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Pig to Scalding

julienledem edited this page Dec 4, 2014 · 7 revisions

Pig to Scalding

This pages intends to help Pig users to learn Scalding by listing corresponding statements and basic Scala knowledge. You should also take a look at the tutorial.

LOAD

Pig:

A = LOAD 'foo'

Scalding:

// The TextLine source splits the input by lines.
val textSource = TextLine(args("input"))
// Create a type-safe pipe from the TextLine.
val lines: TypedPipe[String] = TypedPipe.from[String](textSource) 

STORE

Pig:

STORE B INTO 'bar'

Scalding:

b.write(TypedTsv[String](args("output")))

FOREACH

Pig:

B = FOREACH A GENERATE /* expression */

Scalding:

val b = a.map((t) => /* expression */)

FILTER

Pig:

B = FILTER A BY foo == 0

Scalding:

a.filter{ case (foo, bar) => foo == 0 } // using pattern matching to name elements of a tuple
// if you don't need to name an element you can use the _ wildcard instead
a.filter{ case (foo, _) => foo == 0 }

FOREACH A GENERATE FLATTEN(...)

in Scalding the use of flatMap is similar to the following in Pig:

B = FOREACH A GENERATE FLATTEN(Tokenize(text))

in Scalding:

def tokenize(s: String) = s.split(" ").toList
b = a.flatMap(tokenize(_))
// which produces the same result as:
b = a.map(tokenize(_)).flatten()
// and the same as 
b = a.map(tokenize(_)).flatten // empty parens are usually omitted

Aggregating

Pig:

B = FOREACH (GROUP A BY $0) GENERATE COUNT(A)

Scalding:

val b = a.groupBy(_._1).size 

notice the _ shorthand used here.

Join

Pig:

C = JOIN A BY $0, B BY $0

Scalding: assuming a and b are both a Pipe[(K,V)], you can join them as follows

val c = a.join(b)

Scala cheat sheet:

It is recommended to know the basics of Scala when trying out Scalding. Here are some common things Scala noobs may become confused about coming from Java and Pig.

Primitive types:

Scala uses the java primitive type names but with the first letter capitalized. (Scala uses the boxed type automatically when needed.) ex: Java:

final int a = 1

Scala:

val a = 1  // (val means it's a constant. Type is inferred. use var for variables)
val a: Int = 1 // same thing with explicit type declaration

Functions

def f(x:Int) = x * 2 // return type inferred

def f(x:Int): Int = x * 2 // same thing with explicit return type

Common types:

case classes

Immutable data class that can be used in pattern matching ex:

case class User(val firstname: String, val lastname: String)

kind of similar to the following in Java plus the added benefit of pattern matching:

final class User {
   public final String firstname; // those are immutable so it's fine to make them public
   public final String lastname;
   public User(String firstname,String lastname) {
     this.firstname = firstname;
     this.lastname = lastname;
  }
}

Tuples

fixed size with type assigned to each field ex:

val t = (1, "foo") // the type of t is Tuple2[Int, String]
t._1 // => 1
t._2 // => "foo"

assigning the members of t to a and b:

val (a, b) = t 
a // => 1
b // => 2

it is the same as:

val a = t._1
val b = t._2

it is not the same as:

val a, b = t
// which is:
val a = t
val b = t

pattern matching:

example:

t match {
  case (a, b) => a
}

Which translate to: if t is a Tuple2, assign t._1 to a and t._2 to b and return a You don't need to name things you don't use. The _ wildcard can be used:

t match {
  case (a, _) => a
}

similarly with case classes:

val u = User("Jack", "Jackson") // This is the same as User.apply("Jack", "Jackson"). Not a constructor  call
var v = u match {
  case User(firstname, lastname) => firstname
  ... // other cases
}

More advanced pattern matching

case class Name(first: String, middle:String, last:String)
case class Address(street: String, zip: String, city: String)
case class Person(name:Name, age: Int, address: Address)
val p = Person(Name("Bob", "E.", "Roberts"), 42, Address("23 colorado st.", "99999", "Las Vegas"))
// unwrap Person
p match  { case Person(a,b,c) => (a,b,c) }
// unwrap Person and Name
p match  { case Person(Name(f,m,l), b, c) => (f, m, l, b, c) }
// multiple case statements (anonymizing minors not in the "Roberts" familly)
p match  { 
  case Person(Name(first, _,"Roberts"), _, _) => first // matches only when lastname in Name is "Roberts"
  case Person(Name(first, _, _), age, _) if (age > 21) => first // predicate can be applied as well
  case _ => "anonymous" // default case if none of the above applies 
}
// just extracting age
p match  { case Person(_, age, _) => age }
// this one could be
p.age
// flattening the entire structure
p match  { case Person(Name(f,m,l), age, Address(street, zip, city)) => (f, m, l, age, street, zip, city) }

Typed pipes basics

map

If we have the following p1 of typed Pipe[T] f of type Function1[T,U] then

val p2 = p1.map(f)

p2 is of type Pipe[U]

lambda syntax

When defining a function inline we use the following syntax:

(param1, param2, ...) => /* expression */

which can be used in map

p.map( (a) => a + 1 )

Here we are defining a function that takes one parameter named a and apply it to all elements of p

map variations

with p1 of type Pipe[(Int, String)] (a Pipe of Tuple2[Int, String]) mapping elements in p1:

p1.map( (t) => t._1 )

When a function takes only one parameter and is extremely simple, we can use the following shorthand:

p1.map( _._1 )

This syntax defines a function that takes one parameter on which we call ._1 (get the first element of the tuple)

WARNING: _ expands only to the expression directly around it. _._1._2 works but (_._1)._2 does not. (it turns into ((t) => (t._1))._2 which does not compile) always fallback to the full syntax when in doubt: (t) => (t._1)._2 works

In Scala the syntax for getting a field is the same as for calling a parameter-less method (parens are omitted). In fact getting a fields is calling a parameter-less methods.

operator notation to call a function:

 p1 map f 

is the same as

 p1.map(f)

In Scala every method can be used as an operator. In fact, this is how operators are implemented as symbols are allowed in method names.

p1 filter { _._1 == 0 } map { _._2 }

also: p1.map { (t) => t._1 } notice the curly braces, we're executing a block of code that returns a function. the result (last statement) of { } is passed to map p1.map { println("foo"); (t) => t._1 } "foo" is printed once (before passing the function to map) p1.map { println("foo"); _._1 } "foo" is printed once (before passing the function to map) l.map{ (t) => { println("foo"); t._1 } } "foo" is printed for each element

pattern matching short hand

p1.map { case (a,b) => a } block of code that returns a partial function that is then passed to map is a short hand for:

p1.map( (t) => t match { case (a,b) => a } )

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