IPv6 is big enough to give 10 billion unique addresses for every grain of sand on earth and still have some left over. Just in case we need to, I guess.
It’s great that the address space is so large. When designing a new system, you want to make sure it’ll hopefully never encounter the same issue as the old system, to ensure you don’t have to migrate yet again.
Sure. But the IPv6 implementation is a bit like if we went “you know the y2038 problem of 32 bit numbers, and how goin under 1970 is sometimes hard? Lets solve it by making it start from the big bang and store time as a 256 bit integer so we don’t run out until year 3.1 x 10^69”.
IPv6 is big enough for 340,282,366,920,938,463,463,374,607,431,768,211,456 unique addresses. Are we expecting to create an universe consuming army of exponentially replicating paper clip converting robots that each need an IPv6 address or something?
IPv6 is big enough to give 10 billion unique addresses for every grain of sand on earth and still have some left over. Just in case we need to, I guess.
It’s great that the address space is so large. When designing a new system, you want to make sure it’ll hopefully never encounter the same issue as the old system, to ensure you don’t have to migrate yet again.
Sure. But the IPv6 implementation is a bit like if we went “you know the y2038 problem of 32 bit numbers, and how goin under 1970 is sometimes hard? Lets solve it by making it start from the big bang and store time as a 256 bit integer so we don’t run out until year 3.1 x 10^69”.
IPv6 is big enough for 340,282,366,920,938,463,463,374,607,431,768,211,456 unique addresses. Are we expecting to create an universe consuming army of exponentially replicating paper clip converting robots that each need an IPv6 address or something?