test/chan/sieve2.go - go - Git at Google

 // run

 // Copyright 2009 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Test concurrency primitives: prime sieve of Eratosthenes.

 // Generate primes up to 100 using channels, checking the results.
 // This sieve is Eratosthenesque and only considers odd candidates.
 // See discussion at <http://blog.onideas.ws/eratosthenes.go>.

 package main

 import (
 	"container/heap"
 	"container/ring"
 )

 // Return a chan of odd numbers, starting from 5.
 func odds() chan int {
 	out := make(chan int, 50)
 	go func() {
 		n := 5
 		for {
 			out <- n
 			n += 2
 		}
 	}()
 	return out
 }

 // Return a chan of odd multiples of the prime number p, starting from p*p.
 func multiples(p int) chan int {
 	out := make(chan int, 10)
 	go func() {
 		n := p * p
 		for {
 			out <- n
 			n += 2 * p
 		}
 	}()
 	return out
 }

 type PeekCh struct {
 	head int
 	ch   chan int
 }

 // Heap of PeekCh, sorting by head values, satisfies Heap interface.
 type PeekChHeap []*PeekCh

 func (h *PeekChHeap) Less(i, j int) bool {
 	return (*h)[i].head < (*h)[j].head
 }

 func (h *PeekChHeap) Swap(i, j int) {
 	(*h)[i], (*h)[j] = (*h)[j], (*h)[i]
 }

 func (h *PeekChHeap) Len() int {
 	return len(*h)
 }

 func (h *PeekChHeap) Pop() (v interface{}) {
 	*h, v = (*h)[:h.Len()-1], (*h)[h.Len()-1]
 	return
 }

 func (h *PeekChHeap) Push(v interface{}) {
 	*h = append(*h, v.(*PeekCh))
 }

 // Return a channel to serve as a sending proxy to 'out'.
 // Use a goroutine to receive values from 'out' and store them
 // in an expanding buffer, so that sending to 'out' never blocks.
 func sendproxy(out chan<- int) chan<- int {
 	proxy := make(chan int, 10)
 	go func() {
 		n := 16 // the allocated size of the circular queue
 		first := ring.New(n)
 		last := first
 		var c chan<- int
 		var e int
 		for {
 			c = out
 			if first == last {
 				// buffer empty: disable output
 				c = nil
 			} else {
 				e = first.Value.(int)
 			}
 			select {
 			case e = <-proxy:
 				last.Value = e
 				if last.Next() == first {
 					// buffer full: expand it
 					last.Link(ring.New(n))
 					n *= 2
 				}
 				last = last.Next()
 			case c <- e:
 				first = first.Next()
 			}
 		}
 	}()
 	return proxy
 }

 // Return a chan int of primes.
 func Sieve() chan int {
 	// The output values.
 	out := make(chan int, 10)
 	out <- 2
 	out <- 3

 	// The channel of all composites to be eliminated in increasing order.
 	composites := make(chan int, 50)

 	// The feedback loop.
 	primes := make(chan int, 10)
 	primes <- 3

 	// Merge channels of multiples of 'primes' into 'composites'.
 	go func() {
 		var h PeekChHeap
 		min := 15
 		for {
 			m := multiples(<-primes)
 			head := <-m
 			for min < head {
 				composites <- min
 				minchan := heap.Pop(&h).(*PeekCh)
 				min = minchan.head
 				minchan.head = <-minchan.ch
 				heap.Push(&h, minchan)
 			}
 			for min == head {
 				minchan := heap.Pop(&h).(*PeekCh)
 				min = minchan.head
 				minchan.head = <-minchan.ch
 				heap.Push(&h, minchan)
 			}
 			composites <- head
 			heap.Push(&h, &PeekCh{<-m, m})
 		}
 	}()

 	// Sieve out 'composites' from 'candidates'.
 	go func() {
 		// In order to generate the nth prime we only need multiples of
 		// primes ≤ sqrt(nth prime).  Thus, the merging goroutine will
 		// receive from 'primes' much slower than this goroutine
 		// will send to it, making the buffer accumulate and block this
 		// goroutine from sending, causing a deadlock.  The solution is to
 		// use a proxy goroutine to do automatic buffering.
 		primes := sendproxy(primes)

 		candidates := odds()
 		p := <-candidates

 		for {
 			c := <-composites
 			for p < c {
 				primes <- p
 				out <- p
 				p = <-candidates
 			}
 			if p == c {
 				p = <-candidates
 			}
 		}
 	}()

 	return out
 }

 func main() {
 	primes := Sieve()
 	a := []int{2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97}
 	for i := 0; i < len(a); i++ {
 		if x := <-primes; x != a[i] {
 			println(x, " != ", a[i])
 			panic("fail")
 		}
 	}
 }
	// run

	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Test concurrency primitives: prime sieve of Eratosthenes.

	// Generate primes up to 100 using channels, checking the results.
	// This sieve is Eratosthenesque and only considers odd candidates.
	// See discussion at <http://blog.onideas.ws/eratosthenes.go>.

	package main

	import (
	"container/heap"
	"container/ring"
	)

	// Return a chan of odd numbers, starting from 5.
	func odds() chan int {
	out := make(chan int, 50)
	go func() {
	n := 5
	for {
	out <- n
	n += 2
	}
	}()
	return out
	}

	// Return a chan of odd multiples of the prime number p, starting from p*p.
	func multiples(p int) chan int {
	out := make(chan int, 10)
	go func() {
	n := p * p
	for {
	out <- n
	n += 2 * p
	}
	}()
	return out
	}

	type PeekCh struct {
	head int
	ch chan int
	}

	// Heap of PeekCh, sorting by head values, satisfies Heap interface.
	type PeekChHeap []*PeekCh

	func (h *PeekChHeap) Less(i, j int) bool {
	return (h)[i].head < (h)[j].head
	}

	func (h *PeekChHeap) Swap(i, j int) {
	(h)[i], (h)[j] = (h)[j], (h)[i]
	}

	func (h *PeekChHeap) Len() int {
	return len(*h)
	}

	func (h *PeekChHeap) Pop() (v interface{}) {
	h, v = (h)[:h.Len()-1], (*h)[h.Len()-1]
	return
	}

	func (h *PeekChHeap) Push(v interface{}) {
	h = append(h, v.(*PeekCh))
	}

	// Return a channel to serve as a sending proxy to 'out'.
	// Use a goroutine to receive values from 'out' and store them
	// in an expanding buffer, so that sending to 'out' never blocks.
	func sendproxy(out chan<- int) chan<- int {
	proxy := make(chan int, 10)
	go func() {
	n := 16 // the allocated size of the circular queue
	first := ring.New(n)
	last := first
	var c chan<- int
	var e int
	for {
	c = out
	if first == last {
	// buffer empty: disable output
	c = nil
	} else {
	e = first.Value.(int)
	}
	select {
	case e = <-proxy:
	last.Value = e
	if last.Next() == first {
	// buffer full: expand it
	last.Link(ring.New(n))
	n *= 2
	}
	last = last.Next()
	case c <- e:
	first = first.Next()
	}
	}
	}()
	return proxy
	}

	// Return a chan int of primes.
	func Sieve() chan int {
	// The output values.
	out := make(chan int, 10)
	out <- 2
	out <- 3

	// The channel of all composites to be eliminated in increasing order.
	composites := make(chan int, 50)

	// The feedback loop.
	primes := make(chan int, 10)
	primes <- 3

	// Merge channels of multiples of 'primes' into 'composites'.
	go func() {
	var h PeekChHeap
	min := 15
	for {
	m := multiples(<-primes)
	head := <-m
	for min < head {
	composites <- min
	minchan := heap.Pop(&h).(*PeekCh)
	min = minchan.head
	minchan.head = <-minchan.ch
	heap.Push(&h, minchan)
	}
	for min == head {
	minchan := heap.Pop(&h).(*PeekCh)
	min = minchan.head
	minchan.head = <-minchan.ch
	heap.Push(&h, minchan)
	}
	composites <- head
	heap.Push(&h, &PeekCh{<-m, m})
	}
	}()

	// Sieve out 'composites' from 'candidates'.
	go func() {
	// In order to generate the nth prime we only need multiples of
	// primes ≤ sqrt(nth prime). Thus, the merging goroutine will
	// receive from 'primes' much slower than this goroutine
	// will send to it, making the buffer accumulate and block this
	// goroutine from sending, causing a deadlock. The solution is to
	// use a proxy goroutine to do automatic buffering.
	primes := sendproxy(primes)

	candidates := odds()
	p := <-candidates

	for {
	c := <-composites
	for p < c {
	primes <- p
	out <- p
	p = <-candidates
	}
	if p == c {
	p = <-candidates
	}
	}
	}()

	return out
	}

	func main() {
	primes := Sieve()
	a := []int{2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83, 89, 97}
	for i := 0; i < len(a); i++ {
	if x := <-primes; x != a[i] {
	println(x, " != ", a[i])
	panic("fail")
	}
	}
	}