- Author(s): Mark D. Roth (roth@google.com)
- Approver: a11r
- Status: Implemented
- Implemented in: C-core (Go and Java in progress)
- Last updated: 2017-09-13
- Discussion at: https://groups.google.com/d/topic/grpc-io/6be1QsHyZkk/discussion
This document describes how additional name service data for load balancing should be encoded in DNS.
As described in the name resolution doc, a resolver implementation is expected to return two additional pieces of data with each address, both related to load balancing. Those two pieces of data are:
-
A boolean indicating whether the address is a backend address (i.e., the address to use to contact the server directly) or a balancer address.
-
The name of the balancer, if the address is a balancer address. This will be used to perform peer authorization.
This document describes how those two pieces of data should be encoded when the name service is DNS.
N/A
This proposal makes use of DNS SRV records, as described in RFC-2782. The SRV record for grpclb will use the following values:
- service name:
grpclb - protocol:
tcp - priority: this will be
0for all grpclb SRV records - weight: this will be
0for all grpclb SRV records
When the gRPC client library opens a channel for a given server name, it will ask DNS for these SRV records in addition to the normal address records. For each SRV record that comes back in the response, the client library will then do a DNS lookup for address records for the name specified by the SRV record. It will then return each of the resulting addresses with the extra fields indicating that the addresses are balancer addresses and the name from the SRV record.
Since the SRV service name is the same for plain text and encrypted, there is not a way to provide different ports depending on the presence of encryption. If simultaneous support for http+https is necessary, we recommend using different DNS host names for insecure vs secure.
Note that the gRPC library will ignore the values of the priority and
weight fields. Instead, it will put all balancer addresses into a
single list (in whatever order the DNS server returns them) and use the
pick_first load-balancing policy to decide which one of them to use.
However, in order to leave open the possibility of adding support for
priority and weight in the future, we recommend that these fields be set
to 0. That way, if we do add support for these fields in the future,
existing records will not break.
For example, let's say that we have the following DNS zone file:
$ORIGIN example.com.
; grpclb for server.example.com goes to lb.example.com:1234
_grpclb._tcp.server IN SRV 0 0 1234 lb
; lb.example.com has 3 IP addresses
lb IN A 10.0.0.1
IN A 10.0.0.2
IN A 10.0.0.3
With this data, a gRPC client will resolve the name server.example.com
to the following addresses:
address=10.0.0.1:1234, is_balancer=true, balancer_name=lb.example.com
address=10.0.0.2:1234, is_balancer=true, balancer_name=lb.example.com
address=10.0.0.3:1234, is_balancer=true, balancer_name=lb.example.com
For redundancy, it may be desirable to return both server and balancer addresses for the same server name. In principle, this will allow the client to fall back to directly contacting the servers if the load balancers are unreachable. However, that fallback functionality is not yet implemented, so it will be the subject of future work.
However, it is still possible for service owners to set up their DNS zone files to publish both types of addresses, so that they are prepared for an eventual future when this fallback functionality has been implemented. For example:
$ORIGIN example.com.
server IN A 10.0.0.11
IN A 10.0.0.12
; grpclb for server.example.com goes to lb.example.com:1234
_grpclb._tcp.server IN SRV 0 0 1234 lb
; lb.example.com has 3 IP addresses
lb IN A 10.0.0.1
IN A 10.0.0.2
IN A 10.0.0.3
For now, if both address records and SRV records are present for the
same server name, the gRPC client will ignore the address records and
return only the SRV records -- in other words, the result for a lookup
of server.example.com will be exactly the same in this case as it
would be in the previous example.
In the future, when we do implement support for this kind of fallback, this lookup will result in the following addresses:
address=10.0.0.11:443, is_balancer=false, balancer_name=<unset>
address=10.0.0.12:443, is_balancer=false, balancer_name=<unset>
address=10.0.0.1:1234, is_balancer=true, balancer_name=lb.example.com
address=10.0.0.2:1234, is_balancer=true, balancer_name=lb.example.com
address=10.0.0.3:1234, is_balancer=true, balancer_name=lb.example.com
Note that port 443 is the default if not specified by the server name passed to the client library by the application. If the server name passed in by the application does specify a port, that would be used for the resulting server addresses, but it would not affect the port used for the balancer addresses.
We considered one alternative, which was adding additional fields to a TXT record instead of using an SRV record. However, the SRV record seems to be a much better fit for this purpose.
In C-core, this implementation will rely on use of the c-ares DNS library, which was added in grpc/grpc#7771.
Specifically, we will change the c-ares resolver implementation to automatically look up the grpclb SRV records for the specified name. If found, it will then look up the name(s) that the SRV records point to and return those as balancer addresses.
Note that, due to platform support issues, we will initially not support the c-ares resolver under Windows or for Node. Alternatives will need to be found for these environments.
Java will depend on JNDI, Netty DNS, dnsjava, or a another DNS library
to do SRV record resolution. The existing name resolver, DnsNameResolver,
will be modified to resolve the additional records and include them in
the Attributes presented to the load balancer.
Go will use the LookupSRV function in package net to do SRV record
resolution.
N/A