43

The following draft from Scott Meyers new C++11 book says(page 2, lines 7-21)

The difference between unwinding the call stack and possibly unwinding it has a surprisingly large impact on code generation. In a noexcept function, optimizers need not keep the runtime stack in an unwindable state if an exception would propagate out of the function, nor must they ensure that objects in a noexcept function are destroyed in the inverse order of construction should an exception leave the function. The result is more opportunities for optimization, not only within the body of a noexcept function, but also at sites where the function is called. Such flexibility is present only for noexcept functions. Functions with “throw()” exception specifications lack it, as do functions with no exception specification at all.

In contrast, section 5.4 of "Technical Report on C++ Performance" describes the "code" and "table" ways of implementing exception handling. In particular, the "table" method is shown to have no time overhead when no exceptions are thrown and only has a space overhead.

My question is this - what optimizations is Scott Meyers talking about when he talks of unwinding vs possibly unwinding? Why don't these optimizations apply for throw()? Do his comments apply only to the "code" method mentioned in the 2006 TR?

  • 3
    A related question some can forget about is that the exception table approach - even if it did magically have no runtime overhead - incurs at the very least a code size overhead. This can become a problem on embedded devices, some game consoles, mobile apps, etc. – Sean Middleditch Sep 28 '14 at 2:03
  • @SeanMiddleditch Zero overhead unless an exception is thrown is not "magical". – curiousguy May 27 '18 at 4:08
  • 1
    @curiousguy: the "magical" part is that the exception table actually does have overhead. it's just (usually) so inconsequential that a lot of people consider it "zero." you can't get something for nothing, and exceptions are no exception. – Sean Middleditch May 29 '18 at 4:09
27

There's "no" overhead and then there's no overhead. You can think of the compiler in different ways:

  • It generates a program which performs certain actions.
  • It generates a program satisfying certain constraints.

The TR says there's no overhead in the table-driven appraoch because no action needs to be taken as long as a throw doesn't occur. The non-exceptional execution path goes straight forward.

However, to make the tables work, the non-exceptional code still needs additional constraints. Each object needs to be fully initialized before any exception could lead to its destruction, limiting the reordering of instructions (e.g. from an inlined constructor) across potentially throwing calls. Likewise, an object must be completely destroyed before any possible subsequent exception.

Table-based unwinding only works with functions following the ABI calling conventions, with stack frames. Without the possibility of an exception, the compiler may have been free to ignore the ABI and omit the frame.

Space overhead, a.k.a. bloat, in the form of tables and separate exceptional code paths, might not affect execution time, but it can still affect time taken to download the program and load it into RAM.

It's all relative, but noexcept cuts the compiler some slack.

  • Could you elaborate on this - "each place where unwinding (exception-handling) may reenter the function is an additional entry point, meaning it's a barrier across which operations can't be reordered." Or perhaps a reference/example of the difference in the code generated? – Pradhan Sep 27 '14 at 23:10
  • @Pradhan Are you familiar with machine code and entry points, a.k.a. labels in assembly language? I think that's outside the scope of this question. – Potatoswatter Sep 28 '14 at 1:08
  • "Table-based unwinding only works with functions following the ABI calling conventions" why? – curiousguy May 27 '18 at 4:12
  • Any time you can do something, you can do it with a table, by definition. So tables don't inherently limit any optimization. But simplicity of implementation might. – curiousguy Oct 29 at 18:34
13

The difference between noexcept and throw() is that in case of throw() the exception stack is still unwound and destructors are called, so implementation has to keep track of the stack (see 15.5.2 The std::unexpected() function in the standard).

On the contrary, std::terminate() does not require the stack to be unwound (15.5.1 states that it is implementation-defined whether or not the stack is unwound before std::terminate() is called).

GCC seem to really not unwind the stack for noexcept: Demo
While clang still unwinds: Demo

(You can comment f_noexcept() and uncomment f_emptythrow() in the demos to see that for throw() both GCC and clang unwind the stack)

  • "so implementation has to keep track of the stack" When can you not keep track of the stack? – curiousguy May 27 '18 at 4:19
  • @curiousguy in case of noexcept, this is what this answer is all about. – Anton Savin May 29 '18 at 18:38
  • I don't understand what that means in practice. – curiousguy May 29 '18 at 18:45
  • @curiousguy calling destructors for one. You wouldn't have this question if you'd read the answer and run the demos. – Anton Savin May 29 '18 at 19:23
  • Yes indeed but what's the gain in term of optimisation? What cost is avoided if exceptions are not thrown? – curiousguy May 29 '18 at 20:28
10

Take the following example:

#include <stdio.h>

int fun(int a) {

  int res;
  try
  {
    res = a *11;
    if(res == 33)
       throw 20;
  }
  catch (int e)
  {
    char *msg = "error";
    printf(msg);
  }
  return res;
}

int main(int argc, char** argv) {
  return fun(argc);
}

the data passed as input isn't foresee-able from a compiler's perspective and thus no assumption can be made even with -O3 optimizations to completely elide the call or the exception system.

In LLVM IR the fun function roughly translates as

define i32 @_Z3funi(i32 %a) #0 {
entry:
  %mul = mul nsw i32 %a, 11 // The actual processing
  %cmp = icmp eq i32 %mul, 33 
  br i1 %cmp, label %if.then, label %try.cont // jump if res == 33 to if.then

if.then:                                          // lots of stuff happen here..
  %exception = tail call i8* @__cxa_allocate_exception(i64 4) #3
  %0 = bitcast i8* %exception to i32*
  store i32 20, i32* %0, align 4, !tbaa !1
  invoke void @__cxa_throw(i8* %exception, i8* bitcast (i8** @_ZTIi to i8*), i8* null) #4
          to label %unreachable unwind label %lpad

lpad:                                             
  %1 = landingpad { i8*, i32 } personality i8* bitcast (i32 (...)* @__gxx_personality_v0 to i8*)
          catch i8* bitcast (i8** @_ZTIi to i8*)
 ... // also here..

invoke.cont:                                      
  ... // and here
  br label %try.cont

try.cont:        // This is where the normal flow should go
  ret i32 %mul

eh.resume:                                        
  resume { i8*, i32 } %1

unreachable:                                    
  unreachable
}

as you can see the codepath, even if straightforward in the event of a normal control flow (no exceptions), now consists of several basic blocks branches in the same function.

It is true that at runtime almost no cost is associated since you pay for what you use (if you don't throw, nothing extra happens), but having multiple branches might hurt your performances as well, e.g.

  • branch prediction becomes harder
  • register pressure might increase substantially
  • [others]

and surely you can't run passthrough-branch optimizations between normal control flow and landing pads/exception entry points.

Exceptions are a complex mechanism and noexcept greatly facilitates a compiler's life even in the even of zero-cost EH.


Edit: in the specific case of the noexcept specifier, if the compiler can't 'prove' that your code doesn't throw, a std::terminate EH is set up (with implementation-dependent details). In both cases (code doesn't throw and/or can't prove that the code doesn't throw) the mechanics involved are simpler and the compiler is less constrained. Anyway you don't really use noexcept for optimization reasons, it's also an important semantic indication.

  • +1 for the explanation. However, my question is about the optimizations allowed in the noexcept case which aren't possible in the throw() case. Scott Meyers' text attributes this to stack unwinding guarantees which a noexcept function needn't adhere to. Which part of the IR shown would be different? – Pradhan Sep 27 '14 at 23:53
  • it would be simpler because if the compiler can 'prove' that your code doesn't throw, there will be no exception handling. If it can't prove that, a std::terminate EH is set up. Anyway you don't really use noexcept for optimization reasons, it's more of a semantic indication. – Marco A. Sep 28 '14 at 0:14
1

I just made a benchmark, to measure the performance effect of adding a 'noexcept' specifier, for various test cases: https://github.com/N-Dekker/noexcept_benchmark It has a specific test case that could take advantage of the possibility to skip stack unwinding, with 'noexcept':

void recursive_func(recursion_data& data) noexcept // or no 'noexcept'!
{
  if (--data.number_of_func_calls_to_do > 0)
  {
    noexcept_benchmark::throw_exception_if(data.volatile_false);
    object_class stack_object(data.object_counter);
    recursive_func(data);
  }
}

https://github.com/N-Dekker/noexcept_benchmark/blob/v03/lib/stack_unwinding_test.cpp#L48

Looking at the benchmark results, it appears that both VS2017 x64 and GCC 5.4.0 yield a significant performance gain from adding 'noexcept', in this specific test case.

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