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I wrote a simple program to examine how IL works :

void Main()

 int a=5;
 int b=6;
 if (a<b) Console.Write("333");

The IL :

IL_0000:  ldc.i4.5    
IL_0001:  stloc.0     
IL_0002:  ldc.i4.6    
IL_0003:  stloc.1     
IL_0004:  ldloc.0     
IL_0005:  ldloc.1     
IL_0006:  bge.s       IL_0012
IL_0008:  ldstr       "333"
IL_000D:  call        System.Console.Write
IL_0012:  call        System.Console.ReadLine

I'm trying to understand the implemented efficiency :

  • at line #1 (IL code) it pushes the value 5 onto the stack ( 4 bytes which is int32)

  • at line #2 (IL code) it POPs from the stack into a local variable.

same goes for the next 2 lines.

and then , it loads those local variables onto the stack and THEN it evaluate bge.s.

Question #1

Why does he loads the local variables to the stack ? the values has already been in the stack. but he poped them in order to put them in a local variables . isn't it a waste ?

I mean , why the code couldn't be something like :

IL_0000:  ldc.i4.5
IL_0001:  ldc.i4.6    
IL_0002:  bge.s       IL_0004
IL_0003:  ldstr       "333"
IL_0004:  call        System.Console.Write
IL_0005:  call        System.Console.ReadLine

my sample of code is just 5 lines of code. what about 50,000,000 lines of code ? there will be plenty of extra code emitted by IL

Question #2

Looking at the code address :

enter image description here

  • where is the IL_0009 address ? isnt it supposed to be sequential ?

p.s. Im with Optimize flag on + release mode

share|improve this question
Is this debug or optimized compiler ? –  spender Dec 8 '12 at 11:48
@spender release mode+optimize on –  Royi Namir Dec 8 '12 at 12:08

4 Answers 4

up vote 6 down vote accepted

Why does he loads the local variables to the stack? The values has already been in the stack. But he poped them in order to put them in a local variables. Isn't it a waste?

A waste of what? You have to remember that IL (usually) isn't executed as it is, it's compiled again by the JIT compiler, which performs most of the optimizations. One of the points of using an “intermediate language” is so that optimizations can be implemented in one place: the JIT compiler and each language (C#, VB.NET, F#, …) doesn't have to implement them all over again. This is explained by Eric Lippert in his article Why IL?

Where is the IL_0009 address? Isn't it supposed to be sequential?

Let's have a look at the specification of the ldstr instruction (from ECMA-335):

III.4.16 ldstr – load a literal string

Format: 72 <T> […]

The ldstr instruction pushes a new string object representing the literal stored in the metadata as string (which is a string literal).

That reference to metadata above and the <T> mean that the byte 72 of the instruction is followed by a metadata token, which points to a table containing strings. How big is such token? From section III.1.9 of the same document:

Many CIL instructions are followed by a "metadata token". This is a 4-byte value, that specifies a row in a metadata table […]

So, in your case, the byte 72 of the instruction is at the address 0008 and the token (0x70000001 in this case, where the 0x70 byte represents the user strings table) is at addresses 0009 to 000C.

share|improve this answer
why did the IL supply extra code to JIT to handle at first place ? –  Royi Namir Dec 8 '12 at 13:11
Because writing code that makes this optimization in the C# compiler is completely useless work. The CIL compiler already does that well, why should the C# compiler try to do the same thing? –  svick Dec 8 '12 at 13:14
@RoyiNamir, because it is easier to compile it this way, and there is no point in optimising out this "extra code", because JIT will do it later. Most of the .NET languages compiler frontends are pretty straightforward. –  SK-logic Dec 8 '12 at 13:14
@RoyiNamir, why are you calling it "extra code"? It is a direct, straightforward translation from the source code. It is an abstract, intermediate representation, and it does not have an operational semantics itself. There are no e=>f and j=>k operations in reality, they're all abstract. Have you ever seen an LLVM IR emitted directly by Clang frontend? It's full of "extra" code. Same for the GCC - its first level of an intermediate code is extremely verbose and not "efficient" at all. Lower level optimisations would take care of all the cruft. –  SK-logic Dec 8 '12 at 13:48
@RoyiNamir, yes, you can optimise it in the frontend - but then you will have to optimise it in a backend too, after all the transformations. Your frontend will be much more complicated, with absolutely no advantage over an unoptimised one. "Stack" representation is great for generating code, but it is not suitable for analysis - SSA is much better, but then it's more complicated to generate such a code straight from the source. I had only one case in my practice when I had to do a kind of register allocation in IL level - a generated pattern matching code was too big for a JIT. –  SK-logic Dec 8 '12 at 14:16

I can answer the second question easily. The instructions are variable-length. For example the ldstr "333" consists of the opcode for ldstr (at address 8) followed by the data representing the string (a reference to the string in the user string table).

Similarly with the call statements following that - you need the call opcode itself plus the information on the functions to call.

The reason the instructions for pushing small values like 4 or 6 onto the stack don't have extra data is because the values are encoded into the opcode itself.

See here for the instructions and encodings.

As to the first question, you may want to look at this blog entry by Eric Lippert, one of the C# developers, which states:

The /optimize flag does not change a huge amount of our emitting and generation logic. We try to always generate straightforward, verifiable code and then rely upon the jitter to do the heavy lifting of optimizations when it generates the real machine code.

share|improve this answer
I disabled the optimize flag , still , same result. –  Royi Namir Dec 8 '12 at 12:21
Well, yes, it would give the same result if what Eric said is true, and I have no reason to doubt him given he's one of the main C# bods. –  paxdiablo Dec 8 '12 at 12:43
BTW, your assumption is wrong. ldstr "333" actually consists of one byte for the opcode and then 4 bytes of a reference to the user strings table, which actually contains the 333 string. –  svick Dec 8 '12 at 13:08
Thanks, @svick, I wasn't certain of the representation - I've updated the answer based on your information. –  paxdiablo Dec 8 '12 at 13:32

There is no point in reasoning about IL efficiency at this level.

JIT will eliminate the stack altogether, transforming all the stack operations into an intermediate three-address code (and further down into SSA). Since IL is never interpreted, stack operations are not supposed to be efficient and optimised.

See the open source Mono implementation for example.

share|improve this answer
What do you mean there is no point in reasoning . I want to see and learn how things work. I do believe I have a lot of reasons to learn it if I want to be smarter - so next time i will be able to understand things better. –  Royi Namir Dec 8 '12 at 12:04
@RoyiNamir, I mean that you cannot reason about your code efficiency based on its stack representation. It is still a highly abstract intermediate language, not reflecting the real native code. –  SK-logic Dec 8 '12 at 12:11
@SK has a point there. IL is never meant to be executed (with the exception micro framework I guess). It's just an intermediate code to produce a native binary. As long as all inefficiencies are eliminated when generating native code, optimizing IL is meaningless (aka wasted effort). –  ssg Dec 8 '12 at 12:11
@SK-logic I get your point , but why to write those commands from the beginning ? why did the IL supply extra code to JIT to handle from the beginning? Do you get my point ? –  Royi Namir Dec 8 '12 at 12:14
@RoyiNamir, think of the stack semantics of the IL as of a simple way to serialise expression trees. Just a high level intermediate representation, in a flattened form. Those expression trees are later deserialised back into tree form, re-compiled into three address form and then all the variable access is unified with the virtual register access and an SSA transform is applied. It is a relatively cheap sequence of transforms, which justifies keeping a dense, easy-to-generate "stack" representation. –  SK-logic Dec 8 '12 at 13:09

To give a final answer to all this discussion about "extra code".

The C# compiler reads int a=5; and translates that to:


Then it goes to the next line and reads int b=6; and that is translated to:


And then it reads the next line with the if statement and so on.

When compiling from C# to IL it reads line by line and translates that line to IL, not that line when looking at other lines.

To optimize the IL and remove the "extra code" (that you call it) in this stage the C# compiler would have to check all the IL code, build a tree representation of it, remove all unneeded nodes and then write it as IL again. This is not something that the C# compiler should do since this will be done by the JIT compiler when going from IL to machine language.

So the code that you see as extra is not extra code, it is part of the statements that the C# compiler has read from your C# code and will be removed when the JIT compiler compiles the code to a native executable.

This was a high level explanation of how the C# code is translated since I don't think that you have taken any classes in compiler construction or anything like that. If you want to know more there are books and pages on the internet to read.

share|improve this answer
Actually, I don't think the C# compiler is that simple. For example, if you have int a=5; and then never use a, it does not produce any IL code for that statement. –  svick Dec 10 '12 at 0:39
I made a simplification based on the knowledge I thought the OP would have. The compiler has a symbol table that probably keeps track of if the variable is used or not but not where in the code it is used (where in the code in a C# way, it has to keep track of where in respect to the IL). –  esrange Dec 10 '12 at 6:39

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