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1402 lines
42 KiB
1402 lines
42 KiB
Interoperability Test Case Descriptions |
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======================================= |
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|
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Client and server use |
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[test.proto](../src/proto/grpc/testing/test.proto) |
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and the [gRPC over HTTP/2 v2 protocol](./PROTOCOL-HTTP2.md). |
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|
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Client |
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------ |
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|
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Clients implement test cases that test certain functionally. Each client is |
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provided the test case it is expected to run as a command-line parameter. Names |
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should be lowercase and without spaces. |
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|
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Clients should accept these arguments: |
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* --server_host=HOSTNAME |
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* The server host to connect to. For example, "localhost" or "127.0.0.1" |
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* --server_host_override=HOSTNAME |
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* The server host to claim to be connecting to, for use in TLS and HTTP/2 |
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:authority header. If unspecified, the value of --server_host will be |
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used |
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* --server_port=PORT |
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* The server port to connect to. For example, "8080" |
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* --test_case=TESTCASE |
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* The name of the test case to execute. For example, "empty_unary" |
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* --use_tls=BOOLEAN |
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* Whether to use a plaintext or encrypted connection |
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* --use_test_ca=BOOLEAN |
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* Whether to replace platform root CAs with |
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[ca.pem](https://github.com/grpc/grpc/blob/master/src/core/tsi/test_creds/ca.pem) |
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as the CA root |
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* --default_service_account=ACCOUNT_EMAIL |
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* Email of the GCE default service account. |
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* --oauth_scope=SCOPE |
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* OAuth scope. For example, "https://www.googleapis.com/auth/xapi.zoo" |
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* --service_account_key_file=PATH |
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* The path to the service account JSON key file generated from GCE developer |
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console. |
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* --service_config_json=SERVICE_CONFIG_JSON |
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* Disables service config lookups and sets the provided string as the |
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default service config. |
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|
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Clients must support TLS with ALPN. Clients must not disable certificate |
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checking. |
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|
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### empty_unary |
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|
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This test verifies that implementations support zero-size messages. Ideally, |
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client implementations would verify that the request and response were zero |
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bytes serialized, but this is generally prohibitive to perform, so is not |
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required. |
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|
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Server features: |
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* [EmptyCall][] |
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|
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Procedure: |
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1. Client calls EmptyCall with the default Empty message |
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|
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Client asserts: |
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* call was successful |
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* response is non-null |
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|
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*It may be possible to use UnaryCall instead of EmptyCall, but it is harder to |
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ensure that the proto serialized to zero bytes.* |
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|
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### cacheable_unary |
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|
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This test verifies that gRPC requests marked as cacheable use GET verb instead |
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of POST, and that server sets appropriate cache control headers for the response |
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to be cached by a proxy. This test requires that the server is behind |
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a caching proxy. Use of current timestamp in the request prevents accidental |
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cache matches left over from previous tests. |
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|
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Server features: |
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* [CacheableUnaryCall][] |
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|
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Procedure: |
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1. Client calls CacheableUnaryCall with `SimpleRequest` request with payload |
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set to current timestamp. Timestamp format is irrelevant, and resolution is |
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in nanoseconds. |
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Client adds a `x-user-ip` header with value `1.2.3.4` to the request. |
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This is done since some proxys such as GFE will not cache requests from |
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localhost. |
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Client marks the request as cacheable by setting the cacheable flag in the |
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request context. Longer term this should be driven by the method option |
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specified in the proto file itself. |
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2. Client calls CacheableUnaryCall again immediately with the same request and |
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configuration as the previous call. |
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|
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Client asserts: |
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* Both calls were successful |
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* The payload body of both responses is the same. |
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|
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### large_unary |
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|
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This test verifies unary calls succeed in sending messages, and touches on flow |
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control (even if compression is enabled on the channel). |
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|
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Server features: |
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* [UnaryCall][] |
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|
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Procedure: |
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1. Client calls UnaryCall with: |
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|
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``` |
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{ |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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|
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Client asserts: |
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* call was successful |
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* response payload body is 314159 bytes in size |
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* clients are free to assert that the response payload body contents are zero |
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and comparing the entire response message against a golden response |
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|
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### client_compressed_unary |
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|
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This test verifies the client can compress unary messages by sending two unary |
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calls, for compressed and uncompressed payloads. It also sends an initial |
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probing request to verify whether the server supports the [CompressedRequest][] |
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feature by checking if the probing call fails with an `INVALID_ARGUMENT` status. |
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|
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Server features: |
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* [UnaryCall][] |
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* [CompressedRequest][] |
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|
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Procedure: |
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1. Client calls UnaryCall with the feature probe, an *uncompressed* message: |
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``` |
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{ |
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expect_compressed:{ |
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value: true |
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} |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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|
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1. Client calls UnaryCall with the *compressed* message: |
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|
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``` |
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{ |
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expect_compressed:{ |
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value: true |
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} |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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|
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1. Client calls UnaryCall with the *uncompressed* message: |
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|
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``` |
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{ |
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expect_compressed:{ |
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value: false |
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} |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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|
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Client asserts: |
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* First call failed with `INVALID_ARGUMENT` status. |
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* Subsequent calls were successful. |
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* Response payload body is 314159 bytes in size. |
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* Clients are free to assert that the response payload body contents are |
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zeros and comparing the entire response message against a golden response. |
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|
|
|
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### server_compressed_unary |
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|
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This test verifies the server can compress unary messages. It sends two unary |
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requests, expecting the server's response to be compressed or not according to |
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the `response_compressed` boolean. |
|
|
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Whether compression was actually performed is determined by the compression bit |
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in the response's message flags. *Note that some languages may not have access |
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to the message flags, in which case the client will be unable to verify that |
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the `response_compressed` boolean is obeyed by the server*. |
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|
|
|
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Server features: |
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* [UnaryCall][] |
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* [CompressedResponse][] |
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|
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Procedure: |
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1. Client calls UnaryCall with `SimpleRequest`: |
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|
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``` |
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{ |
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response_compressed:{ |
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value: true |
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} |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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|
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``` |
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{ |
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response_compressed:{ |
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value: false |
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} |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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} |
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``` |
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Client asserts: |
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* call was successful |
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* if supported by the implementation, when `response_compressed` is true, |
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the response MUST have the compressed message flag set. |
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* if supported by the implementation, when `response_compressed` is false, |
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the response MUST NOT have the compressed message flag set. |
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* response payload body is 314159 bytes in size in both cases. |
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* clients are free to assert that the response payload body contents are |
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zero and comparing the entire response message against a golden response |
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|
|
|
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### client_streaming |
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|
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This test verifies that client-only streaming succeeds. |
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|
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Server features: |
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* [StreamingInputCall][] |
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Procedure: |
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1. Client calls StreamingInputCall |
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2. Client sends: |
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|
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``` |
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{ |
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payload:{ |
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body: 27182 bytes of zeros |
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} |
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} |
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``` |
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|
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3. Client then sends: |
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|
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``` |
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{ |
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payload:{ |
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body: 8 bytes of zeros |
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} |
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} |
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``` |
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4. Client then sends: |
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|
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``` |
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{ |
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payload:{ |
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body: 1828 bytes of zeros |
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} |
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} |
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``` |
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|
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5. Client then sends: |
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|
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``` |
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{ |
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payload:{ |
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body: 45904 bytes of zeros |
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} |
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} |
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``` |
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6. Client half-closes |
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|
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Client asserts: |
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* call was successful |
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* response aggregated_payload_size is 74922 |
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|
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|
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### client_compressed_streaming |
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|
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This test verifies the client can compress requests on per-message basis by |
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performing a two-request streaming call. It also sends an initial probing |
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request to verify whether the server supports the [CompressedRequest][] feature |
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by checking if the probing call fails with an `INVALID_ARGUMENT` status. |
|
|
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Procedure: |
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1. Client calls `StreamingInputCall` and sends the following feature-probing |
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*uncompressed* `StreamingInputCallRequest` message |
|
|
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``` |
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{ |
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expect_compressed:{ |
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value: true |
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} |
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payload:{ |
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body: 27182 bytes of zeros |
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} |
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} |
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``` |
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If the call does not fail with `INVALID_ARGUMENT`, the test fails. |
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Otherwise, we continue. |
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1. Client calls `StreamingInputCall` again, sending the *compressed* message |
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|
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``` |
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{ |
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expect_compressed:{ |
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value: true |
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} |
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payload:{ |
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body: 27182 bytes of zeros |
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} |
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} |
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``` |
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|
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1. And finally, the *uncompressed* message |
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``` |
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{ |
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expect_compressed:{ |
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value: false |
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} |
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payload:{ |
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body: 45904 bytes of zeros |
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} |
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} |
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``` |
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1. Client half-closes |
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|
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Client asserts: |
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* First call fails with `INVALID_ARGUMENT`. |
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* Next calls succeeds. |
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* Response aggregated payload size is 73086. |
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|
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### server_streaming |
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|
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This test verifies that server-only streaming succeeds. |
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Server features: |
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* [StreamingOutputCall][] |
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Procedure: |
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1. Client calls StreamingOutputCall with `StreamingOutputCallRequest`: |
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|
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``` |
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{ |
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response_parameters:{ |
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size: 31415 |
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} |
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response_parameters:{ |
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size: 9 |
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} |
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response_parameters:{ |
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size: 2653 |
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} |
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response_parameters:{ |
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size: 58979 |
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} |
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} |
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``` |
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Client asserts: |
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* call was successful |
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* exactly four responses |
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* response payload bodies are sized (in order): 31415, 9, 2653, 58979 |
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* clients are free to assert that the response payload body contents are zero |
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and comparing the entire response messages against golden responses |
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|
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### server_compressed_streaming |
|
|
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This test verifies that the server can compress streaming messages and disable |
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compression on individual messages, expecting the server's response to be |
|
compressed or not according to the `response_compressed` boolean. |
|
|
|
Whether compression was actually performed is determined by the compression bit |
|
in the response's message flags. *Note that some languages may not have access |
|
to the message flags, in which case the client will be unable to verify that the |
|
`response_compressed` boolean is obeyed by the server*. |
|
|
|
Server features: |
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* [StreamingOutputCall][] |
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* [CompressedResponse][] |
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|
|
|
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Procedure: |
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1. Client calls StreamingOutputCall with `StreamingOutputCallRequest`: |
|
|
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``` |
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{ |
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response_parameters:{ |
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compressed: { |
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value: true |
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} |
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size: 31415 |
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} |
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response_parameters:{ |
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compressed: { |
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value: false |
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} |
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size: 92653 |
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} |
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} |
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``` |
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Client asserts: |
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* call was successful |
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* exactly two responses |
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* if supported by the implementation, when `response_compressed` is false, |
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the response's messages MUST NOT have the compressed message flag set. |
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* if supported by the implementation, when `response_compressed` is true, |
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the response's messages MUST have the compressed message flag set. |
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* response payload bodies are sized (in order): 31415, 92653 |
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* clients are free to assert that the response payload body contents are |
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zero and comparing the entire response messages against golden responses |
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|
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### ping_pong |
|
|
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This test verifies that full duplex bidi is supported. |
|
|
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Server features: |
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* [FullDuplexCall][] |
|
|
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Procedure: |
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1. Client calls FullDuplexCall with: |
|
|
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``` |
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{ |
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response_parameters:{ |
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size: 31415 |
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} |
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payload:{ |
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body: 27182 bytes of zeros |
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} |
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} |
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``` |
|
|
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2. After getting a reply, it sends: |
|
|
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``` |
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{ |
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response_parameters:{ |
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size: 9 |
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} |
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payload:{ |
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body: 8 bytes of zeros |
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} |
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} |
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``` |
|
|
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3. After getting a reply, it sends: |
|
|
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``` |
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{ |
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response_parameters:{ |
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size: 2653 |
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} |
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payload:{ |
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body: 1828 bytes of zeros |
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} |
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} |
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``` |
|
|
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4. After getting a reply, it sends: |
|
|
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``` |
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{ |
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response_parameters:{ |
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size: 58979 |
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} |
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payload:{ |
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body: 45904 bytes of zeros |
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} |
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} |
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``` |
|
|
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5. After getting a reply, client half-closes |
|
|
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Client asserts: |
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* call was successful |
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* exactly four responses |
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* response payload bodies are sized (in order): 31415, 9, 2653, 58979 |
|
* clients are free to assert that the response payload body contents are zero |
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and comparing the entire response messages against golden responses |
|
|
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### empty_stream |
|
|
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This test verifies that streams support having zero-messages in both |
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directions. |
|
|
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Server features: |
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* [FullDuplexCall][] |
|
|
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Procedure: |
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1. Client calls FullDuplexCall and then half-closes |
|
|
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Client asserts: |
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* call was successful |
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* exactly zero responses |
|
|
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### compute_engine_creds |
|
|
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This test is only for cloud-to-prod path. |
|
|
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This test verifies unary calls succeed in sending messages while using Service |
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Credentials from GCE metadata server. The client instance needs to be created |
|
with desired oauth scope. |
|
|
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The test uses `--default_service_account` with GCE service account email and |
|
`--oauth_scope` with the OAuth scope to use. For testing against |
|
grpc-test.sandbox.googleapis.com, "https://www.googleapis.com/auth/xapi.zoo" |
|
should |
|
be passed in as `--oauth_scope`. |
|
|
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Server features: |
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* [UnaryCall][] |
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* [Echo Authenticated Username][] |
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* [Echo OAuth Scope][] |
|
|
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Procedure: |
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1. Client configures channel to use GCECredentials |
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2. Client calls UnaryCall on the channel with: |
|
|
|
``` |
|
{ |
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response_size: 314159 |
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payload:{ |
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body: 271828 bytes of zeros |
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} |
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fill_username: true |
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fill_oauth_scope: true |
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} |
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``` |
|
|
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Client asserts: |
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* call was successful |
|
* received SimpleResponse.username equals the value of |
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`--default_service_account` flag |
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* received SimpleResponse.oauth_scope is in `--oauth_scope` |
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* response payload body is 314159 bytes in size |
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* clients are free to assert that the response payload body contents are zero |
|
and comparing the entire response message against a golden response |
|
|
|
### jwt_token_creds |
|
|
|
This test is only for cloud-to-prod path. |
|
|
|
This test verifies unary calls succeed in sending messages while using JWT |
|
token (created by the project's key file) |
|
|
|
Test caller should set flag `--service_account_key_file` with the |
|
path to json key file downloaded from |
|
https://console.developers.google.com. Alternately, if using a |
|
usable auth implementation, she may specify the file location in the environment |
|
variable GOOGLE_APPLICATION_CREDENTIALS. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Authenticated Username][] |
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* [Echo OAuth Scope][] |
|
|
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Procedure: |
|
1. Client configures the channel to use JWTTokenCredentials |
|
2. Client calls UnaryCall with: |
|
|
|
``` |
|
{ |
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response_size: 314159 |
|
payload:{ |
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body: 271828 bytes of zeros |
|
} |
|
fill_username: true |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* call was successful |
|
* received SimpleResponse.username is not empty and is in the json key file used |
|
by the auth library. The client can optionally check the username matches the |
|
email address in the key file or equals the value of `--default_service_account` |
|
flag. |
|
* response payload body is 314159 bytes in size |
|
* clients are free to assert that the response payload body contents are zero |
|
and comparing the entire response message against a golden response |
|
|
|
### oauth2_auth_token |
|
|
|
This test is only for cloud-to-prod path and some implementations may run |
|
in GCE only. |
|
|
|
This test verifies unary calls succeed in sending messages using an OAuth2 token |
|
that is obtained out of band. For the purpose of the test, the OAuth2 token is |
|
actually obtained from a service account credentials or GCE credentials via the |
|
language-specific authorization library. |
|
|
|
The difference between this test and the other auth tests is that it |
|
first uses the authorization library to obtain an authorization token. |
|
|
|
The test |
|
- uses the flag `--service_account_key_file` with the path to a json key file |
|
downloaded from https://console.developers.google.com. Alternately, if using a |
|
usable auth implementation, it may specify the file location in the environment |
|
variable GOOGLE_APPLICATION_CREDENTIALS, *OR* if GCE credentials is used to |
|
fetch the token, `--default_service_account` can be used to pass in GCE service |
|
account email. |
|
- uses the flag `--oauth_scope` for the oauth scope. For testing against |
|
grpc-test.sandbox.googleapis.com, "https://www.googleapis.com/auth/xapi.zoo" |
|
should be passed as the `--oauth_scope`. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Authenticated Username][] |
|
* [Echo OAuth Scope][] |
|
|
|
Procedure: |
|
1. Client uses the auth library to obtain an authorization token |
|
2. Client configures the channel to use AccessTokenCredentials with the access |
|
token obtained in step 1 |
|
3. Client calls UnaryCall with the following message |
|
|
|
``` |
|
{ |
|
fill_username: true |
|
fill_oauth_scope: true |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* call was successful |
|
* received SimpleResponse.username is valid. Depending on whether a service |
|
account key file or GCE credentials was used, client should check against the |
|
json key file or GCE default service account email. |
|
* received SimpleResponse.oauth_scope is in `--oauth_scope` |
|
|
|
### per_rpc_creds |
|
|
|
Similar to the other auth tests, this test is only for cloud-to-prod path. |
|
|
|
This test verifies unary calls succeed in sending messages using a JWT or a |
|
service account credentials set on the RPC. |
|
|
|
The test |
|
- uses the flag `--service_account_key_file` with the path to a json key file |
|
downloaded from https://console.developers.google.com. Alternately, if using a |
|
usable auth implementation, it may specify the file location in the environment |
|
variable GOOGLE_APPLICATION_CREDENTIALS |
|
- optionally uses the flag `--oauth_scope` for the oauth scope if implementer |
|
wishes to use service account credential instead of JWT credential. For testing |
|
against grpc-test.sandbox.googleapis.com, oauth scope |
|
"https://www.googleapis.com/auth/xapi.zoo" should be used. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Authenticated Username][] |
|
* [Echo OAuth Scope][] |
|
|
|
Procedure: |
|
1. Client configures the channel with just SSL credentials |
|
2. Client calls UnaryCall, setting per-call credentials to |
|
JWTTokenCredentials. The request is the following message |
|
|
|
``` |
|
{ |
|
fill_username: true |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* call was successful |
|
* received SimpleResponse.username is not empty and is in the json key file used |
|
by the auth library. The client can optionally check the username matches the |
|
email address in the key file. |
|
|
|
### google_default_credentials |
|
|
|
Similar to the other auth tests, this test should only be run against prod |
|
servers. Different from some of the other auth tests however, this test |
|
may be also run from outside of GCP. |
|
|
|
This test verifies unary calls succeed when the client uses |
|
GoogleDefaultCredentials. The path to a service account key file in the |
|
GOOGLE_APPLICATION_CREDENTIALS environment variable may or may not be |
|
provided by the test runner. For example, the test runner might set |
|
this environment when outside of GCP but keep it unset when on GCP. |
|
|
|
The test uses `--default_service_account` with GCE service account email. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Authenticated Username][] |
|
|
|
Procedure: |
|
1. Client configures the channel to use GoogleDefaultCredentials |
|
* Note: the term `GoogleDefaultCredentials` within the context |
|
of this test description refers to an API which encapsulates |
|
both "transport credentials" and "call credentials" and which |
|
is capable of transport creds auto-selection (including ALTS). |
|
Similar APIs involving only auto-selection of OAuth mechanisms |
|
might work for this test but aren't the intended subjects. |
|
2. Client calls UnaryCall with: |
|
|
|
``` |
|
{ |
|
fill_username: true |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* call was successful |
|
* received SimpleResponse.username matches the value of |
|
`--default_service_account` |
|
|
|
### compute_engine_channel_credentials |
|
|
|
Similar to the other auth tests, this test should only be run against prod |
|
servers. Note that this test may only be ran on GCP. |
|
|
|
This test verifies unary calls succeed when the client uses |
|
ComputeEngineChannelCredentials. All that is needed by the test environment |
|
is for the client to be running on GCP. |
|
|
|
The test uses `--default_service_account` with GCE service account email. This |
|
email must identify the default service account of the GCP VM that the test |
|
is running on. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Authenticated Username][] |
|
|
|
Procedure: |
|
1. Client configures the channel to use ComputeEngineChannelCredentials |
|
* Note: the term `ComputeEngineChannelCredentials` within the context |
|
of this test description refers to an API which encapsulates |
|
both "transport credentials" and "call credentials" and which |
|
is capable of transport creds auto-selection (including ALTS). |
|
The exact name of the API may vary per language. |
|
2. Client calls UnaryCall with: |
|
|
|
``` |
|
{ |
|
fill_username: true |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* call was successful |
|
* received SimpleResponse.username matches the value of |
|
`--default_service_account` |
|
|
|
### custom_metadata |
|
|
|
This test verifies that custom metadata in either binary or ascii format can be |
|
sent as initial-metadata by the client and as both initial- and trailing-metadata |
|
by the server. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [FullDuplexCall][] |
|
* [Echo Metadata][] |
|
|
|
Procedure: |
|
1. The client attaches custom metadata with the following keys and values: |
|
|
|
``` |
|
key: "x-grpc-test-echo-initial", value: "test_initial_metadata_value" |
|
key: "x-grpc-test-echo-trailing-bin", value: 0xababab |
|
``` |
|
|
|
to a UnaryCall with request: |
|
|
|
``` |
|
{ |
|
response_size: 314159 |
|
payload:{ |
|
body: 271828 bytes of zeros |
|
} |
|
} |
|
``` |
|
|
|
2. The client attaches custom metadata with the following keys and values: |
|
|
|
``` |
|
key: "x-grpc-test-echo-initial", value: "test_initial_metadata_value" |
|
key: "x-grpc-test-echo-trailing-bin", value: 0xababab |
|
``` |
|
|
|
to a FullDuplexCall with request: |
|
|
|
``` |
|
{ |
|
response_parameters:{ |
|
size: 314159 |
|
} |
|
payload:{ |
|
body: 271828 bytes of zeros |
|
} |
|
} |
|
``` |
|
|
|
and then half-closes |
|
|
|
Client asserts: |
|
* call was successful |
|
* metadata with key `"x-grpc-test-echo-initial"` and value |
|
`"test_initial_metadata_value"`is received in the initial metadata for calls |
|
in Procedure steps 1 and 2. |
|
* metadata with key `"x-grpc-test-echo-trailing-bin"` and value `0xababab` is |
|
received in the trailing metadata for calls in Procedure steps 1 and 2. |
|
|
|
|
|
|
|
### status_code_and_message |
|
|
|
This test verifies unary calls succeed in sending messages, and propagate back |
|
status code and message sent along with the messages. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [FullDuplexCall][] |
|
* [Echo Status][] |
|
|
|
Procedure: |
|
1. Client calls UnaryCall with: |
|
|
|
``` |
|
{ |
|
response_status:{ |
|
code: 2 |
|
message: "test status message" |
|
} |
|
} |
|
``` |
|
|
|
2. Client calls FullDuplexCall with: |
|
|
|
``` |
|
{ |
|
response_status:{ |
|
code: 2 |
|
message: "test status message" |
|
} |
|
} |
|
``` |
|
|
|
and then half-closes |
|
|
|
|
|
Client asserts: |
|
* received status code is the same as the sent code for both Procedure steps 1 |
|
and 2 |
|
* received status message is the same as the sent message for both Procedure |
|
steps 1 and 2 |
|
|
|
### special_status_message |
|
|
|
This test verifies Unicode and whitespace is correctly processed in status |
|
message. "\t" is horizontal tab. "\r" is carriage return. "\n" is line feed. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Echo Status][] |
|
|
|
Procedure: |
|
1. Client calls UnaryCall with: |
|
|
|
``` |
|
{ |
|
response_status:{ |
|
code: 2 |
|
message: "\t\ntest with whitespace\r\nand Unicode BMP ☺ and non-BMP 😈\t\n" |
|
} |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* received status code is the same as the sent code for Procedure step 1 |
|
* received status message is the same as the sent message for Procedure step 1, |
|
including all whitespace characters |
|
|
|
### unimplemented_method |
|
|
|
This test verifies that calling an unimplemented RPC method returns the |
|
UNIMPLEMENTED status code. |
|
|
|
Server features: |
|
N/A |
|
|
|
Procedure: |
|
* Client calls `grpc.testing.TestService/UnimplementedCall` with an empty |
|
request (defined as `grpc.testing.Empty`): |
|
|
|
``` |
|
{ |
|
} |
|
``` |
|
|
|
Client asserts: |
|
* received status code is 12 (UNIMPLEMENTED) |
|
|
|
### unimplemented_service |
|
|
|
This test verifies calling an unimplemented server returns the UNIMPLEMENTED |
|
status code. |
|
|
|
Server features: |
|
N/A |
|
|
|
Procedure: |
|
* Client calls `grpc.testing.UnimplementedService/UnimplementedCall` with an |
|
empty request (defined as `grpc.testing.Empty`) |
|
|
|
Client asserts: |
|
* received status code is 12 (UNIMPLEMENTED) |
|
|
|
### cancel_after_begin |
|
|
|
This test verifies that a request can be cancelled after metadata has been sent |
|
but before payloads are sent. |
|
|
|
Server features: |
|
* [StreamingInputCall][] |
|
|
|
Procedure: |
|
1. Client starts StreamingInputCall |
|
2. Client immediately cancels request |
|
|
|
Client asserts: |
|
* Call completed with status CANCELLED |
|
|
|
### cancel_after_first_response |
|
|
|
This test verifies that a request can be cancelled after receiving a message |
|
from the server. |
|
|
|
Server features: |
|
* [FullDuplexCall][] |
|
|
|
Procedure: |
|
1. Client starts FullDuplexCall with |
|
|
|
``` |
|
{ |
|
response_parameters:{ |
|
size: 31415 |
|
} |
|
payload:{ |
|
body: 27182 bytes of zeros |
|
} |
|
} |
|
``` |
|
|
|
2. After receiving a response, client cancels request |
|
|
|
Client asserts: |
|
* Call completed with status CANCELLED |
|
|
|
### timeout_on_sleeping_server |
|
|
|
This test verifies that an RPC request whose lifetime exceeds its configured |
|
timeout value will end with the DeadlineExceeded status. |
|
|
|
Server features: |
|
* [FullDuplexCall][] |
|
|
|
Procedure: |
|
1. Client calls FullDuplexCall with the following request and sets its timeout |
|
to 1ms |
|
|
|
``` |
|
{ |
|
payload:{ |
|
body: 27182 bytes of zeros |
|
} |
|
} |
|
``` |
|
|
|
2. Client waits |
|
|
|
Client asserts: |
|
* Call completed with status DEADLINE_EXCEEDED. |
|
|
|
### rpc_soak |
|
|
|
The client performs many large_unary RPCs in sequence over the same channel. |
|
The client records the latency and status of each RPC in some data structure. |
|
If the test ever consumes `soak_overall_timeout_seconds` seconds and still hasn't |
|
completed `soak_iterations` RPCs, then the test should discontinue sending RPCs |
|
as soon as possible. After performing all RPCs, the test should examine |
|
previously recorded RPC latency and status results in a second pass and fail if |
|
either: |
|
|
|
a) not all `soak_iterations` RPCs were completed |
|
|
|
b) the sum of RPCs that either completed with a non-OK status or exceeded |
|
`max_acceptable_per_rpc_latency_ms` exceeds `soak_max_failures` |
|
|
|
Implementations should use a timer with sub-millisecond precision to measure |
|
latency. Also, implementations should avoid setting RPC deadlines and should |
|
instead wait for each RPC to complete. Doing so provides more data for |
|
debugging in case of failure. For example, if RPC deadlines are set to |
|
`soak_per_iteration_max_acceptable_latency_ms` and one of the RPCs hits that |
|
deadline, it's not clear if the RPC was late by a millisecond or a minute. |
|
|
|
This test must be configurable via a few different command line flags: |
|
|
|
* `soak_iterations`: Controls the number of RPCs to perform. This should |
|
default to 10. |
|
|
|
* `soak_max_failures`: An inclusive upper limit on the number of RPC failures |
|
that should be tolerated (i.e. after which the test process should |
|
still exit 0). A failure is considered to be either a non-OK status or an RPC |
|
whose latency exceeds `soak_per_iteration_max_acceptable_latency_ms`. This |
|
should default to 0. |
|
|
|
* `soak_per_iteration_max_acceptable_latency_ms`: An upper limit on the latency |
|
of a single RPC in order for that RPC to be considered successful. This |
|
should default to 1000. |
|
|
|
* `soak_overall_timeout_seconds`: The overall number of seconds after which |
|
the test should stop and fail if `soak_iterations` have not yet been |
|
completed. This should default to |
|
`soak_per_iteration_max_acceptable_latency_ms` * `soak_iterations`. |
|
|
|
* `soak_min_time_ms_between_rpcs`: The minimum time in milliseconds between |
|
consecutive RPCs. Useful for limiting QPS. |
|
|
|
The following is optional but encouraged to improve debuggability: |
|
|
|
* Implementations should log the number of milliseconds that each RPC takes. |
|
Additionally, implementations should use a histogram of RPC latencies |
|
to log interesting latency percentiles at the end of the test (e.g. median, |
|
90th, and max latency percentiles). |
|
|
|
### channel_soak |
|
|
|
Similar to rpc_soak, but this time each RPC is performed on a new channel. The |
|
channel is created just before each RPC and is destroyed just after. |
|
|
|
This test is configured with the same command line flags that the rpc_soak test |
|
is configured with, with only one semantic difference: when measuring an RPCs |
|
latency to see if it exceeds `soak_per_iteration_max_acceptable_latency_ms` or |
|
not, the creation of the channel should be included in that |
|
latency measurement, but the teardown of that channel should **not** be |
|
included in that latency measurement (channel teardown semantics differ widely |
|
between languages). This latency measurement should also be the value that is |
|
logged and recorded in the latency histogram. |
|
|
|
|
|
### orca_per_rpc |
|
[orca_per_rpc]: #orca_per_rpc |
|
|
|
The client verifies that a custom LB policy, which is integrated with ORCA APIs, will receive |
|
per-query metric reports from the backend. |
|
|
|
The client will register the custom LB policy named `test_backend_metrics_load_balancer`, which |
|
using ORCA APIs already installed a per-query report listener. The interop-testing client will run with a |
|
service config to select the load balancing config (using argument `--service_config_json`), so that |
|
it effectively uses this newly registered custom LB policy. A load report reference can be passed |
|
from the call to the LB policy through, e.g. CallOptions, to receive metric reports. |
|
The LB policy will fill in the reference with the latest load report from the report listener. |
|
This way, together with server behaviors we can verify the expected metric reports are received. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Backend Metrics Report][] |
|
|
|
Procedures: |
|
* The client sends a unary request to the server. The call request sets `orca_per_rpc_report` to a |
|
test load report. |
|
``` |
|
{ |
|
orca_per_rpc_report:{ |
|
cpu_utilization: 0.8210 |
|
memory_utilization: 0.5847 |
|
request_cost: { |
|
cost: 3456.32 |
|
} |
|
utilization: { |
|
util: 0.30499 |
|
} |
|
} |
|
} |
|
``` |
|
|
|
The call carries a reference to receive the load report, e.g. using CallOptions. |
|
The reference is passed to the custom LB policy as part of the `OrcaPerRequestReportListener` API. |
|
|
|
Client asserts: |
|
* The call is successful. |
|
* The per-query load report reference contains a metrics report that is identical to the metrics |
|
data sent in the request shown above. |
|
|
|
### orca_oob |
|
|
|
The client verifies that a custom LB policy, which is integrated with ORCA APIs, will receive |
|
out-of-band metric reports from the backend. |
|
|
|
The client will register the custom LB policy named `test_backend_metrics_load_balancer`. It has |
|
similar and additional functions as described in the [orca_per_rpc][] test. |
|
We use ORCA APIs to install an out-of-band report listener (configure load report interval to be 1s) |
|
in the LB policy. The interop-testing client will run with a service config to select the load |
|
balancing config(using argument `--service_config_json`), so that it effectively uses this newly |
|
registered custom LB policy. A load report reference can be passed from the call to the LB policy |
|
through, e.g. CallOptions, to receive metric reports. |
|
The test framework will fill in the reference with the latest load report from the report listener. |
|
This way, together with server behaviors we can verify the expected metric reports are received. |
|
|
|
Server features: |
|
* [UnaryCall][] |
|
* [Backend Metrics Report][] |
|
|
|
Procedures: |
|
* Client sends a unary call to the server. The call request sets `orca_oob_report` to a test load report. |
|
``` |
|
{ |
|
orca_oob_report:{ |
|
cpu_utilization: 0.8210 |
|
memory_utilization: 0.5847 |
|
utilization: { |
|
util: 0.30499 |
|
} |
|
} |
|
} |
|
``` |
|
The call carries a reference to receive the load report, e.g. using CallOptions. |
|
The reference will be passed to the custom LB policy as part of the `OrcaOobReportListener` API. |
|
* Client asserts that, after 1.5 second, the latest OOB load report received is equal to the test load report. |
|
* Client sends another unary call to the server. The call request sets `orca_oob_report` to a |
|
different test load report. |
|
``` |
|
{ |
|
orca_oob_report:{ |
|
cpu_utilization: 0.29309 |
|
memory_utilization: 0.2 |
|
utilization: { |
|
util: 100.2039 |
|
} |
|
} |
|
} |
|
``` |
|
The call still carries a reference to receive the load report. |
|
* Client asserts that, after 1.5 second, the latest OOB load report received is equal to the new test load report. |
|
|
|
### Experimental Tests |
|
|
|
These tests are not yet standardized, and are not yet implemented in all |
|
languages. Therefore they are not part of our interop matrix. |
|
|
|
#### long_lived_channel |
|
|
|
The client performs a number of large_unary RPCs over a single long-lived |
|
channel with a fixed but configurable interval between each RPC. |
|
|
|
#### concurrent_large_unary |
|
|
|
Status: TODO |
|
|
|
Client performs 1000 large_unary tests in parallel on the same channel. |
|
|
|
#### Flow control. Pushback at client for large messages (TODO: fix name) |
|
|
|
Status: TODO |
|
|
|
This test verifies that a client sending faster than a server can drain sees |
|
pushback (i.e., attempts to send succeed only after appropriate delays). |
|
|
|
### TODO Tests |
|
|
|
#### High priority: |
|
|
|
Propagation of status code and message (yangg) |
|
|
|
Multiple thousand simultaneous calls on same Channel (ctiller) |
|
|
|
Metadata: client headers, server headers + trailers, binary+ascii |
|
|
|
#### Normal priority: |
|
|
|
Cancel before start (ctiller) |
|
|
|
Cancel after sent first message (ctiller) |
|
|
|
Cancel after received headers (ctiller) |
|
|
|
Timeout but completed before expire (zhaoq) |
|
|
|
Multiple thousand simultaneous calls timeout on same Channel (ctiller) |
|
|
|
#### Lower priority: |
|
|
|
Flow control. Pushback at client for large messages (abhishek) |
|
|
|
Flow control. Pushback at server for large messages (abhishek) |
|
|
|
Going over max concurrent streams doesn't fail (client controls itself) |
|
(abhishek) |
|
|
|
RPC method not implemented (yangg) |
|
|
|
Multiple thousand simultaneous calls on different Channels (ctiller) |
|
|
|
Failed TLS hostname verification (ejona?) |
|
|
|
Large amount of headers to cause CONTINUATIONs; 63K of 'X's, all in one header. |
|
|
|
#### To priorize: |
|
|
|
Start streaming RPC but don't send any requests, server responds |
|
|
|
### Postponed Tests |
|
|
|
Resilience to buggy servers: These tests would verify that a client application |
|
isn't affected negatively by the responses put on the wire by a buggy server |
|
(e.g. the client library won't make the application crash). |
|
|
|
Reconnect after transport failure |
|
|
|
Reconnect backoff |
|
|
|
Fuzz testing |
|
|
|
|
|
Server |
|
------ |
|
|
|
Servers implement various named features for clients to test with. Server |
|
features are orthogonal. If a server implements a feature, it is always |
|
available for clients. Names are simple descriptions for developer |
|
communication and tracking. |
|
|
|
Servers should accept these arguments: |
|
|
|
* --port=PORT |
|
|
|
* The port to listen on. For example, "8080" |
|
|
|
* --use_tls=BOOLEAN |
|
|
|
* Whether to use a plaintext or encrypted connection |
|
|
|
Servers must support TLS with ALPN. They should use |
|
[server1.pem](https://github.com/grpc/grpc/blob/master/src/core/tsi/test_creds/server1.pem) |
|
for their certificate. |
|
|
|
### EmptyCall |
|
[EmptyCall]: #emptycall |
|
|
|
Server implements EmptyCall which immediately returns the empty message. |
|
|
|
### UnaryCall |
|
[UnaryCall]: #unarycall |
|
|
|
Server implements UnaryCall which immediately returns a SimpleResponse with a |
|
payload body of size `SimpleRequest.response_size` bytes and type as appropriate |
|
for the `SimpleRequest.response_type`. If the server does not support the |
|
`response_type`, then it should fail the RPC with `INVALID_ARGUMENT`. |
|
|
|
### CacheableUnaryCall |
|
[CacheableUnaryCall]: #cacheableunarycall |
|
|
|
Server gets the default SimpleRequest proto as the request. The content of the |
|
request is ignored. It returns the SimpleResponse proto with the payload set |
|
to current timestamp. The timestamp is an integer representing current time |
|
with nanosecond resolution. This integer is formatted as ASCII decimal in the |
|
response. The format is not really important as long as the response payload |
|
is different for each request. In addition it adds |
|
1. cache control headers such that the response can be cached by proxies in |
|
the response path. Server should be behind a caching proxy for this test |
|
to pass. Currently we set the max-age to 60 seconds. |
|
|
|
### CompressedResponse |
|
[CompressedResponse]: #compressedresponse |
|
|
|
When the client sets `response_compressed` to true, the server's response is |
|
sent back compressed. Note that `response_compressed` is present on both |
|
`SimpleRequest` (unary) and `StreamingOutputCallRequest` (streaming). |
|
|
|
### CompressedRequest |
|
[CompressedRequest]: #compressedrequest |
|
|
|
When the client sets `expect_compressed` to true, the server expects the client |
|
request to be compressed. If it's not, it fails the RPC with `INVALID_ARGUMENT`. |
|
Note that `response_compressed` is present on both `SimpleRequest` (unary) and |
|
`StreamingOutputCallRequest` (streaming). |
|
|
|
### StreamingInputCall |
|
[StreamingInputCall]: #streaminginputcall |
|
|
|
Server implements StreamingInputCall which upon half close immediately returns |
|
a StreamingInputCallResponse where aggregated_payload_size is the sum of all |
|
request payload bodies received. |
|
|
|
### StreamingOutputCall |
|
[StreamingOutputCall]: #streamingoutputcall |
|
|
|
Server implements StreamingOutputCall by replying, in order, with one |
|
StreamingOutputCallResponse for each ResponseParameters in |
|
StreamingOutputCallRequest. Each StreamingOutputCallResponse should have a |
|
payload body of size ResponseParameters.size bytes, as specified by its |
|
respective ResponseParameters. After sending all responses, it closes with OK. |
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### FullDuplexCall |
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[FullDuplexCall]: #fullduplexcall |
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Server implements FullDuplexCall by replying, in order, with one |
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StreamingOutputCallResponse for each ResponseParameters in each |
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StreamingOutputCallRequest. Each StreamingOutputCallResponse should have a |
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payload body of size ResponseParameters.size bytes, as specified by its |
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respective ResponseParameters. After receiving half close and sending all |
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responses, it closes with OK. |
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### Echo Status |
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[Echo Status]: #echo-status |
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When the client sends a response_status in the request payload, the server closes |
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the stream with the status code and message contained within said response_status. |
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The server will not process any further messages on the stream sent by the client. |
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This can be used by clients to verify correct handling of different status codes and |
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associated status messages end-to-end. |
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|
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### Echo Metadata |
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[Echo Metadata]: #echo-metadata |
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When the client sends metadata with the key `"x-grpc-test-echo-initial"` with its |
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request, the server sends back exactly this key and the corresponding value back to |
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the client as part of initial metadata. When the client sends metadata with the key |
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`"x-grpc-test-echo-trailing-bin"` with its request, the server sends back exactly this |
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key and the corresponding value back to the client as trailing metadata. |
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|
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### Observe ResponseParameters.interval_us |
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[Observe ResponseParameters.interval_us]: #observe-responseparametersinterval_us |
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In StreamingOutputCall and FullDuplexCall, server delays sending a |
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StreamingOutputCallResponse by the ResponseParameters' `interval_us` for that |
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particular response, relative to the last response sent. That is, `interval_us` |
|
acts like a sleep *before* sending the response and accumulates from one |
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response to the next. |
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|
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Interaction with flow control is unspecified. |
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|
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### Echo Auth Information |
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|
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Status: Pending |
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|
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#### Echo Authenticated Username |
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[Echo Authenticated Username]: #echo-authenticated-username |
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|
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If a SimpleRequest has fill_username=true and that request was successfully |
|
authenticated, then the SimpleResponse should have username filled with the |
|
canonical form of the authenticated source. The canonical form is dependent on |
|
the authentication method, but is likely to be a base 10 integer identifier or |
|
an email address. |
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|
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#### Echo OAuth scope |
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[Echo OAuth Scope]: #echo-oauth-scope |
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|
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If a SimpleRequest has `fill_oauth_scope=true` and that request was successfully |
|
authenticated via OAuth, then the SimpleResponse should have oauth_scope filled |
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with the scope of the method being invoked. |
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|
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Although a general server-side feature, most test servers won't implement this |
|
feature. The TLS server `grpc-test.sandbox.googleapis.com:443` supports this |
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feature. It requires at least the OAuth scope |
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`https://www.googleapis.com/auth/xapi.zoo` for authentication to succeed. |
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Discussion: |
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|
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Ideally, this would be communicated via metadata and not in the |
|
request/response, but we want to use this test in code paths that don't yet |
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fully communicate metadata. |
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### Backend metrics report |
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[Backend Metrics Report]: #backend-metrics-report |
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Server reports backend metrics data in both per-query and out-of-band cases, with metrics data |
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indicated from the unary call request. |
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Using ORCA APIs we install the per-query metrics reporting server interceptor, so that it can attach |
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metrics per RPC. |
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Also using ORCA APIs we register the `OpenRCAService` implementation to the server, so that it can |
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report metrics periodically. The minimum report interval in the ORCA service is set to 1 sec. |
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|
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During test, the server will receive unary requests from the client that each may contain up to two |
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test load report, indicating whether it needs to update metrics for the current call or at the OOB server. |
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Then the server sets the metrics data, echoing the test load report it just received. |
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Specifically: |
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1. If the `orca_per_rpc_report` is set in the request, the server test driver will call |
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`CallMetricRecorder` to record both utilization and |
|
request cost metrics for the current RPC, the metrics data is coped from the received test load |
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report from the request. |
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2. And if the `orca_oob_report` is set in the request, the server test driver will call |
|
`MetricRecorder` to first clear all the previous metrics data, and then record the utilization |
|
metrics, the metrics data is coped from the received test load report from the request.
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