From 87bc2f172d87fff042dc493e16419687518c3866 Mon Sep 17 00:00:00 2001 From: Nick Mathewson Date: Tue, 5 Feb 2019 07:10:23 -0500 Subject: Convert prop299 to unix line-endings --- proposals/299-ip-failure-count.txt | 234 ++++++++++++++++++------------------- 1 file changed, 117 insertions(+), 117 deletions(-) (limited to 'proposals/299-ip-failure-count.txt') diff --git a/proposals/299-ip-failure-count.txt b/proposals/299-ip-failure-count.txt index 99d2534..60d35d4 100644 --- a/proposals/299-ip-failure-count.txt +++ b/proposals/299-ip-failure-count.txt @@ -1,117 +1,117 @@ -Filename: 299-ip-failure-count.txt -Title: Preferring IPv4 or IPv6 based on IP Version Failure Count -Author: Neel Chauhan -Created: 25-Jan-2019 -Status: Open -Ticket: https://trac.torproject.org/projects/tor/ticket/27491 - -1. Introduction - - As IPv4 address space becomes scarce, ISPs and organizations will deploy - IPv6 in their networks. Right now, Tor clients connect to guards using - IPv4 connectivity by default. - - When networks first transition to IPv6, both IPv4 and IPv6 will be enabled - on most networks in a so-called "dual-stack" configuration. This is to not - break existing IPv4-only applications while enabling IPv6 connectivity. - However, IPv6 connectivity may be unreliable and clients should be able - to connect to the guard using the most reliable technology, whether IPv4 - or IPv6. - - In ticket #27490, we introduced the option ClientAutoIPv6ORPort which adds - preliminary "happy eyeballs" support. If set, this lets a client randomly - choose between IPv4 or IPv6. However, this random decision does not take - into account unreliable connectivity or network failures of an IP family. - A successful Tor implementation of the happy eyeballs algorithm requires - that unreliable connectivity on IPv4 and IPv6 are taken into consideration. - - This proposal describes an algorithm to take into account network failures - in the random decision used for choosing an IP family and the data fields - used by the algorithm. - -2. Failure Counter Design - - I propose that the failure counter uses the following fields: - - * IPv4 failure count - - * IPv4 failure count from no route (autofail) - - * IPv6 failure count - - * IPv6 failure count from no route (autofail) - - These entries will exist as internal counters for the current session, and - as a list of the previous counts of these counters from previous sessions in - the state file. - - These values will be stored as 32-bit unsigned integers for the current - session, and as comma seperated values in the statefile. - - The list capacity will be the 4 most recent sessions for each field above - stored in the state file with the least recent first. This is for the - following reasons: - - * We can forget about the oldest sessions without having to keep the - exact timestamp when a client failed. This prevents an attacker from - getting detailed failure information from the state file. - - * Some clients (mobile phones, laptops) may switch between networks of - which may be more or less reliable than the previous in terms of IPv4 - or IPv6. In this case, it makes less sense to remember old failures - caused on a different network from the current one. - - When Tor is being closed, and there are less than four entries for each - field, we will append the current session at the end. If there are four - entries, we will remove the oldest entry and then add the current session's - values at Tor's shutdown. - -3. Failure Probability Calculation - - The failure count of one IP version will increase the probability of the - other IP version. For instance, a failure of IPv4 will increase the IPv6 - probability, and vice versa. - - When the IP version is being chosen, I propose that these values will be - included in the guard selection code: - - * IPv4 failure points - - * IPv6 failure points - - * Total failure points - - These values will be stored as 32-bit unsigned integers. - - A generic failure of an IP version will add one point to the failure point - count values of the particular IP version which failed. - - A failure of an IP version from a "no route" error which happens when - connections automatically fail will be counted as two failure points - for the automatically failed version. - - The failure points for both IPv4 and IPv6 is sum of the values in the state - file plus the current session's failure values. The total failure points is - a sum of the IPv4 and IPv6 failure points. - - The probability of a particular IP version is the failure points of the - other version divided by the total number of failure points, multiplied - by 8 and stored as an integer. We will call this value the summarized - failure point value (SFPV). The reason for this summarization is to - emulate a probability in 1/8 intervals by the random number generator. - - In the random number generator, we will choose a random number between 0 - and 8. If the random number is less than the IPv6 SFPV, we will choose - IPv4. If it is equal or greater, we will choose IPv6. - - If the probability is 0/8 with a SFPV value of 0, it will be rounded to - 1/8 with a SFPV of 1. Also, if the probability is 8/8 with a SFPV of 8, - it will be rounded to 7/8 with a SFPV of 7. The reason for this is to - accomodate mobile clients which could change networks at any time (e.g. - WiFi to cellular) which may be more or less reliable in terms of a - particular IP family when compared to the previous network of the client. - -4. Acknowledgements - - Thank you teor for aiding me with the implementation of Happy Eyeballs in - Tor. This would not have been possible if it weren't for you. +Filename: 299-ip-failure-count.txt +Title: Preferring IPv4 or IPv6 based on IP Version Failure Count +Author: Neel Chauhan +Created: 25-Jan-2019 +Status: Open +Ticket: https://trac.torproject.org/projects/tor/ticket/27491 + +1. Introduction + + As IPv4 address space becomes scarce, ISPs and organizations will deploy + IPv6 in their networks. Right now, Tor clients connect to guards using + IPv4 connectivity by default. + + When networks first transition to IPv6, both IPv4 and IPv6 will be enabled + on most networks in a so-called "dual-stack" configuration. This is to not + break existing IPv4-only applications while enabling IPv6 connectivity. + However, IPv6 connectivity may be unreliable and clients should be able + to connect to the guard using the most reliable technology, whether IPv4 + or IPv6. + + In ticket #27490, we introduced the option ClientAutoIPv6ORPort which adds + preliminary "happy eyeballs" support. If set, this lets a client randomly + choose between IPv4 or IPv6. However, this random decision does not take + into account unreliable connectivity or network failures of an IP family. + A successful Tor implementation of the happy eyeballs algorithm requires + that unreliable connectivity on IPv4 and IPv6 are taken into consideration. + + This proposal describes an algorithm to take into account network failures + in the random decision used for choosing an IP family and the data fields + used by the algorithm. + +2. Failure Counter Design + + I propose that the failure counter uses the following fields: + + * IPv4 failure count + + * IPv4 failure count from no route (autofail) + + * IPv6 failure count + + * IPv6 failure count from no route (autofail) + + These entries will exist as internal counters for the current session, and + as a list of the previous counts of these counters from previous sessions in + the state file. + + These values will be stored as 32-bit unsigned integers for the current + session, and as comma seperated values in the statefile. + + The list capacity will be the 4 most recent sessions for each field above + stored in the state file with the least recent first. This is for the + following reasons: + + * We can forget about the oldest sessions without having to keep the + exact timestamp when a client failed. This prevents an attacker from + getting detailed failure information from the state file. + + * Some clients (mobile phones, laptops) may switch between networks of + which may be more or less reliable than the previous in terms of IPv4 + or IPv6. In this case, it makes less sense to remember old failures + caused on a different network from the current one. + + When Tor is being closed, and there are less than four entries for each + field, we will append the current session at the end. If there are four + entries, we will remove the oldest entry and then add the current session's + values at Tor's shutdown. + +3. Failure Probability Calculation + + The failure count of one IP version will increase the probability of the + other IP version. For instance, a failure of IPv4 will increase the IPv6 + probability, and vice versa. + + When the IP version is being chosen, I propose that these values will be + included in the guard selection code: + + * IPv4 failure points + + * IPv6 failure points + + * Total failure points + + These values will be stored as 32-bit unsigned integers. + + A generic failure of an IP version will add one point to the failure point + count values of the particular IP version which failed. + + A failure of an IP version from a "no route" error which happens when + connections automatically fail will be counted as two failure points + for the automatically failed version. + + The failure points for both IPv4 and IPv6 is sum of the values in the state + file plus the current session's failure values. The total failure points is + a sum of the IPv4 and IPv6 failure points. + + The probability of a particular IP version is the failure points of the + other version divided by the total number of failure points, multiplied + by 8 and stored as an integer. We will call this value the summarized + failure point value (SFPV). The reason for this summarization is to + emulate a probability in 1/8 intervals by the random number generator. + + In the random number generator, we will choose a random number between 0 + and 8. If the random number is less than the IPv6 SFPV, we will choose + IPv4. If it is equal or greater, we will choose IPv6. + + If the probability is 0/8 with a SFPV value of 0, it will be rounded to + 1/8 with a SFPV of 1. Also, if the probability is 8/8 with a SFPV of 8, + it will be rounded to 7/8 with a SFPV of 7. The reason for this is to + accomodate mobile clients which could change networks at any time (e.g. + WiFi to cellular) which may be more or less reliable in terms of a + particular IP family when compared to the previous network of the client. + +4. Acknowledgements + + Thank you teor for aiding me with the implementation of Happy Eyeballs in + Tor. This would not have been possible if it weren't for you. -- cgit v1.2.3-54-g00ecf