An introduction to functional programming with go

1. AN INTRODUCTION TO FUNCTIONAL PROGRAMMING IN GO ELEANOR MCHUGH

2. ELEANOR MCHUGH @feyeleanor APPLIED PHYSICIST MISAPPLIED HACKER EMBEDDED SYSTEMS VIRTUAL MACHINES DIGITAL IDENTITY RUBY GO

3. LEANPUB://GONOTEBOOK A GO DEVELOPER'S NOTEBOOK ▸ teaches Go by exploring code ▸ free tutorial on secure networking ▸ opinionated but not prescriptive ▸ based on a decade of experience ▸ buy once & get all future updates ▸ very irregular update cycle ▸ the only book I'll ever write on Go

4. LEANPUB://GONOTEBOOK

5. IMPERATIVE PROGRAMMING

6. A SIMPLE TASK 0: 0 1: 2 2: 4 3: 6 4: 8

7. IMPERATIVE PROGRAMMING THE CONDITIONAL LOOP

8. THE CONDITIONAL LOOP package main import "fmt" func main() { s := []int{0, 2, 4, 6, 8} for i := 0; i < len(s); i++ { fmt.Printf("%v: %vn", i, s[i]) } }

11. THE CONDITIONAL LOOP package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} for i := 0; i < len(s); i++ { Printf("%v: %vn", i, s[i]) } }

25. IMPERATIVE PROGRAMMING AN EXCEPTIONAL LOOP

26. AN EXCEPTIONAL LOOP package main import . "fmt" func main() { defer func() { recover() }() s := []int{0, 2, 4, 6, 8} i := 0 for { Printf("%v: %vn", i, s[i]) i++ } }

32. AN EXCEPTIONAL LOOP package main import . "fmt" func main() { defer func() { recover() }() s := []int{0, 2, 4, 6, 8} i := 0 for i := 0; ; i++ { Printf("%v: %vn", i, s[i]) i++ } }

33. IMPERATIVE PROGRAMMING ENUMERABLE RANGES

34. ENUMERABLE RANGES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} for i, v := range s { Printf("%v: %vn", i, v) } }

40. PROGRAMMINGWITH FUNCTIONS

41. PROGRAMMINGWITH FUNCTIONS ENUMERATION BY FUNCTION

42. ENUMERATION BY FUNCTION package main import . "fmt" func main() { print_slice([]int{0, 2, 4, 6, 8}) } func print_slice(s []int) { for i, v := range s { Printf("%v: %vn", i, v) } }

46. ENUMERATION BY FUNCTION package main import . "fmt" func main() { print_slice(0, 2, 4, 6, 8) } func print_slice(s ...int) { for i, v := range s { Printf("%v: %vn", i, v) } }

47. PROGRAMMINGWITH FUNCTIONS TYPE ABSTRACTION

48. ABSTRACTING TYPE package main import . "fmt" func main() { print_slice([]int{0, 2, 4, 6, 8}) } func print_slice(s interface{}) { for i, v := range s.([]int) { Printf("%v: %vn", i, v) } }

51. ABSTRACTING TYPE package main import . "fmt" func main() { print_slice([]int{0, 2, 4, 6, 8}) } func print_slice(s interface{}) { if s, ok := s.([]int); ok { for i, v := range s { Printf("%v: %vn", i, v) } } }

55. ABSTRACTING TYPE package main import . "fmt" func main() { print_slice([]int{0, 2, 4, 6, 8}) } func print_slice(s interface{}) { switch s := s.(type) { case []int: for i, v := range s { Printf("%v: %vn", i, v) } } }

58. PROGRAMMINGWITH FUNCTIONS FUNCTIONS AS VALUES

59. FUNCTIONS AS VALUES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_slice(s, element) } func element(s []int, i int) int { return s[i] } func print_slice(s []int, f func([]int, int) int { defer func() { recover() }() for i := 0; ; i++ { Printf("%v: %vn", i, f(i)) } }

60. FUNCTIONS AS VALUES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_slice(s, element) } func element(s []int, i int) int { return s[i] } func print_slice(s []int, f func([]int, int) int { defer func() { recover() }() for i := 0; ; i++ { Printf("%v: %vn", i, f(i)) } }

61. FUNCTIONS AS VALUES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_slice(s, element) } func element(s []int, i int) int { return s[i] } func print_slice(s []int, f func([]int, int) int) { defer func() { recover() }() for i := 0; ; i++ { Printf("%v: %vn", i, f(s, i)) } }

65. FUNCTIONS AS VALUES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_slice(s, func(s []int, i int) int { return s[i] }) } func print_slice(s []int, f func([]int, int) int) { defer func() { recover() }() for i := 0; ; i++ { Printf("%v: %vn", i, f(s, i)) } }

66. PROGRAMMINGWITH FUNCTIONS CLOSURES

67. CLOSURES package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_slice(func(i int) int { return s[i] }) } func print_slice(s interface{}) { switch s := s.(type) { case func(int) int: for i := 0; i < 5; i++ { Printf("%v: %vn", i, s(i)) } } }

75. PROGRAMMINGWITH FUNCTIONS CONCURRENCY

76. CONCURRENCY package main import . "fmt" func main() { c := make(chan int) go func() { for i := 0; i++; i < 5 { c <- i * 2 } close(c) }() print_channel(c) } func print_channel(c chan int) (i int) { for v := range c { Printf("%v: %vn", i, v) i++ } return }

78. CONCURRENCY package main import . "fmt" func main() { c := make(chan int, 16) go func() { for i := 0; i++; i < 5 { c <- i * 2 } close(c) }() print_channel(c) } func print_channel(c chan int) (i int) { for v := range c { Printf("%v: %vn", i, v) i++ } return }

83. CONCURRENCY package main import . "fmt" func main() { c := make(chan int) go func() { for _, v := range []int{0, 2, 4, 6, 8} { c <- v } close(c) }() print_channel(c) } func print_channel(c chan int) (i int) { for v := range c { Printf("%v: %vn", i, v) i++ } return }

87. PROGRAMMINGWITH FUNCTIONS INFINITE SEQUENCES

88. INFINITE SEQUENCES package main import . "fmt" func main() { c := make(chan int) go sequence(c) print_channel(c) } func sequence(c chan int) { for i := 0; ; i++ { c <- i * 2 } } func print_channel(c chan int) { for i := 0; i < 5; i++ { Printf("%v: %vn", i, <- c) } return }

93. PROGRAMMINGWITH FUNCTIONS WORKING WITH KINDS

94. WORKING WITH KINDS package main import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { switch s := s.(type) { case func(int) int: for i := 0; i < 5; i++ { Printf("%v: %vn", i, s(i)) } case []int: for i, v := range s { Printf("%v: %vn", i, v) } } }

98. WORKING WITH KINDS package main import "reflect" import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { switch s := reflect.ValueOf(s); s.Kind() { case reflect.Func: for i := 0; i < 5; i++ { p := []reflect.Value{ reflect.ValueOf(i) } Printf("%v: %vn", i, s.Call(p)[0].Interface()) } case reflect.Slice: for i := 0; i < s.Len(); i++ { Printf("%v: %vn", i, s.Index(i).Interface()) } } }

102. WORKING WITH KINDS package main import . "reflect" import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { switch s := ValueOf(s); s.Kind() { case Func: for i := 0; i < 5; i++ { p := []Value{ ValueOf(i) } Printf("%v: %vn", i, s.Call(p)[0].Interface()) } case Slice: for i := 0; i < s.Len(); i++ { Printf("%v: %vn", i, s.Index(i).Interface()) } } }

105. WORKING WITH KINDS package main import . "reflect" import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { defer func() { recover() } switch s := ValueOf(s); s.Kind() { case Func: for i := 0; ; i++ { p := []Value{ ValueOf(i) } Printf("%v: %vn", i, s.Call(p)[0].Interface()) } case Slice: for i := 0; ; i++ { Printf("%v: %vn", i, s.Index(i).Interface()) } } }

106. WORKING WITH KINDS package main import . "reflect" import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { switch s := ValueOf(s); s.Kind() { case Func: for_each(func(i int) { p := []Value{ ValueOf(i) } Printf("%v: %vn", i, s.Call(p)[0].Interface()) }) case Slice: for_each(func(i int) { Printf("%v: %vn", i, s.Index(i).Interface()) }) } } func for_each(f func(int)) (i int) { defer func() { recover() } for ; ; i++ { f(i) } }

107. WORKING WITH KINDS package main import . "reflect" import . "fmt" func main() { s := []int{0, 2, 4, 6, 8} print_values(s) print_values(func(i int) int { return s[i] }) } func print_values(s interface{}) { switch s := ValueOf(s); s.Kind() { case Func: p := make([]Value, 1) for_each(func(i int) { p[0] = ValueOf(i) Printf("%v: %vn", i, s.Call(p)[0].Interface()) }) case Slice: for_each(func(i int) { Printf("%v: %vn", i, s.Index(i).Interface()) }) } } func for_each(f func(int)) (i int) { defer func() { recover() } for ; ; i++ { f(i) } }

108. PROGRAMMINGWITH OBJECTS

109. PROGRAMMINGWITH OBJECTS TYPES + METHODS = OBJECTS

110. TYPES + METHODS = OBJECTS package main import . "fmt" func main() { s := IterableSlice{ 0, 2, 4, 6, 8 } i := 0 s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) } type IterableSlice []int func (i IterableSlice) Each(f func(interface{})) { for _, v := range i { f(v) } }

115. PROGRAMMINGWITH OBJECTS INTERFACES = POLYMORPHISM

116. INTERFACES = POLYMORPHISM package main import . "fmt" func main() { var s Iterable = IterableSlice{ 0, 2, 4, 6, 8 } i := 0 s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) } type Iterable interface { Each(func(interface{})) } type IterableSlice []int func (i IterableSlice) Each(f func(interface{})) { for _, v := range i { f(v) } }

119. INTERFACES = POLYMORPHISM package main import . "fmt" func main() { print_values(IterableLimit(5)) print_values(IterableSlice{ 0, 2, 4, 6, 8 }) } func print_values(s Iterable) (i int) { s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) return i } type Iterable interface { Each(func(interface{})) } type IterableLimit int type IterableSlice []int func (i IterableLimit) Each(f func(interface{})) { for v := IterableLimit(0); v < i; v++ { f(v) } } func (i IterableSlice) Each(f func(interface{})) { for _, v := range i { f(v) } }

123. PROGRAMMINGWITH OBJECTS IMMUTABILITY IS A CHOICE

124. IMMUTABILITY IS A CHOICE package main import . "fmt" func main() { s := IterableRange{ 0, 2, 5 } print_values(s) print_values(s) } func print_values(s Iterable) (i int) { s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) return i } type Iterable interface { Each(func(interface{})) } type IterableRange struct { start int step int limit int } func (r IterableRange) Each(f func(interface{})) { for; r.limit > 0; r.limit-- { f(r.start) r.start += r.step } }

128. IMMUTABILITY IS A CHOICE package main import . "fmt" func main() { s := &IterableRange{ 0, 2, 5 } print_values(s) print_values(s) } func print_values(s Iterable) (i int) { s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) return i } type Iterable interface { Each(func(interface{})) } type IterableRange struct { start int step int limit int } func (r IterableRange) Each(f func(interface{})) { for; r.limit > 0; r.limit-- { f(r.start) r.start += r.step } }

129. IMMUTABILITY IS A CHOICE package main import . "fmt" func main() { s := &IterableRange{ 0, 2, 5 } print_values(s) print_values(s) } func print_values(s Iterable) (i int) { s.Each(func(v interface{}) { Printf("%v: %vn", i, v) i++ }) return i } type Iterable interface { Each(func(interface{})) } type IterableRange struct { start int step int limit int } func (r *IterableRange) Each(f func(interface{})) { for; r.limit > 0; r.limit-- { f(r.start) r.start += r.step } }

130. OO makes code understandable by encapsulating moving parts. FP makes code understandable by minimizing moving parts. Michael Feathers @mfeathers LEANPUB://GONOTEBOOK

131. FUNCTIONSAS PARADIGM

132. FUNCTIONSAS PARADIGM A PURE FUNCTION

133. A PURE FUNCTION package main import "os" func main() { os.Exit(add(3, 4)) } func add(x, y int) int { return x + y }

134. A PURE FUNCTION package main import "os" func main() { os.Exit(add(3, 4)) } func add(x, y int) int { return x + y }

135. A PURE FUNCTION package main import "os" func main() { os.Exit(add(3, 4)) } func add(x int, y int) int { return x + y }

138. A PURE FUNCTION package main import "os" import "strconv" func main() { x, _ := strconv.Atoi(os.Args[1]) y, _ := strconv.Atoi(os.Args[2]) os.Exit(add(x, y)) } func add(x, y int) int { return x + y }

141. A PURE FUNCTION package main import "os" import "strconv" func main() { os.Exit(add(arg(0), arg(1))) } func arg(n int) (r int) { r, _ = strconv.Atoi(os.Args[n + 1]) return } func add(x, y int) int { return x + y }

142. A PURE FUNCTION package main import "os" import "strconv" func main() { var sum int for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) sum = add(sum, x) } os.Exit(sum) } func add(x, y int) int { return x + y }

143. A PURE FUNCTION package main import "os" import "strconv" func main() { var sum int for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) sum = add(sum, x) } os.Exit(sum) } func add(x, y int) int { return x + y }

144. FUNCTIONSAS PARADIGM BEING IMPURE

145. BEING IMPURE package main import "os" import "strconv" func main() { for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) accumulate(x) } os.Exit(y) } var y int func accumulate(x int) { y += x }

149. BEING IMPURE package main import "os" import "strconv" func main() { for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a.Add(x) } os.Exit(int(a)) } var a Accumulator type Accumulator int func (a *Accumulator) Add(y int) { *a += Accumulator(y) }

152. BEING IMPURE package main import "os" import "strconv" func main() { for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a.Add(x) } os.Exit(int(a)) } var a Accumulator type Accumulator int func (a Accumulator) Add(y int) { a += Accumulator(y) }

153. FUNCTIONSAS PARADIGM FUNCTIONS WITH MEMORY

154. FUNCTIONS WITH MEMORY package main import "os" import "strconv" func main() { for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a(0)) } var a = MakeAccumulator() func MakeAccumulator() func(int) int { var y int return func(x int) int { y += x return y } }

159. FUNCTIONS WITH MEMORY package main import "os" import "strconv" func main() { for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a(0)) } var a = MakeAccumulator() type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } }

160. FUNCTIONS WITH MEMORY package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a(0)) } type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } }

161. FUNCTIONS WITH MEMORY package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a(0)) } func MakeAccumulator() func(int) int { var y int return func(x int) int { y += x return y } }

162. FUNCTIONSAS PARADIGM FUNCTIONS AS OBJECTS

163. FUNCTIONS AS OBJECTS package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a.Int()) } type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } } func (a Accumulator) Int() int { return a(0) }

164. FUNCTIONS AS OBJECTS package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a(x) } os.Exit(a.Int()) } type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } } func (a Accumulator) Int() int { return a(0) }

165. FUNCTIONS AS OBJECTS package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a.Add(x) } os.Exit(a.Int()) } type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } } func (a Accumulator) Int() int { return a(0) } func (a Accumulator) Add(x interface{}) { switch x := x.(type) { case int: a(x) case Accumulator: a(x.Value()) } }

166. FUNCTIONS AS OBJECTS package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a.Add(MakeAccumulator()(x)) } os.Exit(a.Int()) } type Accumulator func(int) int func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } } func (a Accumulator) Int() int { return a(0) } func (a Accumulator) Add(x interface{}) { switch x := x.(type) { case int: a(x) case Accumulator: a(x.Value()) } }

167. FUNCTIONS AS OBJECTS package main import "os" import "strconv" func main() { a := MakeAccumulator() for _, v := range os.Args[1:] { x, _ := strconv.Atoi(v) a.Add(MakeAccumulator()(x)) } os.Exit(a.Int()) } type Accumulator func(int) int type Integer interface { Int() int } func MakeAccumulator() Accumulator { var y int return func(x int) int { y += x return y } } func (a Accumulator) Int() int { return a(0) } func (a Accumulator) Add(x interface{}) { switch x := x.(type) { case int: a(x) case Integer: a(x.Int()) } }

168. FUNCTIONSIN MATHEMATICS

169. COMPUTING FACTORIALS

170. COMPUTING FACTORIALS 0! = 1 1! = 1 2! = 2 3! = 6 4! = 24 5! = 120 6! = 720 7! = 5040 8! = 40320 9! = 362880

171. FUNCTIONSIN MATHEMATICS ITERATING FACTORIALS

172. ITERATING FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = 1 for ; n > 0; n-- { r *= n } } return }

178. ITERATING FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) int { r := 1 switch { case n < 0: panic(n) case n > 0: for ; n > 0; n-- { r *= n } } return r }

179. ITERATING FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

180. ITERATING FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

181. FUNCTIONSIN MATHEMATICS MULTIPLE FACTORIALS

182. MULTIPLE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() for _, v := range os.Args[1:] { if x, e := strconv.Atoi(v); e != nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

183. MULTIPLE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() for _, v := range os.Args[1:] { if x, e := strconv.Atoi(v); e != nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

184. MULTIPLE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() for _, v := range os.Args[1:] { if x, e := strconv.Atoi(v); e == nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

188. MULTIPLE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { defer func() { if x := recover(); x != nil { Println("no factorial") } }() if x, e := strconv.Atoi(v); e == nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

189. FUNCTIONSIN MATHEMATICS HIGHER ORDER FUNCTIONS

190. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { func() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() if x, e := strconv.Atoi(v); e == nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } }() } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

194. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { SafeExecute(func(i int) { Printf("%v!: %vn", i, Factorial(i)) })(v) } } func SafeExecute(f func(int)) func(string) { return func(v string) { defer func() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } }() if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

198. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { var errors int f := func(i int) { Printf("%v!: %vn", i, Factorial(i)) } for _, v := range os.Args[1:] { if !SafeExecute(f)(v) { errors++ } } os.Exit(errors) } func SafeExecute(f func(int)) func(string) bool { return func(v string) (r bool) { defer func() { if x := recover(); x != nil { Printf("no defined value for %vn", x) s} }() if x, e := strconv.Atoi(v); e == nil { f(x) r = true } else { panic(v) } return } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

199. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { var errors int f := func(i int) { Printf("%v!: %vn", i, Factorial(i)) } for _, v := range os.Args[1:] { if !SafeExecute(f)(v) { errors++ } } os.Exit(errors) } func SafeExecute(f func(int)) func(string) bool { return func(v string) (r bool) { defer func() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } }() if x, e := strconv.Atoi(v); e == nil { f(x) r = true } else { panic(v) } return } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

202. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { var errors int for _, v := range os.Args[1:] { SafeExecute( func(i int) { Printf("%v!: %vn", i, Factorial(i)) }, func() { if x := recover(); x != nil { Printf("no defined value for %vn", x) errors++ } }, )(v) } os.Exit(errors) } func SafeExecute(f func(int), e func()) func(string) { return func(v string) { defer e() if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

203. HIGHER ORDER FUNCTIONS package main import . "fmt" import "os" import "strconv" func main() { var errors int for _, v := range os.Args[1:] { SafeExecute( func(i int) { Printf("%v!: %vn", i, Factorial(i)) }, func() { if x := recover(); x != nil { Printf("no defined value for %vn", x) errors++ } }, )(v) } os.Exit(errors) } func SafeExecute(f func(int), e func()) func(string) { return func(v string) { defer e() if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

204. FUNCTIONSIN MATHEMATICS CURRYING

205. CURRYING

206. CURRYING package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { OnPanicFor(UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) }), PrintErrorMessage) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanicFor(f, e func()) { defer e() f() } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

210. CURRYING package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { OnPanicFor(UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) }), PrintErrorMessage)() } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanicFor(f, e func()) func() { return func() { defer e() f() } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

211. CURRYING package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { OnPanicFor(UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) }), PrintErrorMessage)() } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanicFor(f, e func()) func() { return func() { defer e() f() } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

212. CURRYING package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

215. CURRYING package main import . "fmt" import "os" import "strconv" func main() { p := OnPanic(PrintErrorMessage) for _, v := range os.Args[1:] { p(UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { if n < 0 { panic(n) } for r = 1; n > 0; n-- { r *= n } return }

216. FUNCTIONSIN MATHEMATICS RECURSION

217. RECURSION package main func main() { main() }

220. RECURSION package main func main() { defer func() { recover() } main() }

221. RECURSION package main import "os" import"strconv" var limit int func init() { if x, e := strconv.Atoi(os.Args[1]); e == nil { limit = x } } func main() { limit-- if limit > 0 { main() } }

225. FUNCTIONSIN MATHEMATICS RECURSIVE FACTORIALS

226. RECURSIVE FACTORIALS

230. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = 1 for ; n > 0; n-- { r *= n } } return }

233. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() x, _ := strconv.Atoi(os.Args[1]) Printf("%v!: %vn", x, Factorial(x)) } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } return }

234. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { defer func() { if x := recover(); x != nil { Println("no factorial") } }() for _, v := range os.Args[1:] { if x, e := strconv.Atoi(v); e != nil { Printf("%v!: %vn", x, Factorial(x)) } else { panic(v) } } } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } return }

235. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { for _, v := range os.Args[1:] { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } return }

236. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) }) } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func Each(s []string, f func(string)) { for _, v := range s { f(v) } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } return }

239. RECURSIVE FACTORIALS package main import . "fmt" import "os" import "strconv" func main() { Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) }) } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func Each(s []string, f func(string)) { if len(s) > 0 { f(s[0]) Each(s[1:], f) } } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func Factorial(n int) (r int) { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } return }

243. FUNCTIONSIN MATHEMATICS CACHING RESULTS

244. CACHING RESULTS package main import . "fmt" import "os" import "strconv" func main() { Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, Factorial(i)) })) }) } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Each(s []string, f func(string)) { if len(s) > 0 { f(s[0]) Each(s[1:], f) } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } var cache map[int] int = make(map[int] int) func Factorial(n int) (r int) { if r = cache[n]; r == 0 { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * Factorial(n - 1) } cache[n] = r } return }

249. CACHING RESULTS package main import . "fmt" import "os" import "strconv" func main() { c := make(Cache) Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, c.Factorial(i)) })) }) } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Each(s []string, f func(string)) { if len(s) > 0 { f(s[0]) Each(s[1:], f) } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } type Cache map[int] int func (c Cache) Factorial(n int) (r int) { if r = c[n]; r == 0 { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * c.Factorial(n - 1) } c[n] = r } return }

250. CACHING RESULTS package main import . "fmt" import "os" import "strconv" func main() { c := make(Cache) Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, c.Factorial(i)) })) }) } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Each(s []string, f func(string)) { if len(s) > 0 { f(s[0]) Each(s[1:], f) } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } type Cache map[int] int func (c Cache) Factorial(n int) (r int) { if r = c[n]; r == 0 { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * c.Factorial(n - 1) } c[n] = r } return }

251. CACHING RESULTS package main import . "fmt" import "os" import "strconv" func main() { f := MakeFactorial() Each(os.Args[1:], func(v string) { OnPanic(PrintErrorMessage)( UseNumericParam(v, func(i int) { Printf("%v!: %vn", i, f(i)) })) }) } func PrintErrorMessage() { if x := recover(); x != nil { Printf("no defined value for %vn", x) } } func UseNumericParam(v string, f func(i int)) func() { return func() { if x, e := strconv.Atoi(v); e == nil { f(x) } else { panic(v) } } } func Each(s []string, f func(string)) { if len(s) > 0 { f(s[0]) Each(s[1:], f) } } func OnPanic(e func()) func(func()) { return func(f func()) { defer e() f() } } func MakeFactorial() (f func(int) int) { c := make(map[int] int) return func(n int) (r int) { if r = c[n]; r == 0 { switch { case n < 0: panic(n) case n == 0: r = 1 default: r = n * f(n - 1) } c[n] = r } return } }

An introduction to functional programming with go

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