Update: in late December, 2015, AWS announced a new feature, a Managed NAT Gateway for VPC. This optional service provides an alternative mechanism for VPC instances in a private subnet to access the Internet, where previously, the common solution was an EC2 instance on a public subnet within the VPC, functioning as a "NAT instance," providing network address translation (technically, port address translation) for instances in other, private subnets, allowing those machines to use the NAT instance's public IP address for their outbound Internet access.
The new managed NAT service does not fundamentally change the applicability of the following information, but this option is not addressed in the content that follows. A NAT instance can still be used as described, or the Managed NAT Gateway service can be provisioned, instead. An expanded version of this answer integrating more information about NAT Gateway and how it compares to a NAT instance will be forthcoming, as these are both relevant to the private/public subnet paradigm in VPC.
Note that the Internet Gateway and NAT Gateway are two different features. All VPC configurations with Internet access will have an Internet Gateway virtual object.
To understand the distinction between "private" and "public" subnets in Amazon VPC requires an understanding of how IP routing and network address translation (NAT) work in general, and how it they are specifically implemented in VPC.
The core differentiation between a public and private subnet in VPC is defined by what that subnet's default route is, in the VPC routing tables.
This configuration, in turn, dictates the validity of using, or not using, public IP addresses on instances on that particular subnet.
Each subnet has exactly one default route, which can be only one of two things:
- the VPC's "Internet Gateway" object, in the case of a "public" subnet, or
- a NAT device -- that is, either a NAT Gateway or an EC2 instance, performing the "NAT instance" role, in the case of a "private" subnet.
The Internet Gateway does not do any network address translation for instances without public IP addresses so an instance without a public IP address cannot connect outward to the Internet -- to do things like downloading software updates, or accessing other AWS resources like S31 and SQS -- if the default route on its VPC subnet is the Internet Gateway object. So, if you are an instance on a "public" subnet, then you need a public IP address in order to do a significant number of things that servers commonly need to do.
For instances with only a private IP address, there's an alternate way of outbound access to the Internet. This is where Network Address Translation² and a NAT instance come in.
The machines on a private subnet can access the Internet because the default route on a private subnet is not the VPC "Internet Gateway" object -- it is an EC2 instance configured as a NAT instance.
A NAT instance is an instance on a public subnet with a public IP, and specific configuration. There are AMIs that are pre-built to do this, or your can build your own.
When the private-addressed machines send traffic outward, the traffic is sent, by VPC, to the NAT instance, which replaces the source IP address on the packet (the private machine's private IP address) with its own public IP address, sends the traffic out to the Internet, accepts the response packets, and forwards them back to the private address of the originating machine. (It may also rewrite the source port, and in any case, it remembers the mappings so it knows which internal machine should receive the response packets). A NAT instance does not allow any "unexpected" inbound traffic to reach the private instances, unless it's been specifically configured to do so.
Thus, when accessing external Internet resource from a private subnet, the traffic traverses the NAT instance, and appears to the destination to have originated from the public IP address of the NAT instance... so the response traffic comes back to the NAT instance. Neither the security group assigned to the NAT instance nor the security group assigned to the private instance need to be configured to "allow" this response traffic, because security groups are stateful. They realize the response traffic is correlated to sessions originated internally, so it is automatically allowed. Unexpected traffic is, of course, denied unless the security group is configured to permit it.
Unlike conventional IP routing, where your default gateway is on your same subnet, the way it works in VPC is different: the NAT instance for any given private subnet is always on a different subnet, and that other subnet is always a public subnet, because the NAT instance needs to have a public external IP, and its default gateway has to be the VPC "Internet Gateway" object.
Similarly... you cannot deploy an instance with a public IP on a private subnet. It doesn't work, because the default route on a private subnet is (by definition) a NAT instance (which performs NAT on the traffic), and not the Internet Gateway object (which doesn't). Inbound traffic from the Internet would hit the public IP of the instance, but the replies would try to route outward through the NAT instance, which would either drop the traffic (since it would be composed of replies to connections it's not aware of, so they'd be deemed invalid) or would rewrite the reply traffic to use its own public IP address, which wouldn't work since the external origin would not accept replies that came from an IP address other than the one they were trying to initiate communications with.
In essence, then, the "private" and "public" designations are not really about accessibility or inaccessibility from the Internet. They are about the kinds of addresses that will be assigned to the instances on that subnet, which is relevant because of the need to translate -- or avoid translating -- those IP addresses for Internet interactions.
Since VPC has implicit routes from all VPC subnets to all other VPC subnets, the default route does not play a role in internal VPC traffic. Instances with private IP addresses will connect to other private IP addresses in the VPC "from" their private IP address, not "from" their public IP address (if they have one)... as long as the destination address is another private address within the VPC.
If your instances with private IP addresses never, under any circumstances, need to originate outbound Internet traffic, then they technically could be deployed on a "public" subnet and would still still be inaccessible from the Internet... but under such a configuration, it is impossible for them to originate outbound traffic towards the Internet, which includes connections with other AWS infrastructure services, again, like S31 or SQS.
1. Regarding S3, specifically, to say that Internet access is always required is an oversimplification that will likely grow in scope over time and spread to other AWS services, as the capabilities of VPC continue to grow and evolve. There is a relatively new concept called a VPC Endpoint that allows your instances, including those with only private IP addresses, to directly access S3 from selected subnets within the VPC, without touching "the Internet," and without using a NAT instance or NAT gateway, but this does require additional configuration, and is only usable to access buckets within the same AWS region as your VPC. By default, S3 -- which is, as of this writing, the only service that has exposed the capability of creating VPC endpoints -- is only accessible from inside VPC via the Internet. When you create a VPC endpoint, this creates a prefix list (
pl-xxxxxxxx) that you can use in your VPC route tables to send traffic bound for that particular AWS service direct to the service via the virtual "VPC Endpoint" object. It also solves a problem of restricting outbound access to S3 for particular instance, because the prefix list can be used in outbound security groups, in place of a destination IP address or block -- and an S3 VPC endpoint can be subject to additional policy statements, restricting bucket access from inside, as desired.
2. As noted in the documentation, what's actually being discussed here is port as well as network address translation. It's common, though technically a bit imprecise, to refer to the combined operation as "NAT." This is somewhat akin to the way many of us tend to say "SSL" when we actually mean "TLS." We know what we're talking about, but we don't use the most correct word to describe it. "Note
We use the term NAT in this documentation to follow common IT practice, though the actual role of a NAT device is both address translation and port address translation (PAT)."