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144 lines
7.0 KiB
144 lines
7.0 KiB
Load Balancing in gRPC |
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# Objective |
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To design a load balancing API between a gRPC client and a Load Balancer to |
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instruct the client how to send load to multiple backend servers. |
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# Background |
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Prior to any gRPC specifics, we explore some usual ways to approach load |
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balancing. |
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### Proxy Model |
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Using a proxy provides a solid trustable client that can report load to the load |
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balancing system. Proxies typically require more resources to operate since they |
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have temporary copies of the RPC request and response. This model also increases |
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latency to the RPCs. |
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The proxy model was deemed inefficient when considering request heavy services |
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like storage. |
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### Balancing-aware Client |
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This thicker client places more of the load balancing logic in the client. For |
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example, the client could contain many load balancing policies (Round Robin, |
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Random, etc) used to select servers from a list. In this model, a list of |
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servers would be either statically configured in the client, provided by the |
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name resolution system, an external load balancer, etc. In any case, the client |
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is responsible for choosing the preferred server from the list. |
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One of the drawbacks of this approach is writing and maintaining the load |
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balancing policies in multiple languages and/or versions of the clients. These |
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policies can be fairly complicated. Some of the algorithms also require client |
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to server communication so the client would need to get thicker to support |
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additional RPCs to get health or load information in addition to sending RPCs |
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for user requests. |
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It would also significantly complicate the client's code: the new design hides |
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the load balancing complexity of multiple layers and presents it as a simple |
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list of servers to the client. |
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### External Load Balancing Service |
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The client load balancing code is kept simple and portable, implementing |
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well-known algorithms (ie, Round Robin) for server selection. |
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Complex load balancing algorithms are instead provided by the load balancer. The |
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client relies on the load balancer to provide _load balancing configuration_ and |
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_the list of servers_ to which the client should send requests. The balancer |
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updates the server list as needed to balance the load as well as handle server |
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unavailability or health issues. The load balancer will make any necessary |
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complex decisions and inform the client. The load balancer may communicate with |
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the backend servers to collect load and health information. |
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## Requirements |
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#### Simple API and client |
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The gRPC client load balancing code must be simple and portable. The client |
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should only contain simple algorithms (ie Round Robin) for server selection. For |
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complex algorithms, the client should rely on a load balancer to provide load |
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balancing configuration and the list of servers to which the client should send |
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requests. The balancer will update the server list as needed to balance the load |
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as well as handle server unavailability or health issues. The load balancer will |
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make any necessary complex decisions and inform the client. The load balancer |
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may communicate with the backend servers to collect load and health information. |
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#### Security |
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The load balancer may be separate from the actual server backends and a |
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compromise of the load balancer should only lead to a compromise of the |
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loadbalancing functionality. In other words, a compromised load balancer should |
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not be able to cause a client to trust a (potentially malicious) backend server |
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any more than in a comparable situation without loadbalancing. |
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# Proposed Architecture |
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The gRPC load balancing implements the external load balancing server approach: |
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an external load balancer provides simple clients with an up-to-date list of |
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servers. |
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1. On startup, the gRPC client issues a name resolution request for the service. |
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The name will resolve to one or more IP addresses to gRPC servers, a hint on |
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whether the IP address(es) point to a load balancer or not, and also return a |
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client config. |
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2. The gRPC client connects to a gRPC Server. |
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1. If the name resolution has hinted that the endpoint is a load balancer, |
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the client's gRPC LB policy will attempt to open a stream to the load |
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balancer service. The server may respond in only one of the following |
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ways. |
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1. `status::UNIMPLEMENTED`. There is no loadbalancing in use. The client |
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call will fail. |
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2. "I am a Load Balancer and here is the server list." (Goto Step 4.) |
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3. "Please contact Load Balancer X" (See Step 3.) The client will close |
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this connection and cancel the stream. |
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4. If the server fails to respond, the client will wait for some timeout |
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and then re-resolve the name (process to Step 1 above). |
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2. If the name resolution has not hinted that the endpoint is a load |
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balancer, the client connects directly to the service it wants to talk to. |
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3. The gRPC client's gRPC LB policy opens a separate connection to the Load |
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Balancer. If this fails, it will go back to step 1 and try another address. |
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1. During channel initialization to the Load Balancer, the client will |
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attempt to open a stream to the Load Balancer service. |
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2. The Load Balancer will return a server list to the gRPC client. If the |
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server list is empty, the call will wait until a non-empty one is |
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received. Optional: The Load Balancer will also open channels to the gRPC |
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servers if load reporting is needed. |
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4. The gRPC client will send RPCs to the gRPC servers contained in the server |
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list from the Load Balancer. |
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5. Optional: The gRPC servers may periodically report load to the Load Balancer. |
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## Client |
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When establishing a gRPC _stream_ to the balancer, the client will send an initial |
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request to the load balancer (via a regular gRPC message). The load balancer |
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will respond with client config (including, for example, settings for flow |
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control, RPC deadlines, etc.) or a redirect to another load balancer. If the |
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balancer did not redirect the client, it will then send a list of servers to the |
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client. The client will contain simple load balancing logic for choosing the |
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next server when it needs to send a request. |
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## Load Balancer |
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The Load Balancer is responsible for providing the client with a list of servers |
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and client RPC parameters. The balancer chooses when to update the list of |
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servers and can decide whether to provide a complete list, a subset, or a |
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specific list of “picked” servers in a particular order. The balancer can |
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optionally provide an expiration interval after which the server list should no |
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longer be trusted and should be updated by the balancer. |
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The load balancer may open reporting streams to each server contained in the |
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server list. These streams are primarily used for load reporting. For example, |
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Weighted Round Robin requires that the servers report utilization to the load |
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balancer in order to compute the next list of servers. |
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## Server |
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The gRPC Server is responsible for answering RPC requests and providing |
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responses to the client. The server will also report load to the load balancer |
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if a reporting stream was opened for this purpose.
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