position: (3191, 1846)
color: (68, 59, 60), count: 195418 / 0.978957066918%, position: (3948, 470)
color: (82, 42, 32), count: 12216 / 0.0611967143737%, position: (4559, 984)
color: (192, 132, 72), count: 116511 / 0.583668171938%, position: (3103, 1844)

in-input
color: (204, 90, 1), count: 44058 / 0.248299807393%, position: (4695, 2559)
color: (227, 163, 53), count: 12654 / 0.0713147615132%, position: (221, 2384)
color: (196, 179, 135), count: 181534 / 1.02307996812%, position: (1030, 3486)
color: (208, 59, 27), count: 9956 / 0.0561095120614%, position: (4518, 2108)
color: (149, 70, 1), count: 13698 / 0.0771984829467%, position: (3731, 2408)
color: (168, 3, 7), count: 19381 / 0.10922644167%, position: (942, 398)
color: (218, 118, 4), count: 36648 / 0.206538911011%, position: (25, 2606)
color: (224, 230, 246), count: 1076427 / 6.06647185011%, position: (4482, 1442)
color: (213, 127, 66), count: 62673 / 0.353209265712%, position: (4701, 2579)

klatschmohn
color: (170, 133, 19), count: 11535 / 0.0724321530189%, position: (1034, 2633)
color: (162, 92, 4), count: 103795 / 0.651763790429%, position: (489, 2854)
color: (159, 175, 104), count: 10239 / 0.0642941321856%, position: (3098, 2481)
color: (171, 169, 170), count: 10119 / 0.063540611738%, position: (3674, 1490)
color: (184, 115, 58), count: 22425 / 0.140814133632%, position: (1958, 2404)
color: (228, 169, 5), count: 10449 / 0.0656127929688%, position: (1316, 2336)
color: (179, 165, 43), count: 10285 / 0.0645829816905%, position: (1842, 2498)
color: (67, 21, 6), count: 10206 / 0.0640869140625%, position: (2116, 2373)
color: (213, 100, 106), count: 11712 / 0.073543595679%, position: (1303, 1816)

tajinaste-rojo
color: (243, 56, 99), count: 126561 / 0.5273375%, position: (2241, 5424)
color: (114, 37, 19), count: 11285 / 0.0470208333333%, position: (1818, 3583)
color: (108, 117, 116), count: 33855 / 0.1410625%, position: (1269, 5672)
color: (163, 102, 101), count: 1058090 / 4.40870833333%, position: (1546, 4867)
color: (192, 192, 164), count: 10118 / 0.0421583333333%, position: (1919, 3171)
color: (92, 118, 45), count: 13431 / 0.0559625%, position: (3766, 5883)
color: (145, 180, 173), count: 1207713 / 5.0321375%, position: (1863, 955)

turret-arch
color: (116, 70, 36), count: 145610 / 3.23161258822%, position: (96, 671)
color: (183, 222, 237), count: 11704 / 0.259754094722%, position: (140, 604)
color: (237, 136, 82), count: 60477 / 1.34220338231%, position: (1063, 993)
color: (193, 199, 215), count: 359671 / 7.98240046163%, position: (2259, 953)
color: (33, 30, 25), count: 148195 / 3.28898308846%, position: (1307, 861)
color: (17, 23, 39), count: 10601 / 0.235274535044%, position: (2080, 1097)
color: (192, 139, 95), count: 219732 / 4.87664787607%, position: (1127, 970)
color: (176, 125, 98), count: 2471787 / 54.8578942696%, position: (147, 734)

water-lilies
color: (86, 140, 80), count: 10371 / 0.0717376936238%, position: (4542, 3005)
color: (218, 124, 174), count: 25655 / 0.177459312498%, position: (1910, 2457)
color: (197, 211, 186), count: 1144341 / 7.91557073177%, position: (4402, 1894)
color: (253, 242, 162), count: 14174 / 0.0980435897622%, position: (1672, 1379)
color: (111, 93, 27), count: 10405 / 0.0719728764975%, position: (2147, 2717)
color: (199, 157, 117), count: 10053 / 0.0695380420403%, position: (3096, 993)

Total: 14035624

2
이것은 정말 좋은 대답입니다. 좋은 알고리즘도 있습니다.
niemiro 2016 년

1
여러 씨앗을 사용한 가장 가까운 이웃 검색은 훌륭합니다! 나도 당신처럼 힙을 가진 DFS에서 BFS를 사용하는 것을 고려했지만 quadsearch가 너무 넓습니다.
Karl Napf

1

파이썬, 점수 : 396,250,646

  • 파싱 ​​할 PNG가 없으며 테스트 케이스에 여전히 문제가 있지만 어쨌든 프로그래밍하기로 결정했습니다.
  • 이미지에 값이없는 테스트 케이스는 무시되었습니다 (점수 544,017,431 인 전통적인 선형 검색과 비교하여 확인 )
from PIL import Image

def dist(x,y):
 d = 0
 for i in range(3):
  d += (x[i]-y[i])**2
 return d

def mid(x,y):
 return (x+y)/2

class Finder:
 def __init__(self, image_name, c):
  self.image_name = image_name,
  self.c = c
  self.found = False
  self.position = None
  self.im = Image.open(image_name+".jpg").convert("RGB")
  self.L = self.im.load()
  self.visited = set()

 def quadsearch(self,x0,x1,y0,y1):
  if x0==x1 and y0==y1: return
  xm=mid(x0,x1)
  ym=mid(y0,y1)
  R = [
   (x0,xm,y0,ym),
   (xm,x1,y0,ym),
   (x0,xm,ym,y1),
   (xm,x1,ym,y1),
   ]
  P = [(mid(t[0],t[1]), mid(t[2],t[3])) for t in R]
  DR = []
  for i in range(len(P)):
   p = P[i]
   if p in self.visited: continue
   self.visited.add(p)
   u = self.L[p[0], p[1]]
   d = dist(u, self.c)
   if d == 0:
    self.found = True
    self.position = (p[0], p[1])
    return
   DR.append((d,R[i]))
  S = sorted(range(len(DR)), key=lambda k: DR[k][0])
  for i in S:
   if self.found == True: return
   r = DR[i][1]
   self.quadsearch(r[0], r[1], r[2], r[3])

 def start(self):
  sx,sy = self.im.size
  self.quadsearch(0,sx,0,sy)

 def result(self):
  if self.found:
   count = len(self.visited)
   sx,sy = self.im.size
   ratio = float(count)/(sx*sy)
   print len(self.visited), ratio, self.position, self.L[self.position[0], self.position[1]], "=", self.c
  else:
   print self.c, "not found"

if __name__ == "__main__":
 image_name="turret-arch"
 c=(116,70,36)
 F = Finder(image_name, c)
 F.start()
 F.result()

재귀 쿼드 섹션 검색입니다. 때로는 몇 퍼센트, 때로는 75 % 이상에서 올바른 값을 찾습니다. 모든 테스트 케이스에 대한 결과는 다음과 같습니다.

pixels_visited, percentage, (position) (RGB at position) = (RGB searched)

tajinaste-rojo
1500765 0.062531875 (2329, 5146) (243, 56, 99) = (243, 56, 99)
(147, 157, 210) not found
335106 0.01396275 (2116, 5791) (114, 37, 19) = (114, 37, 19)
1770396 0.0737665 (1269, 5672) (108, 117, 116) = (108, 117, 116)
(214, 197, 93) not found
8086276 0.336928166667 (1546, 4867) (163, 102, 101) = (163, 102, 101)
12859 0.000535791666667 (1476, 4803) (192, 192, 164) = (192, 192, 164)
7505961 0.312748375 (3766, 5883) (92, 118, 45) = (92, 118, 45)
15057489 0.627395375 (1871, 1139) (145, 180, 173) = (145, 180, 173)
(181, 124, 105) not found
in-input
35754 0.00201500551852 (4695, 2559) (204, 90, 1) = (204, 90, 1)
5029615 0.283456451895 (10, 2680) (227, 163, 53) = (227, 163, 53)
6986547 0.393744217722 (1383, 3446) (196, 179, 135) = (196, 179, 135)
1608341 0.090642053775 (4518, 2108) (208, 59, 27) = (208, 59, 27)
581774 0.0327873194757 (3750, 2798) (149, 70, 1) = (149, 70, 1)
1302581 0.0734101891628 (4374, 1941) (168, 3, 7) = (168, 3, 7)
6134761 0.345739701008 (25, 2606) (218, 118, 4) = (218, 118, 4)
(127, 153, 4) not found
9760033 0.550050913352 (4482, 1442) (224, 230, 246) = (224, 230, 246)
212816 0.0119937745268 (4701, 2579) (213, 127, 66) = (213, 127, 66)
water-lilies
5649260 0.390767412093 (4577, 3019) (86, 140, 80) = (86, 140, 80)
12600699 0.871608412215 (1910, 2457) (218, 124, 174) = (218, 124, 174)
(191, 77, 50) not found
3390653 0.234536328318 (4402, 1894) (197, 211, 186) = (197, 211, 186)
(236, 199, 181) not found
7060220 0.488365537823 (1672, 1379) (253, 242, 162) = (253, 242, 162)
(114, 111, 92) not found
6852380 0.473988947097 (2147, 2717) (111, 93, 27) = (111, 93, 27)
(139, 92, 102) not found
14105709 0.975712111261 (3096, 993) (199, 157, 117) = (199, 157, 117)
dandelion
(55, 2, 46) not found
9094264 0.619162854031 (1637, 1721) (95, 37, 33) = (95, 37, 33)
2358912 0.16060130719 (1526, 3129) (27, 41, 50) = (27, 41, 50)
11729837 0.798600013617 (1905, 756) (58, 92, 129) = (58, 92, 129)
6697060 0.455954520697 (2246, 2685) (136, 159, 105) = (136, 159, 105)
6429635 0.437747480937 (2148, 2722) (152, 174, 63) = (152, 174, 63)
(78, 49, 19) not found
(217, 178, 205) not found
80727 0.00549611928105 (2481, 3133) (69, 95, 130) = (69, 95, 130)
239962 0.0163372821351 (2660, 917) (150, 171, 174) = (150, 171, 174)
turret-arch
210562 0.0467313240712 (725, 655) (116, 70, 36) = (116, 70, 36)
(121, 115, 119) not found
2548703 0.565649385237 (140, 604) (183, 222, 237) = (183, 222, 237)
150733 0.033453104887 (2165, 601) (237, 136, 82) = (237, 136, 82)
3458188 0.767497003862 (2259, 953) (193, 199, 215) = (193, 199, 215)
2430256 0.539361711572 (265, 1222) (33, 30, 25) = (33, 30, 25)
638995 0.141816103689 (1778, 1062) (17, 23, 39) = (17, 23, 39)
2506522 0.556287895601 (1127, 970) (192, 139, 95) = (192, 139, 95)
1344400 0.298370988504 (147, 734) (176, 125, 98) = (176, 125, 98)
(178, 83, 0) not found
hot-air
17474837 0.875411434688 (1992, 1029) (48, 21, 36) = (48, 21, 36)
1170064 0.0586149905099 (3191, 1846) (104, 65, 36) = (104, 65, 36)
(169, 89, 62) not found
11891624 0.595717352134 (3948, 470) (68, 59, 60) = (68, 59, 60)
(198, 96, 74) not found
(136, 43, 53) not found
12476811 0.625032612198 (4387, 1126) (82, 42, 32) = (82, 42, 32)
4757856 0.238347376116 (3105, 1822) (192, 132, 72) = (192, 132, 72)
(146, 21, 63) not found
(125, 64, 36) not found
daisy
5322196 0.220287235367 (2171, 2128) (21, 57, 91) = (21, 57, 91)
(201, 175, 140) not found
22414990 0.9277629343 (2124, 759) (169, 160, 0) = (169, 160, 0)
20887184 0.864526601043 (1119, 1335) (113, 123, 114) = (113, 123, 114)
595712 0.0246566923794 (2656, 1349) (225, 226, 231) = (225, 226, 231)
3397561 0.140626034757 (2514, 3874) (17, 62, 117) = (17, 62, 117)
201068 0.00832226281046 (1978, 1179) (226, 225, 204) = (226, 225, 204)
18693250 0.773719036752 (2357, 917) (119, 124, 146) = (119, 124, 146)
3091040 0.127939041706 (2165, 3881) (2, 63, 120) = (2, 63, 120)
3567932 0.147677739839 (1453, 1759) (200, 167, 113) = (200, 167, 113)
barn
314215 0.0697356740202 (784, 1065) (143, 91, 33) = (143, 91, 33)
2448863 0.543491277908 (1999, 1260) (53, 35, 59) = (53, 35, 59)
(20, 24, 27) not found
(167, 148, 176) not found
(137, 50, 7) not found
(116, 95, 94) not found
2042891 0.453391406631 (1345, 858) (72, 49, 59) = (72, 49, 59)
(211, 163, 175) not found
(30, 20, 0) not found
(88, 36, 23) not found
klatschmohn
3048249 0.191409829222 (3683, 3439) (170, 133, 19) = (170, 133, 19)
1057649 0.0664133456509 (489, 2854) (162, 92, 4) = (162, 92, 4)
2058022 0.129230138206 (3095, 2475) (159, 175, 104) = (159, 175, 104)
(199, 139, 43) not found
2060805 0.129404892156 (3674, 1490) (171, 169, 170) = (171, 169, 170)
7725501 0.485110247577 (1958, 2404) (184, 115, 58) = (184, 115, 58)
2986734 0.187547095028 (1316, 2336) (228, 169, 5) = (228, 169, 5)
497709 0.0312528257017 (3879, 2379) (179, 165, 43) = (179, 165, 43)
3996978 0.250983720944 (2157, 2318) (67, 21, 6) = (67, 21, 6)
3332106 0.209234167028 (1303, 1816) (213, 100, 106) = (213, 100, 106)
gerbera
(218, 186, 171) not found
9445576 0.390955128952 (4377, 1750) (180, 153, 40) = (180, 153, 40)
(201, 179, 119) not found
6140398 0.254152853347 (5742, 576) (116, 112, 149) = (116, 112, 149)
6500717 0.269066561215 (4233, 1541) (222, 176, 65) = (222, 176, 65)
13307056 0.550782905612 (5302, 3734) (108, 129, 156) = (108, 129, 156)
13808847 0.571552180573 (5058, 2023) (125, 99, 48) = (125, 99, 48)
9454870 0.391339810307 (4478, 1647) (170, 149, 32) = (170, 149, 32)
2733978 0.113160142012 (4096, 368) (156, 185, 203) = (156, 185, 203)
11848606 0.490417237301 (4844, 1790) (103, 67, 17) = (103, 67, 17)
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