From the view of the user, there is no difference between a programming function and a subroutine but in theory, there definitely is!

The concept itself is different between a subroutine and a function. Formally, the OP's definition is correct. Subroutines don't take arguments or give return values by *formal* semantics. That's just an interpretion with conventions. And variables in subroutines are accessible in other subroutines of the same file although this can be achieved as well in C with some difficulties.

### Summary:

Subroutines work only based on side-effects, in the view of the programming language you are programming with. The concept itself has no explicit arguments or return values. You have to use side effects to simulate them.

Functions are mappings of input to output value(s) in the original sense, some kind of general substitution operation. In the adopted sense of the programming world, functions **are an abstraction** of subroutines with information about return value and arguments, inspired by mathematical functions. The additional formal abstraction differentiates a function from a subroutine in programming context.

### Details:

The subroutine originally is simply a repeatable snippet of code which you can call in between other code. It originates in Assembly or Machine language programming and designates the instruction sequence itself. In the light of this meaning, Perl also uses the term subroutine for its callable code snippets.

**Subroutines are concrete objects.**

This is what I understood: the concept of a (pure) function is a mathematical concept which is a special case of mathematical relations with an own formal notation. You have an input or argument and it is defined what value is represented by the function with the given argument. The original function concept is entirely unrelated to instructions or calculations. Mathematical operations (or instructions in the programming world) only are a popular formal representation (description) of the actual mapping. The original function term itself is not defined as code. Calculations do not constitute the function, so that functions actually don't have any computational overhead because they are direct mappings. Function complexity considerations only arrived as there is an overhead to find the mapping.

**Functions are abstract objects.**

Now, since the whole PC-stuff is running on small machine instructions, the easiest way to model (or instantiate) mathematics is with a sequence of instructions itself. Computer Science has been founded by mathematicians (noteworthy: Alan Turing) and the first programming concepts are based on it so there is a need to bring mathematics into the machine. That's how I imagine the reason why "function" is the name of something which is implemented as subroutine and why the term "pure" function was coined to differentiate the original function concept from the overly broad term-use in programming languages.

Note: in Assembly Language Programming, it is typically said, that a subroutine has been passed arguments and gives a return value. This is an **interpretation** on top of the concrete formal semantics. Calling conventions specify the location where values, to be considered as arguments and return values, should be written to before calling a subroutine or returning. The call itself takes only a subroutine address, and has no formal arguments or return values.

**PS:** functions in programming languages don't necessarily need to be a subroutine (even though programming language terminology developed this way). Functions in functional programming languages can be constant variables, arrays or hash tables. Isn't every datastructure in ECMAScript a function?