None of it is heap-allocated, unless something else is going on (particularly if the compiler can't guarantee that the lifetime of variables captured by the local function don't exceed the lifetime of the parent method, e.g. if a delegate refers to the local function, or the local function contains yield return
or await
statements).
Let's say you have:
public void M(int i) {
Inner(i + 1);
void Inner(int x)
{
int j = x + i;
Console.WriteLine(j);
}
}
Using the wonderful SharpLab, we can see this gets compiled to:
[StructLayout(LayoutKind.Auto)]
[CompilerGenerated]
private struct <>c__DisplayClass0_0
{
public int i;
}
public void M(int i)
{
<>c__DisplayClass0_0 <>c__DisplayClass0_ = default(<>c__DisplayClass0_0);
<>c__DisplayClass0_.i = i;
<M>g__Inner|0_0(<>c__DisplayClass0_.i + 1, ref <>c__DisplayClass0_);
}
[CompilerGenerated]
internal static void <M>g__Inner|0_0(int x, ref <>c__DisplayClass0_0 P_1)
{
Console.WriteLine(x + P_1.i);
}
So the compiler's taken our inner function, and rewritten it as a static method. Parameters to the inner function remain as parameters to the static method. Things captured by the inner function end up as fields on a compiler-generated struct, which is passed by ref (to avoid copying, and so that changes made to it in the static method are reflected in the calling method).
Structs allocated in that inner function will just be allocated the same in the static method - i.e. on the stack.
Now let's compare that to equivalent code, but using a delegate:
public void M(int i) {
Action<int> inner = x =>
{
int j = x + i;
Console.WriteLine(j);
};
inner(i + 1);
}
This gets compiled to:
[CompilerGenerated]
private sealed class <>c__DisplayClass0_0
{
public int i;
internal void <M>b__0(int x)
{
Console.WriteLine(x + i);
}
}
public void M(int i)
{
<>c__DisplayClass0_0 <>c__DisplayClass0_ = new <>c__DisplayClass0_0();
<>c__DisplayClass0_.i = i;
new Action<int>(<>c__DisplayClass0_.<M>b__0)(<>c__DisplayClass0_.i + 1);
}
Here we can see the difference. The compiler's generated a new class, which has fields to hold the variables captured by the delegate, and has a method on it which contains the body of our delegate. It's had to use a class, rather than a struct passed by reference.
To understand why, think about the fact that your code can pass a delegate around - it could store it in a field, or return it, or pass it to another method. In that case, it's not just being synchronously called by its parent (as a local function must be), but it has to instead carry around the variables it captured with it.
Note that something similar happens if we create a delegate referring to a local function:
public void M(int i) {
void Inner(int x)
{
int j = x + i;
Console.WriteLine(j);
}
Action<int> inner = Inner;
inner(i + 1);
}
This gets compiled to the same as before:
[CompilerGenerated]
private sealed class <>c__DisplayClass0_0
{
public int i;
internal void <M>g__Inner|0(int x)
{
Console.WriteLine(x + i);
}
}
public void M(int i)
{
<>c__DisplayClass0_0 <>c__DisplayClass0_ = new <>c__DisplayClass0_0();
<>c__DisplayClass0_.i = i;
new Action<int>(<>c__DisplayClass0_.<M>g__Inner|0)(<>c__DisplayClass0_.i + 1);
}
Here, the compiler's spotted that it needs to create the delegate anyway, so it generates the same code as in the previous example.
Note that there are other cases where the compiler has to perform heap allocations when calling a local function, such as if the local function has to be resumable because it contains yield return
or await
statements.
To address the specific example in your edit:
int ParentFunction ()
{
int parentVarLambda = 0;
int parentVarLocal = 0;
Func<int> lamdaFuncion = () => parentVarLambda + 1;
int a = lamdaFuncion();
int b = LocalFunction();
return a + b;
int LocalFunction()
{
int localVar = 1;
return parentVarLocal += localVar;
}
}
We can again put this into SharpLab, and get:
[CompilerGenerated]
private sealed class <>c__DisplayClass0_0
{
public int parentVarLambda;
public int parentVarLocal;
internal int <ParentFunction>b__0()
{
return parentVarLambda + 1;
}
internal int <ParentFunction>g__LocalFunction|1()
{
int num = 1;
return parentVarLocal += num;
}
}
private int ParentFunction()
{
<>c__DisplayClass0_0 <>c__DisplayClass0_ = new <>c__DisplayClass0_0();
<>c__DisplayClass0_.parentVarLambda = 0;
<>c__DisplayClass0_.parentVarLocal = 0;
int num = new Func<int>(<>c__DisplayClass0_.<ParentFunction>b__0)();
int num2 = <>c__DisplayClass0_.<ParentFunction>g__LocalFunction|1();
return num + num2;
}
Note that the compiler's realised that it had to create a new instance of a generated class for the delegate anyway, so it's just opted to deal with the local function in the same way at no extra cost. It doesn't make much difference in this case, but this technique is needed where the delegate and the local function capture the same variables - they need to be hoisted into the same generated class.
Because of this, both parentVarLambda
and parentVarLocal
were allocated on the same compiler-generated class, and localFuncVar
just got optimized away (but would have been allocated on the stack in <ParentFunction>g__LocalFunction|1()
).