Mock Server

Pact Go enables consumer driven contract testing, providing a mock service and DSL for the consumer project, and interaction playback and verification for the service provider project. Consumer side Pact testing is an isolated test that ensures a given component is able to collaborate with another (remote) component. Pact will automatically start a Mock server in the background that will act as the collaborators' test double. This implies that any interactions expected on the Mock server will be validated, meaning a test will fail if all interactions were not completed, or if unexpected interactions were found: A typical consumer-side test would look something like this: If this test completed successfully, a Pact file should have been written to ./pacts/my_consumer-my_provider.json containing all of the interactions expected to occur between the Consumer and Provider. In addition to verbatim value matching, you have 3 useful matching functions in the `dsl` package that can increase expressiveness and reduce brittle test cases. Here is a complex example that shows how all 3 terms can be used together: This example will result in a response body from the mock server that looks like: See the examples in the dsl package and the matcher tests (https://github.com/pact-foundation/pact-go/blob/master/dsl/matcher_test.go) for more matching examples. NOTE: You will need to use valid Ruby regular expressions (http://ruby-doc.org/core-2.1.5/Regexp.html) and double escape backslashes. Read more about flexible matching (https://github.com/pact-foundation/pact-ruby/wiki/Regular-expressions-and-type-matching-with-Pact. Provider side Pact testing, involves verifying that the contract - the Pact file - can be satisfied by the Provider. A typical Provider side test would like something like: The `VerifyProvider` will handle all verifications, treating them as subtests and giving you granular test reporting. If you don't like this behaviour, you may call `VerifyProviderRaw` directly and handle the errors manually. Note that `PactURLs` may be a list of local pact files or remote based urls (possibly from a Pact Broker - http://docs.pact.io/documentation/sharings_pacts.html). Pact reads the specified pact files (from remote or local sources) and replays the interactions against a running Provider. If all of the interactions are met we can say that both sides of the contract are satisfied and the test passes. When validating a Provider, you have 3 options to provide the Pact files: 1. Use "PactURLs" to specify the exact set of pacts to be replayed: Options 2 and 3 are particularly useful when you want to validate that your Provider is able to meet the contracts of what's in Production and also the latest in development. See this [article](http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) for more on this strategy. Each interaction in a pact should be verified in isolation, with no context maintained from the previous interactions. So how do you test a request that requires data to exist on the provider? Provider states are how you achieve this using Pact. Provider states also allow the consumer to make the same request with different expected responses (e.g. different response codes, or the same resource with a different subset of data). States are configured on the consumer side when you issue a dsl.Given() clause with a corresponding request/response pair. Configuring the provider is a little more involved, and (currently) requires running an API endpoint to configure any [provider states](http://docs.pact.io/documentation/provider_states.html) during the verification process. The option you must provide to the dsl.VerifyRequest is: An example route using the standard Go http package might look like this: See the examples or read more at http://docs.pact.io/documentation/provider_states.html. See the Pact Broker (http://docs.pact.io/documentation/sharings_pacts.html) documentation for more details on the Broker and this article (http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) on how to make it work for you. Publishing using Go code: Publishing from the CLI: Use a cURL request like the following to PUT the pact to the right location, specifying your consumer name, provider name and consumer version. The following flags are required to use basic authentication when publishing or retrieving Pact files to/from a Pact Broker: Pact Go uses a simple log utility (logutils - https://github.com/hashicorp/logutils) to filter log messages. The CLI already contains flags to manage this, should you want to control log level in your tests, you can set it like so:

Package grpcreplay supports the capture and replay of gRPC calls. Its main goal is to improve testing. Once you capture the calls of a test that runs against a real service, you have an "automatic mock" that can be replayed against the same test, yielding a unit test that is fast and flake-free. To record a sequence of gRPC calls to a file, create a Recorder and pass its DialOptions to grpc.Dial: It is essential to close the Recorder when the interaction is finished. There is also a NewRecorderWriter function for capturing to an arbitrary io.Writer. To replay a captured file, create a Replayer and ask it for a (fake) connection. We don't actually have to dial a server. (Since we're reading the file and not writing it, we don't have to be as careful about the error returned from Close). A test might use random or time-sensitive values, for instance to create unique resources for isolation from other tests. The test therefore has initial values, such as the current time, or a random seed, that differ from run to run. You must record this initial state and re-establish it on replay. To record the initial state, serialize it into a []byte and pass it as the second argument to NewRecorder: On replay, get the bytes from Replayer.Initial: Recorders and replayers have support for running callbacks before messages are written to or read from the replay file. A Recorder has a BeforeFunc that can modify a request or response before it is written to the replay file. The actual RPCs sent to the service during recording remain unaltered; only what is saved in the replay file can be changed. A Replayer has a BeforeFunc that can modify a request before it is sent for matching. Example uses for these callbacks include customized logging, or scrubbing data before RPCs are written to the replay file. If requests are modified by the callbacks during recording, it is important to perform the same modifications to the requests when replaying, or RPC matching on replay will fail. A common way to analyze and modify the various messages is to use a type switch. A nondeterministic program may invoke RPCs in a different order each time it is run. The order in which RPCs are called during recording may differ from the order during replay. The replayer matches incoming to recorded requests by method name and request contents, so nondeterminism is only a concern for identical requests that result in different responses. A nondeterministic program whose behavior differs depending on the order of such RPCs probably has a race condition: since both the recorded sequence of RPCs and the sequence during replay are valid orderings, the program should behave the same under both. The same is not true of streaming RPCs. The replayer matches streams only by method name, since it has no other information at the time the stream is opened. Two streams with the same method name that are started concurrently may replay in the wrong order. Besides the differences in replay mentioned above, other differences may cause issues for some programs. We list them here. The Replayer delivers a response to an RPC immediately, without waiting for other incoming RPCs. This can violate causality. For example, in a Pub/Sub program where one goroutine publishes and another subscribes, during replay the Subscribe call may finish before the Publish call begins. For streaming RPCs, the Replayer delivers the result of Send and Recv calls in the order they were recorded. No attempt is made to match message contents. At present, this package does not record or replay stream headers and trailers, or the result of the CloseSend method.

Pact Go enables consumer driven contract testing, providing a mock service and DSL for the consumer project, and interaction playback and verification for the service provider project. Consumer side Pact testing is an isolated test that ensures a given component is able to collaborate with another (remote) component. Pact will automatically start a Mock server in the background that will act as the collaborators' test double. This implies that any interactions expected on the Mock server will be validated, meaning a test will fail if all interactions were not completed, or if unexpected interactions were found: A typical consumer-side test would look something like this: If this test completed successfully, a Pact file should have been written to ./pacts/my_consumer-my_provider.json containing all of the interactions expected to occur between the Consumer and Provider. In addition to verbatim value matching, you have 3 useful matching functions in the `dsl` package that can increase expressiveness and reduce brittle test cases. Here is a complex example that shows how all 3 terms can be used together: This example will result in a response body from the mock server that looks like: See the examples in the dsl package and the matcher tests (https://github.com/pact-foundation/pact-go/v2/blob/master/dsl/matcher_test.go) for more matching examples. NOTE: You will need to use valid Ruby regular expressions (http://ruby-doc.org/core-2.1.5/Regexp.html) and double escape backslashes. Read more about flexible matching (https://github.com/pact-foundation/pact-ruby/wiki/Regular-expressions-and-type-matching-with-Pact. Provider side Pact testing, involves verifying that the contract - the Pact file - can be satisfied by the Provider. A typical Provider side test would like something like: The `VerifyProvider` will handle all verifications, treating them as subtests and giving you granular test reporting. If you don't like this behaviour, you may call `VerifyProviderRaw` directly and handle the errors manually. Note that `PactURLs` may be a list of local pact files or remote based urls (possibly from a Pact Broker - http://docs.pact.io/documentation/sharings_pacts.html). Pact reads the specified pact files (from remote or local sources) and replays the interactions against a running Provider. If all of the interactions are met we can say that both sides of the contract are satisfied and the test passes. When validating a Provider, you have 3 options to provide the Pact files: 1. Use "PactURLs" to specify the exact set of pacts to be replayed: Options 2 and 3 are particularly useful when you want to validate that your Provider is able to meet the contracts of what's in Production and also the latest in development. See this [article](http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) for more on this strategy. Each interaction in a pact should be verified in isolation, with no context maintained from the previous interactions. So how do you test a request that requires data to exist on the provider? Provider states are how you achieve this using Pact. Provider states also allow the consumer to make the same request with different expected responses (e.g. different response codes, or the same resource with a different subset of data). States are configured on the consumer side when you issue a dsl.Given() clause with a corresponding request/response pair. Configuring the provider is a little more involved, and (currently) requires running an API endpoint to configure any [provider states](http://docs.pact.io/documentation/provider_states.html) during the verification process. The option you must provide to the dsl.VerifyRequest is: An example route using the standard Go http package might look like this: See the examples or read more at http://docs.pact.io/documentation/provider_states.html. See the Pact Broker (http://docs.pact.io/documentation/sharings_pacts.html) documentation for more details on the Broker and this article (http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) on how to make it work for you. Publishing using Go code: Publishing from the CLI: Use a cURL request like the following to PUT the pact to the right location, specifying your consumer name, provider name and consumer version. The following flags are required to use basic authentication when publishing or retrieving Pact files to/from a Pact Broker: Pact Go uses a simple log utility (logutils - https://github.com/hashicorp/logutils) to filter log messages. The CLI already contains flags to manage this, should you want to control log level in your tests, you can set it like so:

Package pgmock provides the ability to mock a PostgreSQL server.

Package gsrv creates a test gRPC server that is useful when mocking a gRPC service. A complete example of mocking a gRPC service that leverges this package is available at https://github.com/weathersource/go-gsrv/tree/master/examples/foo This package is based on Google's testutil.Server. Original code is found at https://github.com/GoogleCloudPlatform/google-cloud-go/blob/master/internal/testutil/server.go

Package ovirtclient provides a human-friendly Go client for the oVirt Engine. It provides an abstraction layer for the oVirt API, as well as a mocking facility for testing purposes. This documentation contains two parts. This introduction explains setting up the client with the credentials. The API doc contains the individual API calls. When reading the API doc, start with the Client interface: it contains all components of the API. The individual API's, their documentation and examples are located in subinterfaces, such as DiskClient. There are several ways to create a client instance. The most basic way is to use the New() function as follows: The mock client simulates the oVirt engine behavior in-memory without needing an actual running engine. This is a good way to provide a testing facility. It can be created using the NewMock method: That's it! However, to make it really useful, you will need the test helper which can set up test fixtures. The test helper can work in two ways: Either it sets up test fixtures in the mock client, or it sets up a live connection and identifies a usable storage domain, cluster, etc. for testing purposes. The ovirtclient.NewMockTestHelper() function can be used to create a test helper with a mock client in the backend: The easiest way to set up the test helper for a live connection is by using environment variables. To do that, you can use the ovirtclient.NewLiveTestHelperFromEnv() function: This function will inspect environment variables to determine if a connection to a live oVirt engine can be established. The following environment variables are supported: URL of the oVirt engine API. Mandatory. The username for the oVirt engine. Mandatory. The password for the oVirt engine. Mandatory. A file containing the CA certificate in PEM format. Provide the CA certificate in PEM format directly. Disable certificate verification if set. Not recommended. The cluster to use for testing. Will be automatically chosen if not provided. ID of the blank template. Will be automatically chosen if not provided. Storage domain to use for testing. Will be automatically chosen if not provided. VNIC profile to use for testing. Will be automatically chosen if not provided. You can also create the test helper manually: This library provides extensive logging. Each API interaction is logged on the debug level, and other messages are added on other levels. In order to provide logging this library uses the go-ovirt-client-log (https://github.com/oVirt/go-ovirt-client-log) interface definition. As long as your logger implements this interface, you will be able to receive log messages. The logging library also provides a few built-in loggers. For example, you can log via the default Go log interface: Or, you can also log in tests: You can also disable logging: Finally, we also provide an adapter library for klog here: https://github.com/oVirt/go-ovirt-client-log-klog Modern-day oVirt engines run secured with TLS. This means that the client needs a way to verify the certificate the server is presenting. This is controlled by the tls parameter of the New() function. You can implement your own source by implementing the TLSProvider interface, but the package also includes a ready-to-use provider. Create the provider using the TLS() function: This provider has several functions. The easiest to set up is using the system trust root for certificates. However, this won't work own Windows: Now you need to add your oVirt engine certificate to your system trust root. If you don't want to, or can't add the certificate to the system trust root, you can also directly provide it to the client. Finally, you can also disable certificate verification. Do we need to say that this is a very, very bad idea? The configured tls variable can then be passed to the New() function to create an oVirt client. This library attempts to retry API calls that can be retried if possible. Each function has a sensible retry policy. However, you may want to customize the retries by passing one or more retry flags. The following retry flags are supported: This strategy will stop retries when the context parameter is canceled. This strategy adds a wait time after each time, which is increased by the given factor on each try. The default is a backoff with a factor of 2. This strategy will cancel retries if the error in question is a permanent error. This is enabled by default. This strategy will abort retries if a maximum number of tries is reached. On complex calls the retries are counted per underlying API call. This strategy will abort retries if a certain time has been elapsed for the higher level call. This strategy will abort retries if a certain underlying API call takes longer than the specified duration.

Pact Go enables consumer driven contract testing, providing a mock service and DSL for the consumer project, and interaction playback and verification for the service provider project. Consumer side Pact testing is an isolated test that ensures a given component is able to collaborate with another (remote) component. Pact will automatically start a Mock server in the background that will act as the collaborators' test double. This implies that any interactions expected on the Mock server will be validated, meaning a test will fail if all interactions were not completed, or if unexpected interactions were found: A typical consumer-side test would look something like this: If this test completed successfully, a Pact file should have been written to ./pacts/my_consumer-my_provider.json containing all of the interactions expected to occur between the Consumer and Provider. In addition to verbatim value matching, you have 3 useful matching functions in the `dsl` package that can increase expressiveness and reduce brittle test cases. Here is a complex example that shows how all 3 terms can be used together: This example will result in a response body from the mock server that looks like: See the examples in the dsl package and the matcher tests (https://github.com/pact-foundation/pact-go/blob/master/dsl/matcher_test.go) for more matching examples. NOTE: You will need to use valid Ruby regular expressions (http://ruby-doc.org/core-2.1.5/Regexp.html) and double escape backslashes. Read more about flexible matching (https://github.com/pact-foundation/pact-ruby/wiki/Regular-expressions-and-type-matching-with-Pact. Provider side Pact testing, involves verifying that the contract - the Pact file - can be satisfied by the Provider. A typical Provider side test would like something like: The `VerifyProvider` will handle all verifications, treating them as subtests and giving you granular test reporting. If you don't like this behaviour, you may call `VerifyProviderRaw` directly and handle the errors manually. Note that `PactURLs` may be a list of local pact files or remote based urls (possibly from a Pact Broker - http://docs.pact.io/documentation/sharings_pacts.html). Pact reads the specified pact files (from remote or local sources) and replays the interactions against a running Provider. If all of the interactions are met we can say that both sides of the contract are satisfied and the test passes. When validating a Provider, you have 3 options to provide the Pact files: 1. Use "PactURLs" to specify the exact set of pacts to be replayed: Options 2 and 3 are particularly useful when you want to validate that your Provider is able to meet the contracts of what's in Production and also the latest in development. See this [article](http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) for more on this strategy. Each interaction in a pact should be verified in isolation, with no context maintained from the previous interactions. So how do you test a request that requires data to exist on the provider? Provider states are how you achieve this using Pact. Provider states also allow the consumer to make the same request with different expected responses (e.g. different response codes, or the same resource with a different subset of data). States are configured on the consumer side when you issue a dsl.Given() clause with a corresponding request/response pair. Configuring the provider is a little more involved, and (currently) requires running an API endpoint to configure any [provider states](http://docs.pact.io/documentation/provider_states.html) during the verification process. The option you must provide to the dsl.VerifyRequest is: An example route using the standard Go http package might look like this: See the examples or read more at http://docs.pact.io/documentation/provider_states.html. See the Pact Broker (http://docs.pact.io/documentation/sharings_pacts.html) documentation for more details on the Broker and this article (http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) on how to make it work for you. Publishing using Go code: Publishing from the CLI: Use a cURL request like the following to PUT the pact to the right location, specifying your consumer name, provider name and consumer version. The following flags are required to use basic authentication when publishing or retrieving Pact files to/from a Pact Broker: Pact Go uses a simple log utility (logutils - https://github.com/hashicorp/logutils) to filter log messages. The CLI already contains flags to manage this, should you want to control log level in your tests, you can set it like so:

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package gizmo is a toolkit that provides packages to put together server and pubsub daemons with the following features: ## The `config` packages The `config` package contains a handful of useful functions to load to configuration structs from JSON files, JSON blobs in Consul k/v or environment variables. The subpackages contain structs meant for managing common configuration options and credentials. There are currently configs for: The package also has a generic `Config` type in the `config/combined` subpackage that contains all of the above types. It's meant to be a 'catch all' convenience struct that many applications should be able to use. The `server` package This package is the bulk of the toolkit and relies on `server.Config` for any managing `Server` implementations. A server must implement the following interface: The package offers 2 server implementations: `SimpleServer`, which is capable of handling basic HTTP and JSON requests via 3 of the available `Service` implementations: `SimpleService`, `JSONService`, `ContextService`, `MixedService` and `MixedContextService`. A service and these implenetations will be defined below. `RPCServer`, which is capable of serving a gRPC server on one port and JSON endpoints on another. This kind of server can only handle the `RPCService` implementation. The `Service` interface is minimal to allow for maximum flexibility: The 3 service types that are accepted and hostable on the `SimpleServer`: Where `JSONEndpoint`, `JSONContextEndpoint`, `ContextHandler` and `ContextHandlerFunc` are defined as: Also, the one service type that works with an `RPCServer`: The `Middleware(..)` functions offer each service a 'hook' to wrap each of its endpoints. This may be handy for adding additional headers or context to the request. This is also the point where other, third-party middleware could be easily be plugged in (ie. oauth, tracing, metrics, logging, etc.) This package contains two generic interfaces for publishing data to queues and subscribing and consuming data from those queues. Where a `SubscriberMessage` is an interface that gives implementations a hook for acknowledging/delete messages. Take a look at the docs for each implementation in `pubsub` to see how they behave. There are currently 3 implementations of each type of `pubsub` interfaces: For pubsub via Amazon's SNS/SQS, you can use the `pubsub/aws` package. For pubsub via Google's Pubsub, you can use the `pubsub/gcp` package. For pubsub via Kafka topics, you can use the `pubsub/kafka` package. For publishing via HTTP, you can use the `pubsub/http` package. The `pubsub/pubsubtest` package This package contains 'test' implementations of the `pubsub.Publisher` and `pubsub.Subscriber` interfaces that will allow developers to easily mock out and test their `pubsub` implementations: This package contains a handful of very useful functions for parsing types from request queries and payloads. For examples of how to use the gizmo `server` and `pubsub` packages, take a look at the 'examples' subdirectory. The Gizmo logo was based on the Go mascot designed by Renée French and copyrighted under the Creative Commons Attribution 3.0 license.

Package gizmo is a toolkit that provides packages to put together server and pubsub daemons with the following features: ## The `config` packages The `config` package contains a handful of useful functions to load to configuration structs from JSON files, JSON blobs in Consul k/v or environment variables. The subpackages contain structs meant for managing common configuration options and credentials. There are currently configs for: The package also has a generic `Config` type in the `config/combined` subpackage that contains all of the above types. It's meant to be a 'catch all' convenience struct that many applications should be able to use. The `server` package This package is the bulk of the toolkit and relies on `server.Config` for any managing `Server` implementations. A server must implement the following interface: The package offers 2 server implementations: `SimpleServer`, which is capable of handling basic HTTP and JSON requests via 3 of the available `Service` implementations: `SimpleService`, `JSONService`, `ContextService`, `MixedService` and `MixedContextService`. A service and these implenetations will be defined below. `RPCServer`, which is capable of serving a gRPC server on one port and JSON endpoints on another. This kind of server can only handle the `RPCService` implementation. The `Service` interface is minimal to allow for maximum flexibility: The 3 service types that are accepted and hostable on the `SimpleServer`: Where `JSONEndpoint`, `JSONContextEndpoint`, `ContextHandler` and `ContextHandlerFunc` are defined as: Also, the one service type that works with an `RPCServer`: The `Middleware(..)` functions offer each service a 'hook' to wrap each of its endpoints. This may be handy for adding additional headers or context to the request. This is also the point where other, third-party middleware could be easily be plugged in (ie. oauth, tracing, metrics, logging, etc.) This package contains two generic interfaces for publishing data to queues and subscribing and consuming data from those queues. Where a `SubscriberMessage` is an interface that gives implementations a hook for acknowledging/delete messages. Take a look at the docs for each implementation in `pubsub` to see how they behave. There are currently 3 implementations of each type of `pubsub` interfaces: For pubsub via Amazon's SNS/SQS, you can use the `pubsub/aws` package. For pubsub via Google's Pubsub, you can use the `pubsub/gcp` package. For pubsub via Kafka topics, you can use the `pubsub/kafka` package. For publishing via HTTP, you can use the `pubsub/http` package. The `pubsub/pubsubtest` package This package contains 'test' implementations of the `pubsub.Publisher` and `pubsub.Subscriber` interfaces that will allow developers to easily mock out and test their `pubsub` implementations: This package contains a handful of very useful functions for parsing types from request queries and payloads. For examples of how to use the gizmo `server` and `pubsub` packages, take a look at the 'examples' subdirectory. The Gizmo logo was based on the Go mascot designed by Renée French and copyrighted under the Creative Commons Attribution 3.0 license.

Package wiremock is client for WireMock API. WireMock is a simulator for HTTP-based APIs. Some might consider it a service virtualization tool or a mock server. HTTP request: With response: Stub: The client should reset all made stubs after tests: To avoid conflicts, you can delete individual rules: You can verify if a request has been made that matches the mapping.

Pact Go enables consumer driven contract testing, providing a mock service and DSL for the consumer project, and interaction playback and verification for the service provider project. Consumer side Pact testing is an isolated test that ensures a given component is able to collaborate with another (remote) component. Pact will automatically start a Mock server in the background that will act as the collaborators' test double. This implies that any interactions expected on the Mock server will be validated, meaning a test will fail if all interactions were not completed, or if unexpected interactions were found: A typical consumer-side test would look something like this: If this test completed successfully, a Pact file should have been written to ./pacts/my_consumer-my_provider.json containing all of the interactions expected to occur between the Consumer and Provider. In addition to verbatim value matching, you have 3 useful matching functions in the `dsl` package that can increase expressiveness and reduce brittle test cases. Here is a complex example that shows how all 3 terms can be used together: colour := Term("red", "red|green|blue") match := EachLike( This example will result in a response body from the mock server that looks like: See the examples in the dsl package and the matcher tests (https://github.com/pact-foundation/pact-go/blob/master/dsl/matcher_test.go) for more matching examples. NOTE: You will need to use valid Ruby regular expressions (http://ruby-doc.org/core-2.1.5/Regexp.html) and double escape backslashes. Read more about flexible matching (https://github.com/pact-foundation/pact-ruby/wiki/Regular-expressions-and-type-matching-with-Pact. Provider side Pact testing, involves verifying that the contract - the Pact file - can be satisfied by the Provider. A typical Provider side test would like something like: The `VerifyProvider` will handle all verifications, treating them as subtests and giving you granular test reporting. If you don't like this behaviour, you may call `VerifyProviderRaw` directly and handle the errors manually. Note that `PactURLs` may be a list of local pact files or remote based urls (possibly from a Pact Broker - http://docs.pact.io/documentation/sharings_pacts.html). Pact reads the specified pact files (from remote or local sources) and replays the interactions against a running Provider. If all of the interactions are met we can say that both sides of the contract are satisfied and the test passes. When validating a Provider, you have 3 options to provide the Pact files: 1. Use "PactURLs" to specify the exact set of pacts to be replayed: 2. Use "PactBroker" to automatically find all of the latest consumers: 3. Use "PactBroker" and "Tags" to automatically find all of the latest consumers: Options 2 and 3 are particularly useful when you want to validate that your Provider is able to meet the contracts of what's in Production and also the latest in development. See this [article](http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) for more on this strategy. Each interaction in a pact should be verified in isolation, with no context maintained from the previous interactions. So how do you test a request that requires data to exist on the provider? Provider states are how you achieve this using Pact. Provider states also allow the consumer to make the same request with different expected responses (e.g. different response codes, or the same resource with a different subset of data). States are configured on the consumer side when you issue a dsl.Given() clause with a corresponding request/response pair. Configuring the provider is a little more involved, and (currently) requires running an API endpoint to configure any [provider states](http://docs.pact.io/documentation/provider_states.html) during the verification process. The option you must provide to the dsl.VerifyRequest is: An example route using the standard Go http package might look like this: See the examples or read more at http://docs.pact.io/documentation/provider_states.html. See the Pact Broker (http://docs.pact.io/documentation/sharings_pacts.html) documentation for more details on the Broker and this article (http://rea.tech/enter-the-pact-matrix-or-how-to-decouple-the-release-cycles-of-your-microservices/) on how to make it work for you. Publishing using Go code: Publishing from the CLI: Use a cURL request like the following to PUT the pact to the right location, specifying your consumer name, provider name and consumer version. The following flags are required to use basic authentication when publishing or retrieving Pact files to/from a Pact Broker: Pact Go uses a simple log utility (logutils - https://github.com/hashicorp/logutils) to filter log messages. The CLI already contains flags to manage this, should you want to control log level in your tests, you can set it like so:

Package graylog provides Golang's structs which represents Graylog resource such as roles and users. Client and mock server and terraform provider are provided as subpackages. https://godoc.org/github.com/suzuki-shunsuke/go-graylog/#pkg-subdirectories

Package ovirtclient provides a human-friendly Go client for the oVirt Engine. It provides an abstraction layer for the oVirt API, as well as a mocking facility for testing purposes. This documentation contains two parts. This introduction explains setting up the client with the credentials. The API doc contains the individual API calls. When reading the API doc, start with the Client interface: it contains all components of the API. The individual API's, their documentation and examples are located in subinterfaces, such as DiskClient. There are several ways to create a client instance. The most basic way is to use the New() function as follows: The mock client simulates the oVirt engine behavior in-memory without needing an actual running engine. This is a good way to provide a testing facility. It can be created using the NewMock method: That's it! However, to make it really useful, you will need the test helper which can set up test fixtures. The test helper can work in two ways: Either it sets up test fixtures in the mock client, or it sets up a live connection and identifies a usable storage domain, cluster, etc. for testing purposes. The ovirtclient.NewMockTestHelper() function can be used to create a test helper with a mock client in the backend: The easiest way to set up the test helper for a live connection is by using environment variables. To do that, you can use the ovirtclient.NewLiveTestHelperFromEnv() function: This function will inspect environment variables to determine if a connection to a live oVirt engine can be established. The following environment variables are supported: URL of the oVirt engine API. Mandatory. The username for the oVirt engine. Mandatory. The password for the oVirt engine. Mandatory. A file containing the CA certificate in PEM format. Provide the CA certificate in PEM format directly. Disable certificate verification if set. Not recommended. The cluster to use for testing. Will be automatically chosen if not provided. ID of the blank template. Will be automatically chosen if not provided. Storage domain to use for testing. Will be automatically chosen if not provided. VNIC profile to use for testing. Will be automatically chosen if not provided. You can also create the test helper manually: This library provides extensive logging. Each API interaction is logged on the debug level, and other messages are added on other levels. In order to provide logging this library uses the go-ovirt-client-log (https://github.com/oVirt/go-ovirt-client-log) interface definition. As long as your logger implements this interface, you will be able to receive log messages. The logging library also provides a few built-in loggers. For example, you can log via the default Go log interface: Or, you can also log in tests: You can also disable logging: Finally, we also provide an adapter library for klog here: https://github.com/oVirt/go-ovirt-client-log-klog Modern-day oVirt engines run secured with TLS. This means that the client needs a way to verify the certificate the server is presenting. This is controlled by the tls parameter of the New() function. You can implement your own source by implementing the TLSProvider interface, but the package also includes a ready-to-use provider. Create the provider using the TLS() function: This provider has several functions. The easiest to set up is using the system trust root for certificates. However, this won't work own Windows: Now you need to add your oVirt engine certificate to your system trust root. If you don't want to, or can't add the certificate to the system trust root, you can also directly provide it to the client. Finally, you can also disable certificate verification. Do we need to say that this is a very, very bad idea? The configured tls variable can then be passed to the New() function to create an oVirt client. This library attempts to retry API calls that can be retried if possible. Each function has a sensible retry policy. However, you may want to customize the retries by passing one or more retry flags. The following retry flags are supported: This strategy will stop retries when the context parameter is canceled. This strategy adds a wait time after each time, which is increased by the given factor on each try. The default is a backoff with a factor of 2. This strategy will cancel retries if the error in question is a permanent error. This is enabled by default. This strategy will abort retries if a maximum number of tries is reached. On complex calls the retries are counted per underlying API call. This strategy will abort retries if a certain time has been elapsed for the higher level call. This strategy will abort retries if a certain underlying API call takes longer than the specified duration.

Package ovirtclient provides a human-friendly Go client for the oVirt Engine. It provides an abstraction layer for the oVirt API, as well as a mocking facility for testing purposes. This documentation contains two parts. This introduction explains setting up the client with the credentials. The API doc contains the individual API calls. When reading the API doc, start with the Client interface: it contains all components of the API. The individual API's, their documentation and examples are located in subinterfaces, such as DiskClient. There are several ways to create a client instance. The most basic way is to use the New() function as follows: The mock client simulates the oVirt engine behavior in-memory without needing an actual running engine. This is a good way to provide a testing facility. It can be created using the NewMock method: That's it! However, to make it really useful, you will need the test helper which can set up test fixtures. The test helper can work in two ways: Either it sets up test fixtures in the mock client, or it sets up a live connection and identifies a usable storage domain, cluster, etc. for testing purposes. The ovirtclient.NewMockTestHelper() function can be used to create a test helper with a mock client in the backend: The easiest way to set up the test helper for a live connection is by using environment variables. To do that, you can use the ovirtclient.NewLiveTestHelperFromEnv() function: This function will inspect environment variables to determine if a connection to a live oVirt engine can be established. The following environment variables are supported: URL of the oVirt engine API. Mandatory. The username for the oVirt engine. Mandatory. The password for the oVirt engine. Mandatory. A file containing the CA certificate in PEM format. Provide the CA certificate in PEM format directly. Disable certificate verification if set. Not recommended. The cluster to use for testing. Will be automatically chosen if not provided. ID of the blank template. Will be automatically chosen if not provided. Storage domain to use for testing. Will be automatically chosen if not provided. VNIC profile to use for testing. Will be automatically chosen if not provided. You can also create the test helper manually: This library provides extensive logging. Each API interaction is logged on the debug level, and other messages are added on other levels. In order to provide logging this library uses the go-ovirt-client-log (https://github.com/oVirt/go-ovirt-client-log) interface definition. As long as your logger implements this interface, you will be able to receive log messages. The logging library also provides a few built-in loggers. For example, you can log via the default Go log interface: Or, you can also log in tests: You can also disable logging: Finally, we also provide an adapter library for klog here: https://github.com/oVirt/go-ovirt-client-log-klog Modern-day oVirt engines run secured with TLS. This means that the client needs a way to verify the certificate the server is presenting. This is controlled by the tls parameter of the New() function. You can implement your own source by implementing the TLSProvider interface, but the package also includes a ready-to-use provider. Create the provider using the TLS() function: This provider has several functions. The easiest to set up is using the system trust root for certificates. However, this won't work own Windows: Now you need to add your oVirt engine certificate to your system trust root. If you don't want to, or can't add the certificate to the system trust root, you can also directly provide it to the client. Finally, you can also disable certificate verification. Do we need to say that this is a very, very bad idea? The configured tls variable can then be passed to the New() function to create an oVirt client. This library attempts to retry API calls that can be retried if possible. Each function has a sensible retry policy. However, you may want to customize the retries by passing one or more retry flags. The following retry flags are supported: This strategy will stop retries when the context parameter is canceled. This strategy adds a wait time after each time, which is increased by the given factor on each try. The default is a backoff with a factor of 2. This strategy will cancel retries if the error in question is a permanent error. This is enabled by default. This strategy will abort retries if a maximum number of tries is reached. On complex calls the retries are counted per underlying API call. This strategy will abort retries if a certain time has been elapsed for the higher level call. This strategy will abort retries if a certain underlying API call takes longer than the specified duration.

List of mocks used for testing Various responses to a LWM2M Server request Typically responses represent a CoAP Request code

Package wiremock is client for WireMock API. WireMock is a simulator for HTTP-based APIs. Some might consider it a service virtualization tool or a mock server. HTTP request: With response: Stub: The client should reset all made stubs after tests: To avoid conflicts, you can delete individual rules: You can verify if a request has been made that matches the mapping.

Package graylog provides Golang's structs which represents Graylog resource such as roles and users. Client and mock server and terraform provider are provided as subpackages. https://godoc.org/github.com/suzuki-shunsuke/go-graylog/#pkg-subdirectories

Package graylog provides Golang's structs which represents Graylog resource such as roles and users. Client and mock server and terraform provider are provided as subpackages. https://godoc.org/github.com/suzuki-shunsuke/go-graylog/#pkg-subdirectories

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices

Package micro is a pluggable framework for microservices