16 prop_all_cidrs_contain_themselves,
17 prop_contains_proper_intransitive
20 import Data.List (nubBy)
22 import Test.QuickCheck
24 import qualified Bit as B
32 data Cidr = None | Cidr { ipv4address :: IPv4Address,
33 maskbits :: Maskbits }
37 instance Show Cidr where
38 show Cidr.None = "None"
39 show cidr = (show (ipv4address cidr)) ++ "/" ++ (show (maskbits cidr))
42 instance Arbitrary Cidr where
44 ipv4 <- arbitrary :: Gen IPv4Address
45 mask <- arbitrary :: Gen Maskbits
46 return (Cidr ipv4 mask)
48 coarbitrary _ = variant 0
51 -- Two CIDR ranges are equivalent if they have the same network bits
52 -- and the masks are the same.
53 equivalent :: Cidr -> Cidr -> Bool
54 equivalent Cidr.None Cidr.None = True
55 equivalent Cidr.None _ = False
56 equivalent _ Cidr.None = False
57 equivalent (Cidr addr1 mbits1) (Cidr addr2 mbits2) =
58 (mbits1 == mbits2) && ((apply_mask addr1 mbits1) == (apply_mask addr2 mbits2))
60 -- Returns the mask portion of a CIDR address. That is, everything
61 -- after the trailing slash.
62 maskbits_from_cidr_string :: String -> Maskbits
63 maskbits_from_cidr_string s =
64 maskbits_from_string ((splitWith (`elem` "/") s) !! 1)
67 -- Takes an IP address String in CIDR notation, and returns a list of
68 -- its octets (as Ints).
69 octets_from_cidr_string :: String -> [Octet]
70 octets_from_cidr_string s =
71 map octet_from_string (take 4 (splitWith (`elem` "./") s))
74 cidr_from_string :: String -> Cidr
76 | addr == IPv4Address.None = Cidr.None
77 | mbits == Maskbits.None = Cidr.None
78 | otherwise = Cidr addr mbits
80 addr = ipv4address_from_octets (oct1) (oct2) (oct3) (oct4)
85 octs = octets_from_cidr_string s
86 mbits = maskbits_from_cidr_string s
90 min_address :: Cidr -> IPv4Address
91 min_address (Cidr IPv4Address.None _) = IPv4Address.None
92 min_address (Cidr _ Maskbits.None) = IPv4Address.None
93 min_address (Cidr addr mask)
94 | mask == ThirtyTwo = addr
95 | mask == ThirtyOne = addr { octet4 = apply_mask oct4 Seven }
96 | mask == Thirty = addr { octet4 = apply_mask oct4 Six }
97 | mask == TwentyNine = addr { octet4 = apply_mask oct4 Five }
98 | mask == TwentyEight = addr { octet4 = apply_mask oct4 Four }
99 | mask == TwentySeven = addr { octet4 = apply_mask oct4 Three }
100 | mask == TwentySix = addr { octet4 = apply_mask oct4 Two }
101 | mask == TwentyFive = addr { octet4 = apply_mask oct4 One }
102 | mask == TwentyFour = addr { octet4 = min_octet }
103 | mask == TwentyThree = addr { octet3 = apply_mask oct3 Seven,
105 | mask == TwentyTwo = addr { octet3 = apply_mask oct3 Six,
107 | mask == TwentyOne = addr { octet3 = apply_mask oct3 Five,
109 | mask == Twenty = addr { octet3 = apply_mask oct3 Four,
111 | mask == Nineteen = addr { octet3 = apply_mask oct3 Three,
113 | mask == Eighteen = addr { octet3 = apply_mask oct3 Two,
115 | mask == Seventeen = addr { octet3 = apply_mask oct3 One,
117 | mask == Sixteen = addr { octet3 = min_octet,
119 | mask == Fifteen = addr { octet2 = apply_mask oct2 Seven,
122 | mask == Fourteen = addr { octet2 = apply_mask oct2 Six,
125 | mask == Thirteen = addr { octet2 = apply_mask oct2 Five,
128 | mask == Twelve = addr { octet2 = apply_mask oct2 Four,
131 | mask == Eleven = addr { octet2 = apply_mask oct2 Three,
134 | mask == Ten = addr { octet2 = apply_mask oct2 Two,
137 | mask == Nine = addr { octet2 = apply_mask oct2 One,
140 | mask == Eight = addr { octet2 = min_octet,
143 | mask == Seven = addr { octet1 = apply_mask oct1 Seven,
147 | mask == Six = addr { octet1 = apply_mask oct1 Six,
151 | mask == Five = addr { octet1 = apply_mask oct1 Five,
155 | mask == Four = addr { octet1 = apply_mask oct1 Four,
159 | mask == Three = addr { octet1 = apply_mask oct1 Three,
163 | mask == Two = addr { octet1 = apply_mask oct1 Two,
167 | mask == One = addr { octet1 = apply_mask oct1 One,
171 | mask == Zero = addr { octet1 = min_octet,
184 max_address :: Cidr -> IPv4Address
185 max_address (Cidr IPv4Address.None _) = IPv4Address.None
186 max_address (Cidr _ Maskbits.None) = IPv4Address.None
187 max_address (Cidr addr mask)
188 | mask == ThirtyTwo = ipv4address_from_octets oct1 oct2 oct3 oct4
189 | mask == ThirtyOne = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 a27 a28 a29 a30 a31 B.One)
190 | mask == Thirty = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 a27 a28 a29 a30 B.One B.One)
191 | mask == TwentyNine = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 a27 a28 a29 B.One B.One B.One)
192 | mask == TwentyEight = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 a27 a28 B.One B.One B.One B.One)
193 | mask == TwentySeven = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 a27 B.One B.One B.One B.One B.One)
194 | mask == TwentySix = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 a26 B.One B.One B.One B.One B.One B.One)
195 | mask == TwentyFive = ipv4address_from_octets oct1 oct2 oct3 (Octet a25 B.One B.One B.One B.One B.One B.One B.One)
196 | mask == TwentyFour = ipv4address_from_octets oct1 oct2 oct3 (max_octet)
197 | mask == TwentyThree = ipv4address_from_octets oct1 oct2 (Octet a17 a18 a19 a20 a21 a22 a23 B.One) (max_octet)
198 | mask == TwentyTwo = ipv4address_from_octets oct1 oct2 (Octet a17 a18 a19 a20 a21 a22 B.One B.One) (max_octet)
199 | mask == TwentyOne = ipv4address_from_octets oct1 oct2 (Octet a17 a18 a19 a20 a21 B.One B.One B.One) (max_octet)
200 | mask == Twenty = ipv4address_from_octets oct1 oct2 (Octet a17 a18 a19 a20 B.One B.One B.One B.One) (max_octet)
201 | mask == Nineteen = ipv4address_from_octets oct1 oct2 (Octet a17 a18 a19 B.One B.One B.One B.One B.One) (max_octet)
202 | mask == Eighteen = ipv4address_from_octets oct1 oct2 (Octet a17 a18 B.One B.One B.One B.One B.One B.One) (max_octet)
203 | mask == Seventeen = ipv4address_from_octets oct1 oct2 (Octet a17 B.One B.One B.One B.One B.One B.One B.One) (max_octet)
204 | mask == Sixteen = ipv4address_from_octets oct1 oct2 (max_octet) (max_octet)
205 | mask == Fifteen = ipv4address_from_octets oct1 (Octet a9 a10 a11 a12 a13 a14 a15 B.One) (max_octet) (max_octet)
206 | mask == Fourteen = ipv4address_from_octets oct1 (Octet a9 a10 a11 a12 a13 a14 B.One B.One) (max_octet) (max_octet)
207 | mask == Thirteen = ipv4address_from_octets oct1 (Octet a9 a10 a11 a12 a13 B.One B.One B.One) (max_octet) (max_octet)
208 | mask == Twelve = ipv4address_from_octets oct1 (Octet a9 a10 a11 a12 B.One B.One B.One B.One) (max_octet) (max_octet)
209 | mask == Eleven = ipv4address_from_octets oct1 (Octet a9 a10 a11 B.One B.One B.One B.One B.One) (max_octet) (max_octet)
210 | mask == Ten = ipv4address_from_octets oct1 (Octet a9 a10 B.One B.One B.One B.One B.One B.One) (max_octet) (max_octet)
211 | mask == Nine = ipv4address_from_octets oct1 (Octet a9 B.One B.One B.One B.One B.One B.One B.One) (max_octet) (max_octet)
212 | mask == Eight = ipv4address_from_octets oct1 (max_octet) (max_octet) (max_octet)
213 | mask == Seven = ipv4address_from_octets (Octet a1 a2 a3 a4 a5 a6 a7 B.One) (max_octet) (max_octet) (max_octet)
214 | mask == Six = ipv4address_from_octets (Octet a1 a2 a3 a4 a5 a6 B.One B.One) (max_octet) (max_octet) (max_octet)
215 | mask == Five = ipv4address_from_octets (Octet a1 a2 a3 a4 a5 B.One B.One B.One) (max_octet) (max_octet) (max_octet)
216 | mask == Four = ipv4address_from_octets (Octet a1 a2 a3 a4 B.One B.One B.One B.One) (max_octet) (max_octet) (max_octet)
217 | mask == Three = ipv4address_from_octets (Octet a1 a2 a3 B.One B.One B.One B.One B.One) (max_octet) (max_octet) (max_octet)
218 | mask == Two = ipv4address_from_octets (Octet a1 a2 B.One B.One B.One B.One B.One B.One) (max_octet) (max_octet) (max_octet)
219 | mask == One = ipv4address_from_octets (Octet a1 B.One B.One B.One B.One B.One B.One B.One) (max_octet) (max_octet) (max_octet)
220 | mask == Zero = ipv4address_from_octets (max_octet) (max_octet) (max_octet) (max_octet)
258 min_octet1 :: Cidr -> Octet
259 min_octet1 cidr = octet1 (min_address cidr)
261 min_octet2 :: Cidr -> Octet
262 min_octet2 cidr = octet2 (min_address cidr)
264 min_octet3 :: Cidr -> Octet
265 min_octet3 cidr = octet3 (min_address cidr)
267 min_octet4 :: Cidr -> Octet
268 min_octet4 cidr = octet4 (min_address cidr)
270 max_octet1 :: Cidr -> Octet
271 max_octet1 cidr = octet1 (max_address cidr)
273 max_octet2 :: Cidr -> Octet
274 max_octet2 cidr = octet2 (max_address cidr)
276 max_octet3 :: Cidr -> Octet
277 max_octet3 cidr = octet3 (max_address cidr)
279 max_octet4 :: Cidr -> Octet
280 max_octet4 cidr = octet4 (max_address cidr)
284 -- Return true if the first argument (a CIDR range) contains the
285 -- second (another CIDR range). There are a lot of ways we can be fed
286 -- junk here. For lack of a better alternative, just return False when
287 -- we are given nonsense.
288 contains :: Cidr -> Cidr -> Bool
289 contains Cidr.None _ = False
290 contains _ Cidr.None = False
291 contains (Cidr _ Maskbits.None) _ = False
292 contains (Cidr IPv4Address.None _) _ = False
293 contains _ (Cidr _ Maskbits.None) = False
294 contains _ (Cidr IPv4Address.None _) = False
296 -- If the number of bits in the network part of the first address is
297 -- larger than the number of bits in the second, there is no way that
298 -- the first range can contain the second. For, if the number of
299 -- network bits is larger, then the number of host bits must be
300 -- smaller, and if cidr1 has fewer hosts than cidr2, cidr1 most
301 -- certainly does not contain cidr2.
303 -- On the other hand, if the first argument (cidr1) has fewer (or the
304 -- same number of) network bits as the second, it can contain the
305 -- second. In this case, we need to check that every host in cidr2 is
306 -- contained in cidr1. If a host in cidr2 is contained in cidr1, then
307 -- at least mbits1 of an address in cidr2 will match cidr1. For
310 -- cidr1 = 192.168.1.0/23, cidr2 = 192.168.1.100/24
312 -- Here, cidr2 contains all of 192.168.1.0 through
313 -- 192.168.1.255. However, cidr1 contains BOTH 192.168.0.0 through
314 -- 192.168.0.255 and 192.168.1.0 through 192.168.1.255. In essence,
315 -- what we want to check is that cidr2 "begins with" something that
316 -- cidr1 CAN begin with. Since cidr1 can begin with 192.168.1, and
317 -- cidr2 DOES, cidr1 contains cidr2..
319 -- The way that we check this is to apply cidr1's mask to cidr2's
320 -- address and see if the result is the same as cidr1's mask applied
321 -- to cidr1's address.
323 contains (Cidr addr1 mbits1) (Cidr addr2 mbits2)
324 | mbits1 > mbits2 = False
325 | otherwise = addr1masked == addr2masked
327 addr1masked = apply_mask addr1 mbits1
328 addr2masked = apply_mask addr2 mbits1
331 contains_proper :: Cidr -> Cidr -> Bool
332 contains_proper cidr1 cidr2 =
333 (cidr1 `contains` cidr2) && (not (cidr2 `contains` cidr1))
336 -- A CIDR range is redundant (with respect to the given list) if
337 -- another CIDR range in that list properly contains it.
338 redundant :: [Cidr] -> Cidr -> Bool
339 redundant cidrlist cidr = any ((flip contains_proper) cidr) cidrlist
342 -- First, we look at all possible pairs of cidrs, and combine the
343 -- adjacent ones in to a new list. Then, we concatenate that list with
344 -- the original one, and filter out all of the redundancies. If two
345 -- adjacent Cidrs are combined into a larger one, they will be removed
346 -- in the second step since the larger Cidr must contain the smaller
348 combine_all :: [Cidr] -> [Cidr]
350 combine_contained unique_cidrs
352 unique_cidrs = nubBy equivalent valid_cidr_combinations
353 valid_cidr_combinations = filter (/= Cidr.None) cidr_combinations
355 cidrs ++ [ (combine_adjacent x y) | x <- cidrs, y <- cidrs ]
358 -- Take a list of CIDR ranges and filter out all of the ones that are
359 -- contained entirelt within some other range in the list.
360 combine_contained :: [Cidr] -> [Cidr]
361 combine_contained cidrs =
362 filter (not . (redundant cidrs)) cidrs
365 -- If the two Cidrs are not adjacent, return Cidr.None. Otherwise,
366 -- decrement the maskbits of cidr1 and return that; it will contain
367 -- both cidr1 and cidr2.
368 combine_adjacent :: Cidr -> Cidr -> Cidr
369 combine_adjacent cidr1 cidr2
370 | not (adjacent cidr1 cidr2) = Cidr.None
371 | (maskbits cidr1 == Zero) = Cidr.None
372 | otherwise = cidr1 { maskbits = decrement (maskbits cidr1) }
376 -- Determine whether or not two CIDR ranges are adjacent. If two
377 -- ranges lie consecutively within the IP space, they can be
378 -- combined. For example, 10.1.0.0/24 and 10.0.1.0/24 are adjacent,
379 -- and can be combined in to 10.1.0.0/23.
380 adjacent :: Cidr -> Cidr -> Bool
381 adjacent Cidr.None _ = False
382 adjacent _ Cidr.None = False
384 | mbits1 /= mbits2 = False
385 | mbits1 == Maskbits.Zero = False -- They're equal.
386 | otherwise = (mbits1 == (most_sig_bit_different addr1 addr2))
388 addr1 = ipv4address cidr1
389 addr2 = ipv4address cidr2
390 mbits1 = maskbits cidr1
391 mbits2 = maskbits cidr2
399 test_equality1 :: Test
401 TestCase $ assertEqual "10.1.1.0/23 equals itself" True (cidr1 == cidr1)
403 cidr1 = cidr_from_string "10.1.1.0/23"
406 test_contains1 :: Test
408 TestCase $ assertEqual "10.1.1.0/23 contains 10.1.1.0/24" True (cidr1 `contains` cidr2)
410 cidr1 = cidr_from_string "10.1.1.0/23"
411 cidr2 = cidr_from_string "10.1.1.0/24"
414 test_contains2 :: Test
416 TestCase $ assertEqual "10.1.1.0/23 contains itself" True (cidr1 `contains` cidr1)
418 cidr1 = cidr_from_string "10.1.1.0/23"
421 test_contains_proper1 :: Test
422 test_contains_proper1 =
423 TestCase $ assertEqual "10.1.1.0/23 contains 10.1.1.0/24 properly" True (cidr1 `contains_proper` cidr2)
425 cidr1 = cidr_from_string "10.1.1.0/23"
426 cidr2 = cidr_from_string "10.1.1.0/24"
429 test_contains_proper2 :: Test
430 test_contains_proper2 =
431 TestCase $ assertEqual "10.1.1.0/23 does not contain itself properly" False (cidr1 `contains_proper` cidr1)
433 cidr1 = cidr_from_string "10.1.1.0/23"
436 test_adjacent1 :: Test
438 TestCase $ assertEqual "10.1.0.0/24 is adjacent to 10.1.1.0/24" True (cidr1 `adjacent` cidr2)
440 cidr1 = cidr_from_string "10.1.0.0/24"
441 cidr2 = cidr_from_string "10.1.1.0/24"
444 test_adjacent2 :: Test
446 TestCase $ assertEqual "10.1.0.0/23 is not adjacent to 10.1.0.0/24" False (cidr1 `adjacent` cidr2)
448 cidr1 = cidr_from_string "10.1.0.0/23"
449 cidr2 = cidr_from_string "10.1.0.0/24"
452 test_adjacent3 :: Test
454 TestCase $ assertEqual "10.1.0.0/24 is not adjacent to 10.2.5.0/24" False (cidr1 `adjacent` cidr2)
456 cidr1 = cidr_from_string "10.1.0.0/24"
457 cidr2 = cidr_from_string "10.2.5.0/24"
460 test_adjacent4 :: Test
462 TestCase $ assertEqual "10.1.1.0/24 is not adjacent to 10.1.2.0/24" False (cidr1 `adjacent` cidr2)
464 cidr1 = cidr_from_string "10.1.1.0/24"
465 cidr2 = cidr_from_string "10.1.2.0/24"
468 test_combine_contained1 :: Test
469 test_combine_contained1 =
470 TestCase $ assertEqual "10.0.0.0/8, 10.1.0.0/16, and 10.1.1.0/24 combine to 10.0.0.0/8" expected_cidrs (combine_contained test_cidrs)
472 cidr1 = cidr_from_string "10.0.0.0/8"
473 cidr2 = cidr_from_string "10.1.0.0/16"
474 cidr3 = cidr_from_string "10.1.1.0/24"
475 expected_cidrs = [cidr1]
476 test_cidrs = [cidr1, cidr2, cidr3]
479 test_combine_contained2 :: Test
480 test_combine_contained2 =
481 TestCase $ assertEqual "192.168.3.0/23 does not contain 192.168.1.0/24" [cidr1, cidr2] (combine_contained [cidr1, cidr2])
483 cidr1 = cidr_from_string "192.168.3.0/23"
484 cidr2 = cidr_from_string "192.168.1.0/24"
487 test_combine_all1 :: Test
489 TestCase $ assertEqual "10.0.0.0/24 is adjacent to 10.0.1.0/24 and 10.0.3.0/23 contains 10.0.2.0/24" expected_cidrs (combine_all test_cidrs)
491 cidr1 = cidr_from_string "10.0.0.0/24"
492 cidr2 = cidr_from_string "10.0.1.0/24"
493 cidr3 = cidr_from_string "10.0.2.0/24"
494 cidr4 = cidr_from_string "10.0.3.0/23"
495 cidr5 = cidr_from_string "10.0.0.0/23"
496 expected_cidrs = [cidr4, cidr5]
497 test_cidrs = [cidr1, cidr2, cidr3, cidr4]
500 test_combine_all2 :: Test
502 TestCase $ assertEqual "127.0.0.1/32 combines with itself recursively" expected_cidrs (combine_all test_cidrs)
504 cidr1 = cidr_from_string "127.0.0.1/32"
505 expected_cidrs = [cidr1]
506 test_cidrs = [cidr1, cidr1, cidr1, cidr1, cidr1]
510 cidr_tests = [ test_equality1,
513 test_contains_proper1,
514 test_contains_proper2,
519 test_combine_contained1,
520 test_combine_contained2,
527 prop_all_cidrs_contain_themselves :: Cidr -> Bool
528 prop_all_cidrs_contain_themselves cidr1 = cidr1 `contains` cidr1
531 -- If cidr1 properly contains cidr2, then by definition cidr2
532 -- does not properly contain cidr1.
533 prop_contains_proper_intransitive :: Cidr -> Cidr -> Property
534 prop_contains_proper_intransitive cidr1 cidr2 =
535 (cidr1 `contains_proper` cidr2) ==>
536 (not (cidr2 `contains_proper` cidr1))