samuell/dataflow_syntax_example.go

## dataflow_syntax_example.go
package main

import (
	"fmt"
	"math"
	"strings"
)

const (
	BUFSIZE = 16
)

// ======= Main =======

func main() {
	// Init processes
	hisay := NewHiSayer()
	split := NewStringSplitter()
	lower := NewLowerCaser()
	upper := NewUpperCaser()
	zippr := NewZipper()
	prntr := NewPrinter()

	// Network definition *** This is where to look! ***
	split.In = hisay.Out
	lower.In = split.OutLeft
	upper.In = split.OutRight
	zippr.In1 = lower.Out
	zippr.In2 = upper.Out
	prntr.In = zippr.Out

	// Set up processes for running (spawn go-routines)
	go hisay.Run()
	go split.Run()
	go lower.Run()
	go upper.Run()
	go zippr.Run()
	prntr.Run()

	println("Finished program!")
}

// ======= HiSayer =======

type hiSayer struct {
	Out chan string
}

func NewHiSayer() *hiSayer {
	return &hiSayer{Out: make(chan string, BUFSIZE)}
}

func (proc *hiSayer) Run() {
	defer close(proc.Out)
	for _, i := range []int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10} {
		proc.Out <- fmt.Sprintf("Hi for the %d:th time!", i)
	}
}

// ======= StringSplitter =======

type stringSplitter struct {
	In       chan string
	OutLeft  chan string
	OutRight chan string
}

func NewStringSplitter() *stringSplitter {
	return &stringSplitter{
		OutLeft:  make(chan string, BUFSIZE),
		OutRight: make(chan string, BUFSIZE),
	}
}

func (proc *stringSplitter) Run() {
	defer close(proc.OutLeft)
	defer close(proc.OutRight)
	for s := range proc.In {
		halfLen := int(math.Floor(float64(len(s)) / float64(2)))
		proc.OutLeft <- s[0:halfLen]
		proc.OutRight <- s[halfLen:len(s)]
	}
}

// ======= LowerCaser =======

type lowerCaser struct {
	In  chan string
	Out chan string
}

func NewLowerCaser() *lowerCaser {
	return &lowerCaser{Out: make(chan string, BUFSIZE)}
}

func (proc *lowerCaser) Run() {
	defer close(proc.Out)
	for s := range proc.In {
		proc.Out <- strings.ToLower(s)
	}
}

// ======= UpperCaser =======

type upperCaser struct {
	In  chan string
	Out chan string
}

func NewUpperCaser() *upperCaser {
	return &upperCaser{Out: make(chan string, BUFSIZE)}
}

func (proc *upperCaser) Run() {
	defer close(proc.Out)
	for s := range proc.In {
		proc.Out <- strings.ToUpper(s)
	}
}

// ======= Merger =======

type zipper struct {
	In1 chan string
	In2 chan string
	Out chan string
}

func NewZipper() *zipper {
	return &zipper{Out: make(chan string, BUFSIZE)}
}

func (proc *zipper) Run() {
	defer close(proc.Out)
	for {
		s1, ok1 := <-proc.In1
		s2, ok2 := <-proc.In2
		if !ok1 && !ok2 {
			break
		}
		proc.Out <- fmt.Sprint(s1, s2)
	}
}

// ======= Printer =======

type printer struct {
	In chan string
}

func NewPrinter() *printer {
	return &printer{}
}

func (proc *printer) Run() {
	for s := range proc.In {
		fmt.Println(s)
	}
}
	package main

	import (
	"fmt"
	"math"
	"strings"
	)

	const (
	BUFSIZE = 16
	)

	// ======= Main =======

	func main() {
	// Init processes
	hisay := NewHiSayer()
	split := NewStringSplitter()
	lower := NewLowerCaser()
	upper := NewUpperCaser()
	zippr := NewZipper()
	prntr := NewPrinter()

	// Network definition * This is where to look! *
	split.In = hisay.Out
	lower.In = split.OutLeft
	upper.In = split.OutRight
	zippr.In1 = lower.Out
	zippr.In2 = upper.Out
	prntr.In = zippr.Out

	// Set up processes for running (spawn go-routines)
	go hisay.Run()
	go split.Run()
	go lower.Run()
	go upper.Run()
	go zippr.Run()
	prntr.Run()

	println("Finished program!")
	}

	// ======= HiSayer =======

	type hiSayer struct {
	Out chan string
	}

	func NewHiSayer() *hiSayer {
	return &hiSayer{Out: make(chan string, BUFSIZE)}
	}

	func (proc *hiSayer) Run() {
	defer close(proc.Out)
	for _, i := range []int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10} {
	proc.Out <- fmt.Sprintf("Hi for the %d:th time!", i)
	}
	}

	// ======= StringSplitter =======

	type stringSplitter struct {
	In chan string
	OutLeft chan string
	OutRight chan string
	}

	func NewStringSplitter() *stringSplitter {
	return &stringSplitter{
	OutLeft: make(chan string, BUFSIZE),
	OutRight: make(chan string, BUFSIZE),
	}
	}

	func (proc *stringSplitter) Run() {
	defer close(proc.OutLeft)
	defer close(proc.OutRight)
	for s := range proc.In {
	halfLen := int(math.Floor(float64(len(s)) / float64(2)))
	proc.OutLeft <- s[0:halfLen]
	proc.OutRight <- s[halfLen:len(s)]
	}
	}

	// ======= LowerCaser =======

	type lowerCaser struct {
	In chan string
	Out chan string
	}

	func NewLowerCaser() *lowerCaser {
	return &lowerCaser{Out: make(chan string, BUFSIZE)}
	}

	func (proc *lowerCaser) Run() {
	defer close(proc.Out)
	for s := range proc.In {
	proc.Out <- strings.ToLower(s)
	}
	}

	// ======= UpperCaser =======

	type upperCaser struct {
	In chan string
	Out chan string
	}

	func NewUpperCaser() *upperCaser {
	return &upperCaser{Out: make(chan string, BUFSIZE)}
	}

	func (proc *upperCaser) Run() {
	defer close(proc.Out)
	for s := range proc.In {
	proc.Out <- strings.ToUpper(s)
	}
	}

	// ======= Merger =======

	type zipper struct {
	In1 chan string
	In2 chan string
	Out chan string
	}

	func NewZipper() *zipper {
	return &zipper{Out: make(chan string, BUFSIZE)}
	}

	func (proc *zipper) Run() {
	defer close(proc.Out)
	for {
	s1, ok1 := <-proc.In1
	s2, ok2 := <-proc.In2
	if !ok1 && !ok2 {
	break
	}
	proc.Out <- fmt.Sprint(s1, s2)
	}
	}

	// ======= Printer =======

	type printer struct {
	In chan string
	}

	func NewPrinter() *printer {
	return &printer{}
	}

	func (proc *printer) Run() {
	for s := range proc.In {
	fmt.Println(s)
	}
	}