From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc1219.txt | 731 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 731 insertions(+) create mode 100644 doc/rfc/rfc1219.txt (limited to 'doc/rfc/rfc1219.txt') diff --git a/doc/rfc/rfc1219.txt b/doc/rfc/rfc1219.txt new file mode 100644 index 0000000..4a4981e --- /dev/null +++ b/doc/rfc/rfc1219.txt @@ -0,0 +1,731 @@ + + + + + + +Network Working Group P. Tsuchiya +Request for Comments: 1219 Bellcore + April 1991 + + + On the Assignment of Subnet Numbers + +Status Of This Memo + + This memo suggests a new procedure for assigning subnet numbers. Use + of this assignment technique within a network would be a purely local + matter, and would not effect other networks. Therefore, the use of + these procedures is entirely discretionary. + + This memo provides information for the Internet community. It does + not specify an Internet standard. Distribution of this memo is + unlimited. + +Overview + + RFC-950 [2] specifies a procedure for subnetting Internet addresses + using a bit-mask. While RFC-950 allows the "ones" in the subnet mask + to be non-contiguous, RFC-950 recommends that 1) they be contiguous, + and 2) that they occupy the most significant bits of the "host" part + of the internet address. + + RFC-950 did not specify whether different subnets of the same network + may have different masks. This ambiguity was unfortunate, as it + resulted in development of routing protocols that do not support + different masks; see e.g., RIP [6]. The Gateway Requirements RFC [7] + settled the issue in favor of allowing different masks, and therefore + future routing protocols may be expected to support this feature; + OSPF [3] is an example. + + The network administrator must of course determine the mask for each + subnet. This involves making an estimate of how many hosts each + subnet is expected to have. As it is often impossible to predict how + large each subnet will grow, inefficient choices are often made, with + some subnets under-utilized, and others possibly requiring + renumbering because of exceeded capacity. + + This memo specifies a procedure for assigning subnet numbers that + eliminates the need to estimate subnet size. Essentially, host bits + (mask = 0) are assigned from the least significant bit working + towards the most, and subnet bits (mask = 1) are assigned from the + most significant bit working towards the least. As subnets grow, + more host bits are assigned. As the number of subnets grows, more + subnet bits are assigned. While this process does sometimes result + + + +Tsuchiya [Page 1] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + in new subnet masks, no host ever need change addresses. + + This technique is not new, but it is also not widely known, and even + less widely implemented. With the development of new routing + protocols such as OSPF, it is possible to take full advantage of this + technique. The purpose of this memo, then, is to make this technique + widely known, and to specify it exactly. + + This memo requires no changes to existing Internet standards. It + does, however, require that the intra-domain routing protocol handle + multiple different subnet masks. + +Acknowledgments + + The author would like to thank Phil Karn, Charles Lynn, Jeff Mogul, + and Charles Wolverton for their helpful suggestions. Special thanks + go to Joel Halpern for his painstaking debugging of the detailed + specification and the examples. + +1. Motivation + + The Subnetting standard, RFC-950, specifies that the Host part of the + formally 2-level Internet address can be divided into two fields, + Subnet and Host. This gives the Internet address a third level of + hierarchy, and the concomitant firewalls and savings in routing + overhead. It also introduces increased inefficiency in the + allocation of addresses. + + This inefficiency arises from the fact that the network administrator + typically over-estimates the size (number of hosts) of any single + subnetwork, in order to prevent future re-addressing of subnets. It + may also occur if the routing protocol being used does not handle + different length subnets, and the administrator must therefore give + every subnet an amount of space equivalent to that received by the + largest subnet. (This RFC does not help in the latter case, as the + technique herein requires different length subnets.) + + The administrative hassle associated with changing the subnet + structure of a network can be considerable. For instance, consider + the following case. A network has three subnets A, B, and C. Assume + that the lowest significant byte is the host part, and the next byte + is the subnet part (that is, the mask is 255.255.255.0). Assume + further that A has subnet 1.0, B has subnet 2.0, and C has subnet + 3.0. + + Now, assume that B grows beyond its allocation of 254 hosts. + Ideally, we would like to simply change B's mask without changing any + of the host addresses in B. However, the subnets numerically above + + + +Tsuchiya [Page 2] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + and below B are already taken by A and C. (If say 3.0 was not taken + by C, B's mask could be changed from 255.0 (ff00) to 254.0 (fe00). + In this case, all of B's existing addresses would still match the new + subnet. Indeed, if non-contiguous masks were in use, it might be + possible for B to find some other mask bit to change to 0. However, + non-contiguous masks are generally not in favor, as they impose + limitations on certain forwarding table lookup algorithms. Indeed, + RFC-950 discourages their use.) + + So, the choices available to the network administrator are to 1) form + two subnets out of the existing one, or 2) renumber the subnet so + that the subnet ends up with a smaller (fewer 1's) mask. Choice 1 + can either be accomplished physically or logically. Physically + forming two subnets requires partitioning the subnet and inserting a + gateway between the two partitions. For obvious reasons, this is not + a desirable course of action. Logically forming two subnets can be + done by simply assigning another subnet number (say 4.0) to the same + subnet, and assigning host addresses under the new subnet. The + result of this logical partition is that the hosts with different + subnet numbers will not recognize that the others are on the same + subnet, and will send packets to the default gateway rather than + directly to the host. In fact, this is not such a bad solution, + because assuming that the gateway is capable of recognizing multiple + subnet numbers on the same subnet, the gateway will simply send the + host an ICMP Redirect [4], and subsequent packets will go directly to + the host [1] (this may not work correctly on all hosts). + + If, however, neither choice is acceptable or possible, then the + network administrator must assign a new subnet number to B, thus + renumbering the existing hosts, modifying the Domain Name System + entries, and changing any other configuration files that have + hardwired addresses for hosts in subnet B. + +2. A More Flexible and Efficient Technique for Assigning Subnet Numbers + + In order to help explain the new technique, we shall show what is + wrong with what is currently done now. Currently, most subnets are + assigned by splitting the host part of the address in two fields; the + subnet field and the host field. Mask bits are one for subnet field + bits, and 0 for host field bits. (In all of our addresses, the least + significant bit (LSB) is on the right, the most significant bit (MSB) + is on the left.) + + MSB LSB + -------------------------------------- + | subnet field | host field | + -------------------------------------- + + + + +Tsuchiya [Page 3] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + The subnet field could be different lengths for different size + subnets. For instance, say a network had two large subnets and the + rest small subnets (by large subnet we mean a large number of hosts). + Then the network administrator might assign two types of addresses: + + -------------------------------------- + | subnet | host | large subnets + -------------------------------------- + + -------------------------------------- + | subnet | host | small subnets + -------------------------------------- + + In this case, the full range of subnet numbers would not be available + to the small subnets, as the bits in the small subnet that correspond + to those in the large subnet could not have the same values as those + in the large subnets. For instance, say that the large subnets had + 4-bit subnet numbers, and the small subnets had 8-bit subnet numbers. + If the large subnets had values 0001 and 0010, then subnet numbers in + the range 00010000 to 00101111 could not be assigned to the small + subnets, otherwise there will be addresses that would match both + subnets. + + In any event, a network administrator will typically assign values to + the two fields in numerical order. For example, within a given + subnet, hosts will be numbered 1, 2, 3, etc. Within a given network, + subnets will be numbered 1, 2, 3, etc. The result is that some + number of bits on the right side of the subnet and host fields will + be ones for some hosts and zeros for others, and some number of bits + on the left side of the subnet and host fields will be zeros for all + subnets and hosts. The "all zeros" bits represent room for growth, + and the "ones and zeros" bits represent bits already consumed by + growth. + + -------------------------------------- + | subnet field | host field | + |-----+-----------+-------+------------| + | | | | | + | 0's | 1's & 0's | 0's | 1's & 0's | + /\ /\ + || || + subnets can hosts can grow here + grow here + + Now, let's assume that the number of hosts in a certain subnet grows + to the maximum allowed, but that there is still room in the subnet + field to assign more addresses. We then have the following: + + + + +Tsuchiya [Page 4] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + -------------------------------------- + | subnet field | host field | + |-----+-----------+--------------------| + | | | | + | 0's | 1's & 0's | 1's & 0's | + + + While the host field can no longer grow, there is still room in the + address for growth. The problem is that because of where the growth + areas are situated, the remaining growth has been effectively + reserved for subnets only. + + What should be done instead is to assign subnet numbers so that the + ones start from the left of the subnet field and work right. In this + case we get the following: + + -------------------------------------- + | subnet field | host field | + |-----------+-------------+------------| + | | | | + | 1's & 0's | 0's | 1's & 0's | + /\ + || + Both hosts and subnets can + grow here + + Now, both hosts and subnets individually have considerably more + growing space than before, although the combined growing space is the + same. Since one can rarely predict how many hosts might end up in a + subnet, or how many subnets there might eventually be, this + arrangement allows for the maximum flexibility in growth. + + Actually, the previous figure is misleading. The boundary between + the host and subnet fields is being shown in the middle of the growth + area. However, the boundary could exist anywhere within the growth + area. Note that it is the mask itself that determines where the + boundary is. Ones in the mask indicate subnet bits, and zeros + indicate host bits. We will show later that in fact the boundary + should lie somewhere in the middle. Putting it there minimizes the + number of times that the masks must be changed in hosts. + + 2.1 Specification of the New Technique + + Having given the appropriate explanatory material, we can now specify + the procedure for subnet number assignment. We need the following + definitions: + + Host-assigned Bits (h-bits): These are the bits, contiguous from + + + +Tsuchiya [Page 5] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + the right, for which host values, within a given subnet, contain + both ones and zeros. Different subnets may have different h-bits. + + Subnet-assigned Bits (s-bits): These are the bits, contiguous from + the left, which 1) are not h-bits, AND 2) are required to + distinguish one subnet from another, AND 3) include all bits + to the left of and including the right-most one. Notice that + different subnets may have different s-bits. + + Growth Bits (g-bits): These are the "all zeros" bits in between + the h-bits and s-bits. + + s-mask: For a given subnet, the mask whereby all s-bits are one, + and all g-bits and h-bits are zero. + + g-mask: For a given subnet, the mask whereby all s-bits and g-bits + are one, and all h-bits are zero. + + Subnet Field: These are the one bits in the subnet mask (as + defined in RFC-950). These bits are on the left. The subnet + field must at least include all of the s-bits, and may + additionally include some or all of the g-bits. + + Host Field: These are the zero bits in the subnet mask. + These bits are on the right. The host field must at least + include all of the h-bits, and may additionally include some + or all of the g-bits. + + Mirror-image Counting: Normal counting, in binary, causes one + bits to start at the right and work left. This is how host + values are assigned. However, for subnet assignment, we want + the one bits to start at the left and work right. This process + is the mirror image of normal counting, where the MSB is swapped + with the LSB, the second MSB is swapped with the second LSB, and + so on. So, where normal counting is: + + 0 (reserved to mean "this host") + 01 + 10 + 011 + 100 + 101 + : + : + 11...1110 + 11...1111 (reserved to mean "all hosts") + + and so on, Mirror-image, or MI counting, is: + + + +Tsuchiya [Page 6] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + 0 (reserved to mean "this subnet") + 10 + 01 + 110 + 001 + 101 + : + : + 011...11 + 111...11 (reserved to mean "all subnets") + + and so on. If the current MI counting value is, say, 001, + the "next" MI value is 101, and the "previous" MI value is 11. + + Now we can specify the algorithm. We have the following functions: + Initialize(), AddSubnet(), RemoveSubnet(subnet#), AddHost(subnet#), + and RemoveHost(subnet#,host#). + + Notice that the algorithm is described as though one state machine is + executing it. In reality, there may be a root Address Authority + (RootAA) that assigns subnet numbers (Initialize, AddSubnet, and + RemoveSubnet), and subnet AA, that assign host numbers within a + subnet (AddHost and RemoveHost). While in general the AAs can act + independently, there are two cases where "coordination" is required + between the rootAA and a subnetAA. These are the cases where either + the rootAA or the subnetAA "grabs" the last growth bit (in the former + case because another subnet has been added, and in the latter because + another host has been added). Since it is impossible for the rootAA + and a subnetAA to simultaneously grab the last growth bit, either one + or the other must do it. + + Finally, note that the following C language style notation is used: + & bit-wise AND function + == is equal to + != is not equal to + x-mask(X) the x-mask of X (where x is s or g) + + Initialize(): + Assign the first subnet value to be 0 (the value reserved to mean + "this subnet"). This is not assigned to any real subnet. + + AddSubnet(): + 1. Find the lowest non-zero (in MI counting) non-assigned subnet + number S such that (S & g-mask(Y)) != (Y & g-mask(Y)) for all + existing subnet numbers Y, (Y != S). + 2. If all bits in S from the rightmost one bit left are ones, + then label all bits to the left of and including one bit + position to the right of the rightmost one bit in S to be + + + +Tsuchiya [Page 7] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + s-bits. Else, label all bits to the left of and including the + rightmost one bit in S to be s-bits. This prevents the "all + ones" value (which is the "all subnets" broadcast address) + from being assigned to a subnet. (Since no hosts have been + added, the rightmost one bit is a subnet bit.) + 3. Label all other bits in the address to be g-bits. (By + address, we mean that part of the IP address not including + the network number.) + 4. Set the subnet mask to include at least all s-bits, and + optionally some g-bits. The subnet mask must be contiguous. + (Section 2.2 discusses the pros and cons of choosing a mask.) + 5. For all existing subnet numbers Y (Y != S): + 51. If (S & s-mask(Y)) == (Y & s-mask(Y)), then: + 511. Change the leftmost g-bit of Y to an s-bit. If + the rootAA and YAA (the address authority for Y) are + separate AAs, then the YAA must be informed of the + change of bit status. If this is the last g-bit, + then this change must be coordinated with YAA. + 512. Expand the subnet mask for all hosts in Y if + necessary (that is, if the subnet mask no longer + includes all s-bits). + + RemoveSubnet(S): + 1. Consider B to be the bit position of the rightmost s-bit in S. + 2. Remove S. + 3. For all existing subnet numbers Y: + 31. If the bit in position B is not an s-bit, or if the bit + in bit position B is a one, or if the bit in bit position + B is a zero and all bits to the left of bit position B + are ones, then do nothing (skip steps 32 and 33). + 32. Change the s-bit in position B to a g-bit. + 33. If for any other existing subnet numbers X + (X & s-mask(Y)) == (Y & s-mask(Y)), then change the + g-bit in position B back into an s-bit for Y. Else, + inform YAA that of the change of bit status. + + AddHost(S): + 1. Create an address A consisting of subnet number S concatenated + with zeros. + 2. Assign to A the same h-bits, g-bits, and s-bits as the + other host addresses. + 3. Find the lowest non-zero (using normal counting) non-assigned + host number H. + 4. If all bits from the leftmost one bit to bit position 0 are + ones, then execute steps 5 and 6 using bit position B equals + one bit position to the left of the leftmost one bit in H. + Else, execute steps 5 and 6 with bit position B equals + the leftmost one bit in H. This prevents the "all ones" value + + + +Tsuchiya [Page 8] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + (which is the "all hosts" broadcast address) from being + assigned to a host. + 5. If bit position B is an s-bit, then the host cannot be added. + Skip the remaining steps. + 6. If bit position B is a g-bit: + 61. Change the g-bit to an h-bit for all hosts in S. Note + that if this is the last g-bit, this change must be + coordinated with the address authority assigning subnet + numbers (see section 2.2). + 62. Modify the subnet mask in all hosts if necessary. + 7. Create a new address A consisting of S concatenated with H + 8. Assign A to the host. + + RemoveHost(S,H): + 1. Remove H. + 2. If for all remaining host numbers in S, the value of the bit + position of the leftmost h-bit is zero, and there is a zero in + at least one of the bit positions to the right of the leftmost + h-bit, then for all hosts change the leftmost h-bit into a + g-bit. + + It is worth noting here that this technique is a 2-level subset of + the more general n-level kampai addressing [5]. The main + difference here is that n-level kampai results in non-contiguous + masks, while 2-level does not. In the description of kampai + addressing in [5], g-bits are called a-bits, h-bits are called + g-bits, and s-bits are called i-bits. + + 2.2 An Example + + For this example, we assume a class C network, so we will only need + to work with 8 bits. We start with 3 subnets, A, B, and C. Our + nomenclature is h for h-bit and g for g-bit. Note that h-bits can be + one or zero, but g-bits are all zero. The remaining bits are s-bits, + but are shown as 1's and 0's according to the subnet number + assignment. The space is just to make the addresses and masks easier + to read. Finally, we number our bits 0 to 7 from right to left as + shown below. + + Subnet Address Mask + A 10gg ghhh 1111 0000 + B 01gg ghhh 1111 0000 + C 110g ghhh 1111 0000 + bit 7 bit 0 + + We see that each subnet has at most 6 hosts (because of the three h- + bits). Notice that we have chosen the masks so that there is room + for growth in both hosts and subnets without requiring a mask change. + + + +Tsuchiya [Page 9] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + However, we have generally allowed for more growth in subnets than in + hosts because adding new subnets can cause mask changes in existing + subnets, while adding new hosts in a subnet only causes that subnet's + mask to change. + + Further, if a subnet's mask must change, but not all hosts are + reconfigured at the same time, then it is less damaging if the not + yet reconfigured hosts have too large a mask (too many ones) than if + they have too small a mask. This is because with too large a mask, a + host may think that another host which is in fact on the subnet is on + another subnet. In this case, the host will send packets to the + gateway, and will be redirected to the host. + + However, with too small a mask, a host may think that another host + which is in fact not on the subnet is on the subnet, and will ARP for + that host but receive no reply. (Note that broadcasts may fail if + all masks do not match.) + + Finally, notice that subnet C requires three s-bits instead of just + two. This is because with just two, the subnet address of C could be + "11" (rather than "110"), which is a broadcast value. Step 2 of + AddSubnet checks for this case. + + Now, a fourth subnet, D, also with 6 hosts, is added. We get: + + Subnet Addr Mask + A 10gg ghhh 1111 0000 + B 01gg ghhh 1111 0000 + C 110g ghhh 1111 0000 + D 001g ghhh 1111 0000 + + Notice that none of the original subnets required a change in any of + their status bits. This is because, when D compared its subnet + number with the others (step 5 of AddSubnet(), using the s-mask), + they were all different. In other words, a router would be able to + distinguish an address in D from addresses in A, B, and C. + + Next, a fifth subnet, E, is added. We get: + + Subnet Addr Mask + A 100g ghhh 1111 0000 + B 01gg ghhh 1111 0000 + C 110g ghhh 1111 0000 + D 001g ghhh 1111 0000 + E 101g ghhh 1111 0000 + + Notice that this time, A was forced to change its leftmost g-bit (bit + 5) into an s-bit, because bit 5 is needed to distinguish subnet A + + + +Tsuchiya [Page 10] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + from subnet E (step 511 of AddSubnet()). Changing bit 5 into an s- + bit prevents hosts from being added to A to the point where bit 5 + would be changed into a one (that is, step 5 of AddHost() would + fail). + + Notice also that if the masks in A, B, and C were originally set to + 1100.0000, then the addition of E would have caused A's mask to + change to 1110.0000 (Step 512 of AddSubnet()). + + Next, 8 hosts each are added to subnets A and C, thus causing the + right-most g-bit in each to change to an h-bit. + + Subnet Addr Mask + A 100g hhhh 1111 0000 + B 01gg ghhh 1111 0000 + C 110g hhhh 1111 0000 + D 001g ghhh 1111 0000 + E 101g ghhh 1111 0000 + + Notice again that no masks have changed. If the masks for A, B, and + C were originally set to 1111 1000, then they would have required + changing (step 62 of AddHost()). + + Next, enough hosts are added to subnet B that all of its remaining + g-bits become h-bits. + + Subnet Addr Mask + A 100g hhhh 1111 0000 + B 01hh hhhh 1100 0000 + C 110g hhhh 1111 0000 + D 001g ghhh 1111 0000 + E 101g ghhh 1111 0000 + + Notice here that the masks in B's subnet had to be changed to + accommodate the new h-bits (step 62 of AddHost()). Notice also that + if the person assigning host addresses for B (B Address Authority, or + BAA) is different than the person assigning network numbers (RootAA), + then BAA must coordinate the change of its last g-bit to an h-bit + with the RootAA. This allows the RootAA to properly assign + additional subnet numbers, as in the next step, where we add another + subnet F: + + Subnet Addr Mask + A 100g hhhh 1111 0000 + B 01hh hhhh 1100 0000 + C 110g hhhh 1111 0000 + D 001g ghhh 1111 0000 + E 101g ghhh 1111 0000 + + + +Tsuchiya [Page 11] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + + F 1110 ghhh 1111 0000 + + Notice that F received subnet number 1110 rather than subnet number + 011 (which is what comes after 101 in MI counting). The reason is + that 1) 011 is not distinguishable from B's subnet address using B's + mask, and 2) we can't increase B's mask to make it distinguishable + because B has already assigned hosts at bit position 5. In other + words, when the comparison of step 1 in AddSubnet() was tried on + number 011, the two values were equal, and so the next number was + tried. In fact, no subnet numbers with 01 in bit positions 7 and 6 + can be assigned (unless B loses hosts). + + Next, subnet E is removed: + + Subnet Addr Mask + A 10gg hhhh 1111 0000 + B 01hh hhhh 1100 0000 + C 110g hhhh 1111 0000 + D 001g ghhh 1111 0000 + F 1110 ghhh 1111 0000 + + Notice that this caused subnet A to change an s-bit back into a g- + bit. This is because the equality of step 33 of RemoveSubnet() did + not hold true for subnet A with respect to the remaining subnets. + +References + + [1] Braden, R., "Requirements for Internet Hosts -- Communication + Layers", RFC 1122, USC/Information Sciences Institute, October + 1989. + + [2] Mogul, J., and J. Postel, "Internet Standard Subnetting + Procedure", RFC 950, USC/Information Sciences Institute, August + 1985. + + [3] Moy, J., "OSPF Specification", RFC 1131, Proteon, October 1989. + + [4] Postel, J., "Internet Control Message Protocol", RFC 792, + USC/Information Sciences Institute, September 1981. + + [5] Tsuchiya, P., "Efficient and Flexible Hierarchical Address + Assignment", TM-ARH-018495, Bellcore, February 1991. + + [6] Hedrick, C., "Routing Information Protocol" RFC 1058, Rutgers + University, June 1988. + + [7] Braden, R., and J. Postel, "Requirements for Internet Gateways", + RFC 1009, USC/Information Sciences Institute, June 1987. + + + +Tsuchiya [Page 12] + +RFC 1219 On the Assignment of Subnet Numbers April 1991 + + +Security Considerations + + Security issues are not discussed in this memo. + +Author's Address + + Paul F. Tsuchiya + Bellcore + 435 South St.5 South St. + MRE 2L-281 + Morristown, NJ 07960 + + Phone: 201 829-4484 + + EMail: tsuchiya@thumper.bellcore.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Tsuchiya [Page 13] + \ No newline at end of file -- cgit v1.2.3