I have a struct that looks something like this:

struct MultipartMessage {
    ubyte[] mime, data;
    Header header;

    void setSender(string sender) {
        header.sender = sender;
    void setId(int id) {
        header.id = id;

and I would like to iterate over it, in another class with something like this:

struct Socket {

    void send(MultipartMessage msg) {
        foreach (part; msg) {


Is this possible? I'd like to use something analogous to Python's __iter__ in the MultipartMessage that can return the fields in a specific order, and ideally even run some additional code, like header.serialize().

Ideally I would add a function to MultipartMessage that would look something like this (pseudocode):

ubyte[] __iter__() {
    yield mime;
    yield data;
    yield header.serialize(); //header.serialize returns a ubyte[]
  • As stated in the documentation (dlang.org/spec/statement.html#ForeachStatement) there are many ways to deal with foreach statements. The easiest is maybe the input range, but without a clear view of what you want each iteration to return it is hard to tell which way is the best for your case. Could you be more precise?
    – cym13
    Dec 1, 2015 at 18:18

3 Answers 3


Use tupleof:

foreach (ref part; msg.tupleof)

This will call sendPart with mime, data and header (the struct's fields, in the order they were declared). You can filter fields by checking their type with e.g. static if (!is(typeof(part) == Header)).

To get the field's name, you can use __traits(identifier):

foreach (i, ref part; msg.tupleof)
    writeln(__traits(identifier, msg.tupleof[i]));

(__traits(identifier, part) would return part.)

There's also __traits(allMembers), which also returns methods.

  • Maybe I misunderstood the question, but D's __iter__ is opApply. Dec 1, 2015 at 0:30
  • what do you mean by D's __iter__ is opApply? How could that be used to iterate over a struct?
    – Charles L.
    Dec 1, 2015 at 17:20

The closest thing to what you want is probably opApply.

See http://dlang.org/spec/statement.html , Section Foreach over Structs and Classes wit opApply

This will work:

int opApply(int delegate(ref ubyte[]) dg) {
    int result = 0;
    result = dg(mime);
    result = dg(data);
    ubyte[] header_bytes = header.serialize();
    result = dg(header_bytes);
    return result;

There are several ways to do iterate over objects in D.

One is to implement the InputRange API. Input ranges are similar to iterators, but have a different API. Implementing a range interface means that you can use all of the std.range/std.algorithm functions on your object, such as map, array, joiner and so on.

D doesn't have an __iter__ function to get an iterator from arbitrary collections, so you will need to implement a function that returns an input range.

import std.range;

auto bytes() {
    return chain(mime, data, header.serialize);

This will return a ubyte input range, consisting of the bytes in mime, followed by the bytes in data, then in header.serialize.

You can also implement the opApply method on your struct. opApply will only work with foreach, so you can't use range methods with it, but it allows you to do things like execute the loop body in separate threads.

The gist of opApply is that D passes the loop body to opApply as a function; that is, foreach(x; myObj) { body } is transformed into myObj.opApply((x) { body }).

void opApply(void delegate(ubyte[] part) loopbody) {

However, instead of either of those options, I recommend that you implement a function on your object that takes an output range and writes the data to it.

An output range is an object that accepts other objects, and does something to them. In this case, the output range should accept ubytes, making it similar to an output stream.

void serialize(Range)(ref Range outRange) if(isOutputRange!(Range, ubyte)) {
    put(outRange, mime); -- `put` simply feeds data into the output range
    put(outRange, data);
    header.serialize(outRange); // No longer have to allocate/return a ubyte array

Example usage, that stores the output into an Appender, which can be converted into an array:

import std.array;

auto serializedDataAppender = appender!ubyte();
auto serializedData = serializedDataAppender.data;

If you implement an output range on top of your socket, then that means that the output range solution does not have to allocate any memory from the heap.

Check out the Programming in D book (specifically, the Ranges and More Ranges sections) for info on how to implement your own ranges.

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