Awesome
go-floc
Floc: Orchestrate goroutines with ease.
The goal of the project is to make the process of running goroutines in parallel and synchronizing them easy.
Announcements
v3
released! The new version keeps the same design as v2
but it distributed now as a Go module and therefore
it has breaking changes.
Migration from v2 to v3
- Install the package with
go get github.com/workanator/go-floc/v3
- Replace all old paths
gopkg.in/workanator/go-floc
togithub.com/workanator/go-floc/v3
- All types from
errors
sub-package moved to the base packagego-floc
. So please, remove all imports of"gopkg.in/workanator/go-floc/errors"
if any and fix type names, e.g.errors.ErrTimeout
->floc.ErrTimeout
Installation and requirements
The package requires Go v1.12 or later.
To install the package use go get github.com/workanator/go-floc/v3
Documentation and examples
Please refer Godoc reference of the package for more details.
Some examples are available at the Godoc reference. Additional examples can be found in go-floc-showcase.
Features
- Easy to use functional interface.
- Simple parallelism and synchronization of jobs.
- As little overhead as possible, in comparison to direct use of goroutines and sync primitives.
- Provide better control over execution with one entry point and one exit point.
Introduction
Floc introduces some terms which are widely used through the package.
Flow
Flow is the overall process which can be controlled through floc.Flow
. Flow
can be canceled or completed with any arbitrary data at any point of execution.
Flow has only one enter point and only one exit point.
// Design the job
flow := run.Sequence(do, something, here, ...)
// The enter point: Run the job
result, data, err := floc.Run(flow)
// The exit point: Check the result of the job.
if err != nil {
// Handle the error
} else if result.IsCompleted() {
// Handle the success
} else {
// Handle other cases
}
Job
Job in Floc is a smallest piece of flow. The prototype of job function is
floc.Job
. Each job can read/write data with floc.Context
and control
the flow with floc.Control
.
Cancel()
, Complete()
, Fail()
methods of floc.Flow
has permanent effect.
Once finished flow cannot be canceled or completed anymore. Calling Fail
and
returning error from job is almost equal.
func ValidateContentLength(ctx floc.Context, ctrl floc.Control) error {
request := ctx.Value("request").(http.Request)
// Cancel the flow with error if request body size is too big
if request.ContentLength > MaxContentLength {
return errors.New("content is too big")
}
return nil
}
Example
Lets have some fun and write a simple example which calculates some statistics on text given.
const Text = `Lorem ipsum dolor sit amet, consectetur adipisicing elit, sed
do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad minim
veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo
consequat. Duis aute irure dolor in reprehenderit in voluptate velit esse cillum
dolore eu fugiat nulla pariatur. Excepteur sint occaecat cupidatat non proident,
sunt in culpa qui officia deserunt mollit anim id est laborum.`
type myKey int
const keyStatistics myKey = 1
var sanitizeWordRe = regexp.MustCompile(`\W`)
type Statistics struct {
Words []string
Characters int
Occurrence map[string]int
}
// Split to words and sanitize them
SplitToWords := func(ctx floc.Context, ctrl floc.Control) error {
statistics := ctx.Value(keyStatistics).(*Statistics)
statistics.Words = strings.Split(Text, " ")
for i, word := range statistics.Words {
statistics.Words[i] = sanitizeWordRe.ReplaceAllString(word, "")
}
return nil
}
// Count and sum the number of characters in the each word
CountCharacters := func(ctx floc.Context, ctrl floc.Control) error {
statistics := ctx.Value(keyStatistics).(*Statistics)
for _, word := range statistics.Words {
statistics.Characters += len(word)
}
return nil
}
// Count the number of unique words
CountUniqueWords := func(ctx floc.Context, ctrl floc.Control) error {
statistics := ctx.Value(keyStatistics).(*Statistics)
statistics.Occurrence = make(map[string]int)
for _, word := range statistics.Words {
statistics.Occurrence[word] = statistics.Occurrence[word] + 1
}
return nil
}
// Print result
PrintResult := func(ctx floc.Context, ctrl floc.Control) error {
statistics := ctx.Value(keyStatistics).(*Statistics)
fmt.Printf("Words Total : %d\n", len(statistics.Words))
fmt.Printf("Unique Word Count : %d\n", len(statistics.Occurrence))
fmt.Printf("Character Count : %d\n", statistics.Characters)
return nil
}
// Design the flow and run it
flow := run.Sequence(
SplitToWords,
run.Parallel(
CountCharacters,
CountUniqueWords,
),
PrintResult,
)
ctx := floc.NewContext()
ctx.AddValue(keyStatistics, new(Statistics))
ctrl := floc.NewControl(ctx)
_, _, err := floc.RunWith(ctx, ctrl, flow)
if err != nil {
panic(err)
}
// Output:
// Words Total : 64
// Unique Word Count : 60
// Character Count : 370
Contributing
Please found information about contributing in CONTRIBUTING.md and the list of braves who spent their priceless time and effort to make the project better in CONTRIBUTORS.md.