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Exercise 1: Basic Methods
Define the type dog as follows:
type dog struct {
name string
race string
female bool
}
Write a method that will rename a dog which can be used as follows:
func main() {
fido := dog {"Fido", "Poodle", false }
fido.rename("Cocotte")
}
Exercise 2: Go Channel Basics
Test what will be printed by the following
package main
import (
"fmt"
"time"
"strconv"
)
var i int
func makeCakeAndSend(cs chan string) {
i = i + 1
cakeName := "Strawberry Cake " + strconv.Itoa(i)
fmt.Println("Making a cake and sending ...", cakeName)
cs <- cakeName //send a strawberry cake
}
func receiveCakeAndPack(cs chan string) {
s := <-cs //get whatever cake is on the channel
fmt.Println("Packing received cake: ", s)
}
func main() {
cs := make(chan string)
for i := 0; i<3; i++ {
go makeCakeAndSend(cs)
go receiveCakeAndPack(cs)
//sleep for a while so that the program doesn't exit
//immediately and output is clear for illustration
time.Sleep(1 * 1e9)
}
}
Exercise 3:
The following program is to be changed such that it uses arbitrary sized slices instead of fixed size arrays. In particular, the user entered size (variable sz) is to replace the hard-coded 32 in main and any function changed correspondingly.
package main
import "fmt"
import "math"
import "math/rand"
type Series struct {
a, b float64
}
func (s Series) add(t, TP int) float64 {
return s.a*math.Sin(2.0*math.Pi*float64(t)/float64(TP)) + s.b*math.Cos(2.0*math.Pi*float64(t)/float64(TP))
}
func fourier(c [32]Series, t, TP int) (res float64) {
res = c[0].a
for n := 1; n < 32; n++ {
res += c[n].add(t, TP)
}
return
}
func main() {
TP := 4
sz := 1
var res float64
// Enter size of fourier series
fmt.Print("Size of series (1 ... 512): ")
// Depending on your environment you may have to remove \n in the scanf
_, err := fmt.Scanf("%d \n", &sz)
for err != nil || sz < 1 || sz 512 {
fmt.Println("Must be positive integer (1...512).")
fmt.Println("Size of series (1 ... 512): ")
_, err = fmt.Scanf("%d \n", &sz)
}
fmt.Printf("Size: %d\n", sz)
var c [32]Series
for t := 0; t < TP; t++ {
for k := 0; k < 32; k++ {
c[k].a = rand.Float64()
c[k].b = rand.Float64()
}
res += fourier(c, t, TP)
fmt.Printf("%f ", res)
fmt.Println()
}
}
Exercise 4 and Quiz: Semaphore
.While go has laguage level support for CSP style concurrency, a resource guided by a semaphore can be easily implemented. The program below uses two go routines to access a variable, one routine counting up and one counting down. Each runs a loop and accesses the variable the same number of times. Naively, the variable should be the same as in the beginning. This is not the case. Use a global semaphore (the variable sema below) to signal the use of the variable Count by the functions increment and decrement.
package main
import (
"fmt"
"time"
)
var (
Count int = 0
nFunctions int = 2
)
var sema = make(chan int)
func main() {
ch := make(chan int)
fmt.Printf("Count = %d\n", Count)
go increment(ch, 1000)
go decrement(ch, 1000)
for i := 0; i < nFunctions*1000; i++ {
fmt.Printf("Waiting %d\n", Count )
<-ch
}
fmt.Printf("Count = %d\n", Count)
}
func increment(ch chan int, nSteps int) {
for i := 0; i < nSteps; i++ {
cnt := Count
time.Sleep(3 * time.Millisecond)
Count = cnt + 1
ch <- 1
}
return
}
func decrement(ch chan int, nSteps int) {
for i := 0; i < nSteps; i++ {
cnt := Count
time.Sleep(2 * time.Millisecond)
Count = cnt - 1
ch <- 1
}
return
}