# Is there an explanation for inline operators in "k += c += k += c;"?

What is the explanation for the result from the following operation?

``````k += c += k += c;
``````

I was trying to understand the output result from the following code:

``````int k = 10;
int c = 30;
k += c += k += c;
//c=70
``````

and currently I am struggling with understanding why the result for "k" is 80. Why is assigning k=40 not working (actually Visual Studio tells me that that value is not being used elsewhere)?

Why is k 80 and not 110?

If I split the operation to:

``````k+=c;
c+=k;
k+=c;
``````

the result is k=110.

I was trying to look through the CIL, but I am not so profound in interpreting generated CIL and can not get a few details:

`````` // [11 13 - 11 24]
IL_0001: ldc.i4.s     10
IL_0003: stloc.0      // k

// [12 13 - 12 24]
IL_0004: ldc.i4.s     30
IL_0006: stloc.1      // c

// [13 13 - 13 30]
IL_0007: ldloc.0      // k expect to be 10
IL_0008: ldloc.1      // c
IL_0009: ldloc.0      // k why do we need the second load?
IL_000a: ldloc.1      // c
IL_000b: add          // I expect it to be 40
IL_000c: dup          // What for?
IL_000d: stloc.0      // k - expected to be 40
IL_000f: dup          // I presume the "magic" happens here
IL_0010: stloc.1      // c = 70
IL_0012: stloc.0      // k = 80??????
``````
• You got different result because you split the function, k += c += k += c = 80 because the values of k and c stay the same in all the sums, so k += c += k += c is equal to 10 + 30 + 10 + 30 Feb 13, 2019 at 16:20
• Interesting exercise, but, in practice, never write code chaining like that unless you want your coworkers to hate you. :) Feb 13, 2019 at 16:22
• @AndriiKotliarov because k += c += k += c is 10 + 30 + 10 + 30, so, K receives all the values, and C gets only the last 3 arguments 30 + 10 + 30 = 70 Feb 13, 2019 at 16:25
• Also worth reading - Eric Lippert's answer to What is the difference between i++ and ++i? Feb 13, 2019 at 16:37
• "Doctor, doctor, it hurts when I do this!" "So don't DO that." Feb 13, 2019 at 17:35

An operation like `a op= b;` is equivalent to `a = a op b;`. An assignment can be used as statement or as expression, while as expression it yields the assigned value. Your statement ...

``````k += c += k += c;
``````

... can, since the assignment operator is right-associative, also be written as

``````k += (c += (k += c));
``````

or (expanded)

``````k =  k +  (c = c +  (k = k  + c));
10    →   30    →   10 → 30   // operand evaluation order is from left to right
|         |        ↓    ↓
|         ↓   40 ← 10 + 30   // operator evaluation
↓   70 ← 30 + 40
80 ← 10 + 70
``````

Where during the whole evaluation the old values of the involved variables are used. This is especially true for the value of `k` (see my review of the IL below and the link Wai Ha Lee provided). Therefore, you are not getting 70 + 40 (new value of `k`) = 110, but 70 + 10 (old value of `k`) = 80.

The point is that (according to the C# spec) "Operands in an expression are evaluated from left to right" (the operands are the variables `c` and `k` in our case). This is independent of the operator precedence and associativity which in this case dictate an execution order from right to left. (See comments to Eric Lippert's answer on this page).

Now let's look at the IL. IL assumes a stack based virtual machine, i.e. it does not use registers.

``````IL_0007: ldloc.0      // k (is 10)
IL_0008: ldloc.1      // c (is 30)
IL_0009: ldloc.0      // k (is 10)
IL_000a: ldloc.1      // c (is 30)
``````

The stack now looks like this (from left to right; top of stack is right)

10 30 10 30

``````IL_000b: add          // pops the 2 top (right) positions, adds them and pushes the sum back
``````

10 30 40

``````IL_000c: dup
``````

10 30 40 40

``````IL_000d: stloc.0      // k <-- 40
``````

10 30 40

``````IL_000e: add
``````

10 70

``````IL_000f: dup
``````

10 70 70

``````IL_0010: stloc.1      // c <-- 70
``````

10 70

``````IL_0011: add
``````

80

``````IL_0012: stloc.0      // k <-- 80
``````

Note that `IL_000c: dup`, `IL_000d: stloc.0`, i.e. the first assignment to `k` , could be optimized away. Probably this is done for variables by the jitter when converting IL to machine code.

Note also that all the values required by the calculation are either pushed to the stack before any assignment is made or are calculated from these values. Assigned values (by `stloc`) are never re-used during this evaluation. `stloc` pops the top of the stack.

The output of the following console test is (`Release` mode with optimizations on)

evaluating k (10)
evaluating c (30)
evaluating k (10)
evaluating c (30)
40 assigned to k
70 assigned to c
80 assigned to k

``````private static int _k = 10;
public static int k
{
get { Console.WriteLine(\$"evaluating k ({_k})"); return _k; }
set { Console.WriteLine(\$"{value} assigned to k"); _k = value; }
}

private static int _c = 30;
public static int c
{
get { Console.WriteLine(\$"evaluating c ({_c})"); return _c; }
set { Console.WriteLine(\$"{value} assigned to c"); _c = value; }
}

public static void Test()
{
k += c += k += c;
}
``````
• You could add the final result with the numbers in the formula for even more complete : final is `k = 10 + (30 + (10 + 30)) = 80` and that `c` final value is set in the first parenthesis which is `c = 30 + (10 + 30) = 70`. Feb 13, 2019 at 16:26
• Indeed if `k` is a local then the dead store is almost certainly removed if optimizations are on, and preserved if they are not. An interesting question is whether the jitter is permitted to elide the dead store if `k` is a field, property, array slot, and so on; in practice I believe it does not. Feb 13, 2019 at 19:28
• A console test in Release mode indeed shows that `k` is assigned twice if it is a property. Feb 13, 2019 at 19:41

First off, Henk and Olivier's answers are correct; I want to explain it in a slightly different way. Specifically, I want to address this point you made. You have this set of statements:

``````int k = 10;
int c = 30;
k += c += k += c;
``````

And you then incorrectly conclude that this should give the same result as this set of statements:

``````int k = 10;
int c = 30;
k += c;
c += k;
k += c;
``````

It is informative to see how you got that wrong, and how to do it right. The right way to break it down is like this.

First, rewrite the outermost +=

``````k = k + (c += k += c);
``````

Second, rewrite the outermost +. I hope you agree that x = y + z must always be the same as "evaluate y to a temporary, evaluate z to a temporary, sum the temporaries, assign the sum to x". So let's make that very explicit:

``````int t1 = k;
int t2 = (c += k += c);
k = t1 + t2;
``````

Make sure that is clear, because this is the step you got wrong. When breaking down complex operations into simpler operation you must make sure that you do so slowly and carefully and do not skip steps. Skipping steps is where we make mistakes.

OK, now break down the assignment to t2, again, slowly and carefully.

``````int t1 = k;
int t2 = (c = c + (k += c));
k = t1 + t2;
``````

The assignment will assign the same value to t2 as is assigned to c, so let's say that:

``````int t1 = k;
int t2 = c + (k += c);
c = t2;
k = t1 + t2;
``````

Great. Now break down the second line:

``````int t1 = k;
int t3 = c;
int t4 = (k += c);
int t2 = t3 + t4;
c = t2;
k = t1 + t2;
``````

Great, we are making progress. Break down the assignment to t4:

``````int t1 = k;
int t3 = c;
int t4 = (k = k + c);
int t2 = t3 + t4;
c = t2;
k = t1 + t2;
``````

Now break down the third line:

``````int t1 = k;
int t3 = c;
int t4 = k + c;
k = t4;
int t2 = t3 + t4;
c = t2;
k = t1 + t2;
``````

And now we can look at the whole thing:

``````int k = 10;  // 10
int c = 30;  // 30
int t1 = k;  // 10
int t3 = c;  // 30
int t4 = k + c; // 40
k = t4;         // 40
int t2 = t3 + t4; // 70
c = t2;           // 70
k = t1 + t2;      // 80
``````

So when we are done, k is 80 and c is 70.

Now let's look at how this is implemented in the IL:

``````int t1 = k;
int t3 = c;
is implemented as
ldloc.0      // stack slot 1 is t1
ldloc.1      // stack slot 2 is t3
``````

Now this is a bit tricky:

``````int t4 = k + c;
k = t4;
is implemented as
add          // sum them to stack slot 3
dup          // t4 is stack slot 3, and is now equal to the sum
stloc.0      // k is now also equal to the sum
``````

We could have implemented the above as

``````ldloc.0      // load k
stloc.0      // k is now equal to the sum
ldloc.0      // t4 is now equal to k
``````

but we use the "dup" trick because it makes the code shorter and makes it easier on the jitter, and we get the same result. In general, the C# code generator tries to keep temporaries "ephemeral" on the stack as much as possible. If you find it easier to follow the IL with fewer ephemerals, turn optimizations off, and the code generator will be less aggressive.

We now have to do the same trick to get c:

``````int t2 = t3 + t4; // 70
c = t2;           // 70
is implemented as:
add          // t3 and t4 are the top of the stack.
dup
stloc.1      // again, we do the dup trick to get the sum in
// both c and t2, which is stack slot 2.
``````

and finally:

``````k = t1 + t2;
is implemented as
add          // stack slots 1 and 2 are t1 and t2.
stloc.0      // Store the sum to k.
``````

Since we do not need the sum for anything else, we do not dup it. The stack is now empty, and we're at the end of the statement.

The moral of the story is: when you are trying to understand a complicated program, always break down operations one at a time. Don't take short cuts; they will lead you astray.

• @OlivierJacot-Descombes: The relevant line of the spec is in the section "Operators" and says "Operands in an expression are evaluated from left to right. For example, in `F(i) + G(i++) * H(i)`, method F is called using the old value of i, then method G is called with the old value of i, and, finally, method H is called with the new value of i. This is separate from and unrelated to operator precedence." (Emphasis added.) So I guess I was wrong when I said there is nowhere that "the old value is used" occurs! It occurs in an example. But the normative bit is "left to right". Feb 13, 2019 at 21:05
• This was the missing link. The quintessence is that we must differentiate between operand evaluation order and operator precedence. Operand evaluation goes from left to right and in the OP’s case the operator execution from right to left. Feb 13, 2019 at 21:55
• @OlivierJacot-Descombes: That's exactly right. Precedence and associativity have nothing whatsoever to do with the order in which subexpressions are evaluated, other than the fact that precedence and associativity determine where the subexpression boundaries are. Subexpressions are evaluated left-to-right. Feb 13, 2019 at 22:16
• Ooops looks like you can't overload assignment operators :/ Feb 14, 2019 at 15:55
• @johnny5: That's correct. But you can overload `+`, and then you will get `+=` for free because `x += y` is defined as `x = x + y` except `x` is evaluated only once. That's true regardless of whether the `+` is built in or user-defined. So: try overloading `+` on a reference type and see what happens. Feb 14, 2019 at 15:56

It boils down to: is the very first `+=` applied to the original `k` or to the value that was computed more to the right ?

The answer is that although assignments bind from right to left, operations still proceed from left to right.

So the leftmost `+=` is executing `10 += 70`.

• This puts it nicely in a nut shell. Feb 13, 2019 at 22:56
• Its actually the operands which are evaluated from left to right. Feb 16, 2019 at 17:20

I tried the example with gcc and pgcc and got 110. I checked the IR they generated, and compiler did expand the expr to:

``````k = 10;
c = 30;
k = c+k;
c = c+k;
k = c+k;
``````

which looks reasonable to me.

for this kind of chain assignments, you have to assign the values from starting at the most right side. You have to assign and calculate and assign it to left side, and go on this all the way to the final (leftmost assignment), Sure it is calculated as k=80.

Simple answer: Replace vars with values und you got it:

``````int k = 10;
int c = 30;
k += c += k += c;
10 += 30 += 10 += 30
= 10 + 30 + 10 + 30
= 80 !!!
``````
• This answer is wrong. Though this technique works in this specific case, that algorithm does not work in general. For example, `k = 10; m = (k += k) + k;` does not mean `m = (10 + 10) + 10`. Languages with mutating expressions cannot be analyzed as though they have eager value substitution. Value substitution happens in a particular order with respect to the mutations and you must take that into account. Feb 16, 2019 at 15:39

You can solve this by counting.

``````a = k += c += k += c
``````

There are two `c`s and two `k`s so

``````a = 2c + 2k
``````

And, as a consequence of the operators of the language, `k` also equals `2c + 2k`

This will work for any combination of variables in this style of chain:

``````a = r += r += r += m += n += m
``````

So

``````a = 2m + n + 3r
``````

And `r` will equal the same.

You can work out the values of the other numbers by only calculating up to their leftmost assignment. So `m` equals `2m + n` and `n` equals `n + m`.

This demonstrates that `k += c += k += c;` is different to `k += c; c += k; k += c;` and hence why you get different answers.

Some folks in the comments seem to be worried that you might try to over generalise from this shortcut to all possible types of addition. So, I'll make it clear that this shortcut is only applicable to this situation, i.e. chaining together addition assignments for the built in number types. It doesn't (necessarily) work if you add other operators in, e.g. `()` or `+`, or if you call functions or if you've overriden `+=`, or if you're using something other than the basic number types. It's only meant to help with the particular situation in the question.

• This does not answer the question Feb 14, 2019 at 15:40
• @johnny5 it explains why you get the result you get, i.e. because that's how maths works. Feb 14, 2019 at 15:45
• Math and the orders of operations that a compiler evaulates a statement are two different things. Under your logic k+=c; c+= k; k+=c should evaluate to the same result. Feb 14, 2019 at 15:53
• No, johnny 5, that's not what it means. Mathematically they are different things. The three separate operations evaluate to 3c + 2k. Feb 14, 2019 at 16:18
• Unfortunately your "algebraic" solution is only coincidentally correct. Your technique does not work in general. Consider `x = 1;` and `y = (x += x) + x;` Is it your contention that "there are three x's and so y is equal to `3 * x`"? Because `y` is equal to `4` in this case. Now what about `y = x + (x += x);` is it your contention that the algebraic law "a + b = b + a" is fulfilled and this is also 4? Because this is 3. Unfortunately, C# does not follow the rules of high school algebra if there are side effects in the expressions. C# follows the rules of a side effecting algebra. Feb 15, 2019 at 1:36