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Say I have an object of type A. Consider this case for any function of the type A -> A (i.e. takes object of type A and returns another object of type A):

foo = func(foo)

Here, the simplest case would be to for the result of func(foo) to be copied into foo. Is it possible to optimize this so that:

  • foo gets modified inplace in func

There are no constraints on the language used. What I want to know is what constraints and properties the language must have to enable such an optimization. Are there any existing languages which perform such an optimization?

Example(in pseudo code):

type Matrix = List<List<int>>

Matrix rotate90Deg(Matrix x):
   Matrix result(x.columns, x.rows) #Assume it has a constructor which takes as args the num of rows, and num of cols.
   for (int i = 0; i < x.rows; i++):
       for (int j = 0; j < x.columns; j++):
           result[i][j] = x[j][i]
   return result

Matrix a = [[1,2,3],[4,5,6],[7,8,9]]
a = rotate90Deg(a)

Here, is it possible to optimize the code so that it doesn't allocate memory for a new matrix(result), and instead just modifies the original matrix passed.

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closed as primarily opinion-based by bmargulies, ryan1234, Rubens, Undo, RiaD Jul 6 '13 at 4:13

Many good questions generate some degree of opinion based on expert experience, but answers to this question will tend to be almost entirely based on opinions, rather than facts, references, or specific expertise. If this question can be reworded to fit the rules in the help center, please edit the question.

Sure, when you inline function call you can do that and much more. –  zch Jul 3 '13 at 14:35
Could you elaborate on how inline functions can help make a function inplace? Thank you. –  Likhit Jul 3 '13 at 14:42
Consider func(x) = x * 2 and code foo = func(foo). After inlining it's foo = foo * 2 and on common processors can be realized with single instruction like ADD r1, r1. It's also possible in more complex cases, especially if address of foo doesn't "escape". –  zch Jul 3 '13 at 14:59
In C-like languages, func can take a pointer to foo, operate on foo and write back to foo directly. void func(int* foo) { (*foo) += 10; }. C# does the same with ref parameters. Is this what you're getting at? –  antiduh Jul 3 '13 at 15:01
@antiduh no that's not what I mean. I edited the question and added an example. –  Likhit Jul 3 '13 at 15:18

2 Answers 2

up vote 2 down vote accepted

First of all, you have to realize that some operations are inherently not possible to be computed in-place. Matrix-matrix multiplication is an example of this, and rotate90Deg would fall under this category since such an operation is actually a matrix multiplication by the appropriate multiplication matrix.

Now as for your example, you actually coded up a matrix transpose function. Matrix transpose can be done in-place since you are swapping pairs of numbers, but I doubt that any compilers can automatically detect this and optimize it for you. Indeed, there are many, many tricks that one can do to optimize matrix transpose in order to be cache-friendly in order to gain huge performance increases. Nevertheless, with an naive implementation, you will almost certainly end up with something very similar to what Aditya Kumar describes in his answer.

As I have foreshadowed by using the word "naive" earlier, programmers can coax the compiler to inline lots and lots of things in extremely optimized ways through advanced templating and other meta-programming techniques. (At least in C++, and maybe other languages that allow you to overload operator =.) For anyone interested in a case study of how this is done and what is involved, take a look at the Eigen matrix library, and how it handles a simple operation like u = v + w; where the three variables are all matrices of floats. Following is a brief overview of the key points.

A naive implementation would overload operator+ to return a temporary and operator= to copy that temporary to the result. Of course, in C++11 it is pretty easy to avoid the final copy during assignment by way of move constructors, but you will still have unnecessary temporaries if you had something a little more complex with multiple operators on the right hand side like u = 3.15f * u.transposed() + 5.0f; since each operator/method would return a temporary, and that temporary would have to be looped over in order to process the next operator.

Long story short, what Eigen does is rather than perform each operation when the corresponding function call occurs, the calls return a templated functor of sorts which merely describes the operation that needs to take place, and all the actual work ends up happening in operator =, thus enabling the compiler to emit a single, inlined loop for traversing the data only once and doing the operation truly in-place.

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Yes it is possible, and this optimization is provided by at least C++11 (inlining).

To explain the optimization a little bit.


foo_t foo;
foo = func(foo); // #1
foo_t func(foo_t foo1) {
   foo_t new_foo;
   // operate on new_foo by using foo1
   return new_foo;

There are three instances of foo_t being made:

  1. foo is copied and passed as foo1 to func
  2. new_foo is created.
  3. new_foo is assigned to foo by copying the contents of new_foo into foo;

All the three copies can be eliminated provided there are some invariants.

  1. foo (the argument to be passed to function is never used later with the same original value. This is equivalent to saying that foo is 'dead' at line #1. This is established here as foo is reassigned.
  2. the scope of object new_foo in function func has its lifetime that does not extend the life of function func. This is also established here as the way new_foo is created, it will be on stack and the lifetime of objects in stack is the same as the lifetime of the function in which the object was created.

In C++ it can be achieved using inlining the function func. After inlining, the code basically will look like this.

`foo_t foo;`
`foo_t new_foo;`
`// operate on new_foo by using foo`
`foo = new_foo;`

Although, C++ provides inlining as a language feature but almost any optimizing compiler do inlining these days.

Now it depends on what kind of operation you perform on new_foo and foo whether this extra new_foo will be optimized away or not. For some data types it is trivial (the compiler can do a 'copy-propagation' followed by 'dead-code elimination' to remove new_foo completely.

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In the above example the temporary object cannot be eliminated because the source and destination are the same. To modify the destination destroys the source. –  Hot Licks Jul 4 '13 at 19:43
@HotLicks, You are right. I have removed the references to move-semantics. –  A. K. Jul 5 '13 at 22:57

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