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Coming from a python background, and just starting with Go, I found myself looking for the equivalent of the map() and reduce() functions in Go. I didn't find them, so fell back on for loops. For example, this is what I used instead of a map(), where mapFunction is defined elsewhere:

data := make([]byte, 1024)
count, err := input.Read(data) // error handling removed from this snippet
for i:=0; i<count; i++ {
    data[i] = mapFunction(data[i])
}

and this is what I used instead of a reduce(), where there are 2 state variables that I'm using to keep track of quoting of fields in a CSV as the code moves through each item in the slice:

data := make([]byte, 1024)
count, err := input.Read(data) // error handling removed from this snippet
for i:=0; i<count; i++ {
    data[i], stateVariable1, stateVariable2 =
        reduceFunction(data[i], stateVariable1, stateVariable2)
}

Here are my questions:

  1. Are there builtin capabilties for this that I missed?
  2. Is it appropriate to use mutable slices for each of these?
  3. Would it be a good idea to use goroutines for the map()? Would that allow decoupling of the IO operation to read the file and the process to run the mapping function on each item, and therefore allow parallelization?
  4. Is it correct to say that goroutines would not be appropriate for the reduce() function because the 2 state variables are defined by all of the preceding data, and it must proceed sequentially. In other words, this sequential process cannot benefit from concurrent architecture?

Thanks!

ps - the full code is here: https://github.com/dbro/csvquote/blob/go/csvquote.go

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2 Answers

up vote 3 down vote accepted

In short:

  1. No, there is no builtin map or reduce.
  2. Yes. What else?
  3. No. Do not even think about such stuff without prior measuring or some proven real need.
  4. Yes.

A bit longer.

  1. Go is not functional, no map/reduce builtins or in the standard library
  2. There are array and slices in Go. Both are mutable. Slices are the natural choice most of the time.
  3. Premature optimization... , but of course: Reading an processing could go into one loop and wrapping input in a bufio.Reader could be a good idea.
  4. Goroutines are nice, they allow a different type of program construction, but that does not mean that they are to be used for everything. There is no need to complicate a perfectly clear for loop by introducing goroutines.
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On (1.): Go supports higher order functions (which are neccessary for map and reduce), it's just the type system that isn't expressive enough for a generic map. Assuming 'a were a type variable, we would need functions func map(f func('a) 'a, l []'a) []'a and func reduce(f func('a, 'a) 'a, l []'a) 'a. Manually specializing these for a certain type (e.g. 'a → byte) is possible. –  amon May 19 '13 at 7:52
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Volker has given a good answer, but it doesn't play to one of Go's main strengths, which is its concurrency. A map/reduce type of operation may be parallelized (premature optimization aside) through the use of a 'server farm' strategy. This involves dividing the work to be done into work packets that are sent to separate workers (i.e. goroutines). Map/Reduce is a generic way of doing this and requires higher order functions and immutable data structures.

Go is flexible enough to allow a bespoke parallel decomposition even though it isn't a functional language. Although there's no immutability, it allows aliasing to be avoided through the use of copy semantics, thereby eliminating race conditions when values are exchanged between goroutines, which is effectively as good. Put simply: use structs directly instead of pointers to structs when sharing. (And to help, there's a new race detector in Go1.1).

The server farm pattern is a good way of achieving high parallelization efficiencies because it is self-balancing. This contrasts with geometric decompositions (i.e. sharing a grid of data by clumping zones and allocating them to processors) and with algorithmic decompositions (i.e. allocating different stages in a pipeline to different processors), both of which suffer from potentially unbalanced load. Go is capable of expressing all three kinds.

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