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+ branches/release-2.1 -> 2.2 base + 3.0 -> branches/cxxconversion + backport some immediate 3.0 functionality for 2.2 + other stuff
316 lines
12 KiB
Text
316 lines
12 KiB
Text
$Id: CIDR.txt 6 2005-09-10 01:02:21Z nenolod $
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CIDR Information
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----------------
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Presently, we all use IPv4. The format of IPv4 is the following:
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A.B.C.D
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Where letters 'A' through 'D' are 8-bit values. In English, this
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means each digit can have a value of 0 to 255. Example:
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129.56.4.234
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Digits are called octets. Oct meaning 8, hence 8-bit values. An
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octet cannot be greater than 255, and cannot be less than 0 (eg. a
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negative number).
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CIDR stands for "classless inter domain routing", details covered
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in RFC's 1518 and 1519. It was introduced mainly due to waste within
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A and B classes space. The goal was to make it possible to use
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smaller nets than it would seem from (above) IP classes, for instance
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by dividing one B class into 256 "C like" classes. The other goal was
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to allow aggregation of routing information, so that routers could use
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one aggregated route (like 194.145.96.0/20) instead of
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advertising 16 C classes.
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Class A are all these addresses which first bit is "0",
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bitmap: 0nnnnnnn.hhhhhhhh.hhhhhhhh.hhhhhhhh (n=net, h=host)
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IP range is 0.0.0.0 - 127.255.255.255
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Class B are all these addresses which first two bits are "10",
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bitmap: 10nnnnnn.nnnnnnnn.hhhhhhhh.hhhhhhhh (n=net, h=host)
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IP range is 128.0.0.0 - 191.255.255.255
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Class C are all these addresses which first three bits are "110",
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bitmap: 110nnnnn.nnnnnnnn.nnnnnnnn.hhhhhhhh (n=net, h=host)
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IP range is 192.0.0.0 - 223.255.255.255
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Class D are all these addresses which first four bits are "1110",
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this is multicast class and net/host bitmap doesn't apply here
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IP range is 224.0.0.0 - 239.255.255.255
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I bet they will never IRC, unless someone creates multicast IRC :)
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Class E are all these addresses which first five bits are "11110",
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this class is reserved for future use
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IP range is 240.0.0.0 - 247.255.255.255
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So, here is how CIDR notation comes into play.
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For those of you who have real basic exposure to how networks are
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set up, you should be aware of the term "netmask." Basically, this
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is a IPv4 value which specifies the "size" of a network. You can
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assume the word "size" means "range" if you want.
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A chart describing the different classes in CIDR format and their
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wildcard equivalents would probably help at this point:
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CIDR version dot notation (netmask) Wildcard equivalent
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-----------------------------------------------------------------
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A.0.0.0/8 A.0.0.0/255.0.0.0 A.*.*.* or A.*
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A.B.0.0/16 A.B.0.0/255.255.0.0 A.B.*.* or A.B.*
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A.B.C.0/24 A.B.C.0/255.255.255.0 A.B.C.* or A.B.C.*
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A.B.C.D/32 A.B.C.D/255.255.255.255 A.B.C.D
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The question on any newbies mind at this point is "So what do all
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of those values & numbers actually mean?"
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Everything relating to computers is based on binary values (1s and
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zeros). Binary plays a *tremendous* role in CIDR notation. Let's
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break it down to the following table:
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A B C D
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-------- -------- -------- --------
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/8 == 11111111 . 00000000 . 00000000 . 00000000 == 255.0.0.0
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/16 == 11111111 . 11111111 . 00000000 . 00000000 == 255.255.0.0
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/24 == 11111111 . 11111111 . 11111111 . 00000000 == 255.255.255.0
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/32 == 11111111 . 11111111 . 11111111 . 11111111 == 255.255.255.255
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The above is basically a binary table for the most common netblock
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sizes. The "1"s you see above are the 8-bit values for each octet.
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If you split an 8-bit value into each of it's bits, you find the
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following:
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00000000
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^^^^^^^^_ 1sts place (1)
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|||||||__ 2nds place (2)
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||||||___ 3rds place (4)
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|||||____ 4ths place (8)
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||||_____ 5ths place (16)
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|||______ 6ths place (32)
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||_______ 7ths place (64)
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|________ 8ths place (128)
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Now, since computers consider zero a number, you pretty much have
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to subtract one (so-to-speak; this is not really how its done, but
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just assume it's -1 :-) ) from all the values possible. Some
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examples of decimal values in binary:
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15 == 00001111 (from left to right: 8+4+2+1)
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16 == 00010000 (from left to right: 16)
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53 == 00110101 (from left to right: 32+16+4+1)
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79 == 01001111 (from left to right: 64+8+4+1)
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254 == 11111110 (from left to right: 128+64+32+16+8+4+2)
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So, with 8 bits, the range (as I said before) is zero to 255.
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If none of this is making sense to you at this point, you should
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back up and re-read all of the above. I realize it's a lot, but
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it'll do you some good to re-read it until you understand :-).
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So, let's modify the original table a bit by providing CIDR info
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for /1 through /8:
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A B C D
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-------- -------- -------- --------
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/1 == 10000000 . 00000000 . 00000000 . 00000000 == 128.0.0.0
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/2 == 11000000 . 00000000 . 00000000 . 00000000 == 192.0.0.0
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/3 == 11100000 . 00000000 . 00000000 . 00000000 == 224.0.0.0
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/4 == 11110000 . 00000000 . 00000000 . 00000000 == 240.0.0.0
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/5 == 11111000 . 00000000 . 00000000 . 00000000 == 248.0.0.0
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/6 == 11111100 . 00000000 . 00000000 . 00000000 == 252.0.0.0
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/7 == 11111110 . 00000000 . 00000000 . 00000000 == 254.0.0.0
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/8 == 11111111 . 00000000 . 00000000 . 00000000 == 255.0.0.0
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At this point, all of this should making a lot of sense, and you
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should be able to see the precision that you can get by using CIDR
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at this point. If not, well, I guess the best way to put it would
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be that wildcards always assume /8, /16, or /24 (yes hello Piotr,
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we can argue this later: I am referring to IPs *ONLY*, not domains
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or FQDNs :-) ).
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This table will provide a reference to all of the IPv4 CIDR values
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cidr|netmask (dot notation)
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----+---------------------
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/1 | 128.0.0.0
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/2 | 192.0.0.0
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/3 | 224.0.0.0
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/4 | 240.0.0.0
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/5 | 248.0.0.0
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/6 | 252.0.0.0
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/7 | 254.0.0.0
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/8 | 255.0.0.0
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/9 | 255.128.0.0
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/10 | 255.192.0.0
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/11 | 255.224.0.0
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/12 | 255.240.0.0
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/13 | 255.248.0.0
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/14 | 255.252.0.0
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/15 | 255.254.0.0
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/16 | 255.255.0.0
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/17 | 255.255.128.0
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/18 | 255.255.192.0
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/19 | 255.255.224.0
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/20 | 255.255.240.0
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/21 | 255.255.248.0
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/22 | 255.255.252.0
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/23 | 255.255.254.0
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/24 | 255.255.255.0
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/25 | 255.255.255.128
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/26 | 255.255.255.192
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/27 | 255.255.255.224
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/28 | 255.255.255.240
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/29 | 255.255.255.248
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/30 | 255.255.255.252
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/31 | 255.255.255.254
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/32 | 255.255.255.255
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So, let's take all of the information above, and apply it to a
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present-day situation on IRC.
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Let's say you have a set of flooding clients who all show up from
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the following hosts. For lack-of a better example, I'll use a
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subnet here at Best:
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nick1 (xyz@shell9.ba.best.com) [206.184.139.140]
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nick2 (abc@shell8.ba.best.com) [206.184.139.139]
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nick3 (foo@shell12.ba.best.com) [206.184.139.143]
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Most people will assume the they were all in the same class C
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(206.184.139.0/24 or 206.184.139.*).
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This, as a matter of fact, is not true. Now, the reason *I* know
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this is solely because I work on the network here; those IPs are
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not delegated to a class C, but two portions of a class C (128 IPs
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each). That means the class C is actually split into these two
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portions:
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Netblock IP range
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-------- --------
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206.184.139.0/25 206.184.139.0 to 206.184.139.127
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206.184.139.128/25 206.184.139.128 to 206.184.139.255
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For the record, 206.184.139.0 and 206.184.139.128 are both known as
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"network addresses" (not to be confused with "netblocks" or "Ethernet
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hardware addresses" or "MAC addresses"). Network addresses are
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*ALWAYS EVEN*.
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206.184.139.127 and 206.184.139.255 are what are known as broadcast
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addresses. Broadcast addresses are *ALWAYS ODD*.
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Now, the aforementioned list of clients are in the 2nd subnet shown
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above, not the first. The reason for this should be obvious.
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The remaining question is, "Well that's nice, you know what the netblock
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is for Best. What about us? We don't know that!"
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Believe it or not, you can find out the network block size by using
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whois -h WHOIS.ARIN.NET on the IP in question. ARIN keeps a list of
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all network blocks and who owns them -- quite useful, trust me. I
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think I use ARIN 5 or 6 times a day, especially when dealing with
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D-lines. Example:
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$ whois -h whois.arin.net 206.184.139.140
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Best Internet Communications, Inc. (NETBLK-NBN-206-184-BEST)
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345 East Middlefield Road
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Mountain View, CA 94043
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Netname: NBN-206-184-BEST
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Netblock: 206.184.0.0 - 206.184.255.255
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Maintainer: BEST
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Does this mean you should D-line 206.184.0.0/16? Probably not.
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That's an entire class B-sized block, while you're only trying
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to deny access to a subnetted class C.
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So then how do you get the *real* info? Well, truth is, you don't.
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You have to pretty much take a guess at what it is, if ARIN reports
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something that's overly vague. Best, for example, was assigned the
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above class B-sized block. We can subnet it however we want without
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reporting back to ARIN how we have it subnetted. We own the block,
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and that's all that matters (to ARIN).
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Not all subnets are like this, however. Smaller subnets you may
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find partitioned and listed on ARIN; I've seen /29 blocks for DSL
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customers show up in ARIN before.
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So, use ARIN any chance you get. The more precision the better!
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Now, there is a small issue I want to address regarding use of CIDR
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notation. Let's say you D-line the following in CIDR format (hi
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sion ;-) ):
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205.100.132.18/24
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Entries like this really makes my blood boil, solely because it adds
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excessive confusion and is just basically pointless. If you
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examine the above, you'll see the /24 is specifying an entire
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class C -- so then what's the purpose of using .18 versus .0?
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There IS no purpose. The netmask itself will mask out the .18 and
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continue to successfully use 205.100.132.0/24.
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Doing things this way just adds confusion, especially on non-octet-
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aligned subnets (such as /8, /16, /24, or /32). Seeing that on a
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/27 or a /19 might make people go "wtf?"
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I know for a fact this doc lacks a lot of necessary information,
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like how the actual netmask/CIDR value play a role in "masking out"
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the correct size, and what to do is WHOIS.ARIN.NET returns no
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netblock information but instead a few different company names with
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NIC handles. I'm sure you can figure this stuff out on your own,
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or just ask an administrator friend of yours who DOES know. A lot
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of us admins are BOFH types, but if you ask us the right questions,
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you'll benefit from the answer quite thoroughly.
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Oh, I almost forgot. Most Linux systems use a different version of
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"whois" than FreeBSD does. The syntax for whois on Linux is
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"whois <INFO>@whois.arin.net", while under FreeBSD it is
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"whois -h whois.arin.net <INFO>" Debian uses yet another version
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of whois that is incompatible with the above syntax options.
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Note that the FreeBSD whois client has shortcuts for the most commonly
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used whois servers. "whois -a <INFO>" is the shortcut for ARIN.
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Also note that ARIN is not authoritative for all IP blocks on the
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Internet. Take for example 212.158.123.66. A whois query to ARIN
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will return the following information:
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$ whois -h whois.arin.net 212.158.123.66
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European Regional Internet Registry/RIPE NCC (NET-RIPE-NCC-)
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These addresses have been further assigned to European users.
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Contact information can be found in the RIPE database, via the
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WHOIS and TELNET servers at whois.ripe.net, and at
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http://www.ripe.net/db/whois.html
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Netname: RIPE-NCC-212
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Netblock: 212.0.0.0 - 212.255.255.255
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Maintainer: RIPE
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This query tells us that it is a European IP block, and is further
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handled by RIPE's whois server. We must then query whois.ripe.net
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to get more information.
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$ whois -h whois.ripe.net 212.158.123.66
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% Rights restricted by copyright. See
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http://www.ripe.net/ripencc/pub-services/db/copyright.html
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inetnum: 212.158.120.0 - 212.158.123.255
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netname: INSNET-P2P
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descr: Point to Point Links for for London Nodes
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country: GB
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--snip--
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This tells us the actual IP block that the query was a part of.
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Other whois servers that you may see blocks referred to are:
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whois.ripn.net for Russia, whois.apnic.net for Asia, Australia, and
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the Pacific, and whois.6bone.net for IPv6 blocks.
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Contributed by Jeremy Chadwick <jdc@best.net>
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Piotr Kucharski <chopin@sgh.waw.pl>
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W. Campbell <wcampbel@botbay.net> and
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Ariel Biener <ariel@fireball.tau.ac.il>
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