README
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core
Core was inspired to capitalize on the Go language for application development. Determining the patterns that need to be employed is critical for writing clear idiomatic Go code. This YouTube video Edward Muller - Go Anti-Patterns, does an excellent job of framing idiomatic go. Robert Griesemer - The Evolution of Go, @ 4:00 minutes, also presents an important analogy between Go modules, packages, closures, and LEGO® bricks. Reviewing the Go standard library packaging structure provides a blueprint for an application architecture, and underscores how essential package design is for idiomatic Go.
Package dependencies also need to be obsessively managed. Rob Pike lists an important deign goal relating copying to dependency in Go Proverbs, #8. Larger dependencies can be imported for test only to insure that the copied code is correct. Kent Beck's book on Test Driven Development, states, "Dependency is the key problem in software development of all scales." Lessening dependencies reduces complexity and increases reliability. Doug McIlroy describes the early approach taken at Bell Labs when developing and revising Research Unix:
We used to sit around in the Unix Room saying, 'What can we throw out? Why is there this option?' It's often because there
is some deficiency in the basic design — you didn't really hit the right design point. Instead of adding an option, think
about what was forcing you to add that option.
With the release of Go generics, a new paradigm has emerged: generic behaviors. Generic behaviors refere to the ability to use a type parameter to modify the behavoir of a function. Semantically, the type parameters that convey behaviors can be analogous to the "control plane" concept, and the type parameters the refer to data can be analogous to the "data plane" concept. The documentation below referes to all generic functions as templated, which is the implementation of generic programming from C++. The term templated is used to convey a wider meaning, encompessing both behavior and data type parameters.
What follows is a description of the packages in Core, highlighting specific patterns and template implementations.
exchange
Exchange provides functionality for processing an Http request/response. Exchange functionality is provied via a templated function, utilizing template paramters for error processing, deserialization type, and the function for processing the http.Client.Do():
func Do[E runtime.ErrorHandler, H Exchange, T any](req *http.Request) (resp *http.Response, t T, status *runtime.Status) {
// implementation details
}
The deserialization function is also templated:
// Deserialize - templated function, providing deserialization of a request/response body
func Deserialize[E runtime.ErrorHandler, T any](body io.ReadCloser) (T, *runtime.Status) {
// implementation details
}
Testing Http calls is implemented through a proxy design pattern: a context.Context interface that contains an http.Client.Do() call.
// HttpExchange - interface for Http request/response interaction
type HttpExchange interface {
Do(req *http.Request) (*http.Response, error)
}
Exchange also includes a common http write response function:
// WriteResponse - write a http.Response, utilizing the data, status, and headers for controlling the content
func WriteResponse(w http.ResponseWriter, buf []byte, status *runtime.Status, headers ...string) {
// implementation details
}
runtime
Runtime implements environment, request context, status, error, and output types. The status type is used extensively as a function return value, and provides error, http, and gRPC status codes.
The error and output types are designed to be used as template parameters.
// ErrorHandler - template parameter error handler interface
type ErrorHandler interface {
Handle(location string, errs ...error) *runtime.Status
HandleWithContext(ctx context.Context, location string, errs ...error) *runtime.Status
HandleStatus(s *runtime.Status) *runtime.Status
}
// OutputHandler - template parameter output handler interface
type OutputHandler interface {
Write(s string)
}
Context functionality is provied for a request Id, and a ProxyContext used for testing:
// ContextWithRequestId - creates a new Context with a request id
func ContextWithRequestId(ctx context.Context, requestId string) context.Context {
// implementation details
}
// ContextWithProxy - create a new Context interface, containing a proxy
func ContextWithProxy(ctx context.Context, proxy any) context.Context {
// implementation details
}
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