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Note that <code>netresolve</code> is both the name of the command and the name of the library. The above tests are done using the command but the same results would be given to an application using the library. Unless you explicitly request, netresolve uses its internal name resolution modules and not the libc functions.
Note that <code>netresolve</code> is both the name of the command and the name of the library. The above tests are done using the command but the same results would be given to an application using the library. Unless you explicitly request, netresolve uses its internal name resolution modules and not the libc functions.
== Tools ==
Tools with issues:
* [https://bugzilla.redhat.com/show_bug.cgi?id=617934 ping: lack of IPv6 support]
* [https://bugzilla.redhat.com/show_bug.cgi?id=1221496 fping: lack of IPv6 support]
* [https://bugzilla.redhat.com/show_bug.cgi?id=1220700 tracepath: lack of IPv6 support]
* [https://bugzilla.redhat.com/show_bug.cgi?id=1220825 nslookup: bad default behavior]


== Testing client applications ==
== Testing client applications ==

Revision as of 07:38, 14 July 2015

Testing IPv6 support and dualstack networking can be very tricky. The purpose of this document is to provide a live resource on testing situations arising from existance and usage of two network layer protocols.

Base system components related to IPv6 and dual-stack operation:

  • kernel
  • glibc

Configuration

Name resolution (using libc functions)

Name resolution features are provided by the GNU C Library (glibc) which is not yet ready for proper IPv6 and dual-stack operation as you can see when performing your tests. The C library comes with its own testing tool getent that has a special database called ahosts that runs getaddrinfo(), the library function that translates names to objects with addressing information. For your testing it is best used together with tools like strace, ltrace or even gdb so that you know exactly what is happening behind the scenes.

As the getent tool is very primitive, we created a tool called getaddrinfo just as the library function that handles a larger subset of the function's API.

Name resolution input

When application requests addressing information for a hostname with an optional service name, the library returns a list of addressing information objects. The order of objects in the list is significant and depends on operating system configuration and connectivity.

From the application

  • nodename
  • servname
  • protocol
  • socktype
  • flags
    • AI_CANONNAME
    • ...

From local configuration and connectivity checks

  • Files in /etc/ including nsswitch, hosts, services and more
  • To what extend is IPv4 and IPv6 available

From the outside world

  • DNS information
  • Multicast DNS information
  • LDAP information

Name resolution processing

What is requested

Not all information is requested at all times. Some information like canonical name must be explicitly requested by the application via AI_CANONNAME flag. It may be desirable to suppress other requests by local configuration or connectivity checks, a notable example being suppression of DNS AAAA queries on hosts without global connectivity.

What is passed to the application

Not all information that is learnt via requests is presented to the application. It is typically filtered according to input from the application. It is sometimes also filtered according to connectivity checks but that has caused more problems than improvements.

How it is sorted

There are rules for sorting addressing information returned by getaddrinfo(). One of the basic features is to return global IPv6 destinations before global IPv4 destinations. But when the library detects that IPv6 connectivity is not available, the reverse applies.

Example tests

Dual-stack host, destination with global IPv4 and IPv6

On a host with IPv4 and IPv6 connectivity we request addressing information of another host that is announced as dual-stack in DNS.

$ getent ahosts www.nix.cz
2a02:38::1001   STREAM info.nix.cz
2a02:38::1001   DGRAM  
2a02:38::1001   RAW    
195.47.235.3    STREAM 
195.47.235.3    DGRAM  
195.47.235.3    RAW

You can see that getaddrinfo() returned six items for two unique IP addresses with the IPv6 address sorted first. If you only expected only two items, one for each IP address, see upstream bug 14990.

IPv4-only host, destination with global IPv4 and IPv6

We do the same on a host without IPv6 connectivity.

$ getent ahosts www.nix.cz
195.47.235.3    STREAM info.nix.cz
195.47.235.3    DGRAM  
195.47.235.3    RAW    
2a02:38::1001   STREAM 
2a02:38::1001   DGRAM  
2a02:38::1001   RAW    

You can see that the result is the same as before except that IPv4 is sorted first.

Name resolution (using netresolve)

There is an experimental package called netresolve (TODO: not yet in Fedora) that consists of a library somewhat similar to the glibc name resolution API implementation and a set of debugging tools. Any application using libc API and a couple of other APIs can be run using wrapresolve to use the netresolve implementation instead and benefit from some advanced features and more extensive debugging. When using the libc backend, netresolve can be also used to test the glibc implementation. With the nss backend it can be used to test glibc nsswitch backends directly.

$ ./netresolve --node www.nix.cz
response netresolve 0.0.1
name info.nix.cz
ip 2a02:38::1001 any any 0 0 0 21599
ip 195.47.235.3 any any 0 0 0 12589

You can see that netresolve behaves slightly different than getent ahosts and it by default returns one item per IP address. But you can easily tweak it to behave the same way.

 
$ ./netresolve --node www.nix.cz --service ''
response netresolve 0.0.1
name info.nix.cz
ip 2a02:38::1001 stream tcp 0 0 0 21021
ip 2a02:38::1001 dgram udp 0 0 0 21021
ip 2a02:38::1001 raw any 0 0 0 21021
ip 195.47.235.3 stream tcp 0 0 0 12592
ip 195.47.235.3 dgram udp 0 0 0 12592
ip 195.47.235.3 raw any 0 0 0 12592

Note that netresolve is both the name of the command and the name of the library. The above tests are done using the command but the same results would be given to an application using the library. Unless you explicitly request, netresolve uses its internal name resolution modules and not the libc functions.

Tools

Tools with issues:

Testing client applications

Client application checklist

A client application should:

  • avoid using obsolete functions:
    • gethostbyname(), gethostbyname2()
    • gethostbyaddr()
    • ...
  • use system wide name resolution configuration
    • avoid implementing name resolution code in the application
    • avoid calling DNS libraries directly (there are other name resolution sources than DNS)
  • reduce timeouts when a fallback is available
    • reduce excessive DNS timeouts, possibly using a decent system wide name resolution library
    • reduce excessive TCP timeouts, possibly using a decent socket library
  • attempt all provided addresses until one succeeds or all fail
    • possibly using a decent socket library

Known problematic packages

Testing server applications

Server applications should be capable of accepting IPv4 and IPv6 clients and logging their addresses. Some server applications make use of addresses extensively, some just need to translate them to a meaningful name. Many server applications initiate connections to other hosts and thus the section about client applications applies to them as well.