What are the implications of the voted in C++17 evaluation order guarantees (P0145) on typical C++ code?

What does it change about things like

f(i++, i)


std::cout << f() << f() << f() ;


up vote 47 down vote accepted

Some common cases where the evaluation order has so far been unspecified, are specified and valid with C++17. Some undefined behaviour is now instead unspecified.

What about things like

f(i++, i)

was undefined but is now unspecified.

std::cout << f() << f() << f() ;

Was unspecified, but will become compatible with operator precedence so that the first evaluation of f will come first in the stream. (examples below).


still has unspecified evaluation order of g, h, j. Note that for getf()(g(),h(),j()), the rules state that getf() will be evaluated before g,h,j.

Also note the following example from the proposal text:

 std::string s = "but I have heard it works even if you don't believe in it" 
 s.replace(0, 4, "").replace(s.find("even"), 4, "only")
  .replace(s.find(" don't"), 6, "");

The example comes from The C++ Programming Language, 4th edition, Stroustrup, and used to be unspecified behaviour, but with C++17 it will work as expected. There were similar issues with resumable functions (.then( . . . )).

As another example, consider the following:

#include <iostream>
#include <string>
#include <vector>
#include <cassert>

struct Speaker{
    int i =0;
    Speaker(std::vector<std::string> words) :words(words) {}
    std::vector<std::string> words;
    std::string operator()(){
        if(i==words.size()) i=0;
        // pre- C++17 version:
        auto word = words[i] + (i+1==words.size()?"\n":",");
        return word;
        // Still not possible with C++17:
        // return words[i++] + (i==words.size()?"\n":",");


int main() {
    auto spk = Speaker{{"All", "Work", "and", "no", "play"}};
    std::cout << spk() << spk() << spk() << spk() << spk() ;

With C++14 and before we may (and will) get results such as


instead of


Note that the above is in effect the same as

(((((std::cout << spk()) << spk()) << spk()) << spk()) << spk()) ;

But still, before C++17 there was no guarantee that the first calls would come first into the stream.

References: From the accepted proposal:

Postfix expressions are evaluated from left to right. This includes functions calls and member selection expressions.

Assignment expressions are evaluated from right to left. This includes compound assignments.

Operands to shift operators are evaluated from left to right. In summary, the following expressions are evaluated in the order a, then b, then c, then d:

  1. a.b
  2. a->b
  3. a->*b
  4. a(b1, b2, b3)
  5. b @= a
  6. a[b]
  7. a << b
  8. a >> b

Furthermore, we suggest the following additional rule: the order of evaluation of an expression involving an overloaded operator is determined by the order associated with the corresponding built-in operator, not the rules for function calls.

Edit note: My original answer misinterpreted a(b1, b2, b3). The order of b1, b2, b3 is still unspecified. (thank you @KABoissonneault, all commenters.)

However, (as @Yakk points out) and this is important: Even when b1, b2, b3 are non-trivial expressions, each of them are completely evaluated and tied to the respective function parameter before the other ones are started to be evaluated. The standard states this like this:

§5.2.2 - Function call

. . . The postfix-expression is sequenced before each expression in the expression-list and any default argument. Every value computation and side effect associated with the initialization of a parameter, and the initialization itself, is sequenced before every value computation and side effect associated with the initialization of any subsequent parameter.

However, one of these new sentences are missing from the github draft:

Every value computation and side effect associated with the initialization of a parameter, and the initialization itself, is sequenced before every value computation and side effect associated with the initialization of any subsequent parameter.

The example is there. It solves a decades-old problems (As explained by Herb Sutter) with exception safety where things like

f(std::unique_ptr<A> a, std::unique_ptr<B> b);


would leak if one of the calls get_raw_a() would throw before the other raw pointer was tied to it's smart pointer parameter. edit: as pointed out by T.C. the example is flawed since unique_ptr construction from raw pointer is explicit, preventing this from compiling.

Also note this classical question (tagged C, not C++):

int x=0;
x++ + ++x;

is still undefined.

  • 1
    "A second, subsidiary proposal replaces the evaluation order of function calls as follows: the function is evaluated before all its arguments, but any pair of arguments (from the argument list) is indeterminately sequenced; meaning that one is evaluated before the other but the order is not specified; it is guaranteed that the function is evaluated before the arguments. This reflects a suggestion made by some members of the Core Working Group." – Yakk - Adam Nevraumont Jul 21 '16 at 12:05
  • 1
    I'm getting that impression from the paper saying that "the following expressions are evaluated in the order a, then b, then c, then d" and then showing a(b1, b2, b3), suggesting that all b expressions are not necessarily evaluated in any order (otherwise, it would be a(b, c, d)) – KABoissonneault Jul 21 '16 at 12:14
  • 1
    @KABoissoneault, You are correct and I have updated the answer accordingly. Also, all: the quotes are form version 3, which is the voted in version as far as I understand. – Johan Lundberg Jul 21 '16 at 12:28
  • 2
    @JohanLundberg There is another thing from the paper that I believe is important. a(b1()(), b2()()) can order b1()() and b2()() in any order, but it cannot do b1() then b2()() then b1()(): it may no longer interleave their executions. In short, "8. ALTERNATE EVALUATION ORDER FOR FUNCTION CALLS" was part of the approved change. – Yakk - Adam Nevraumont Jul 21 '16 at 13:40
  • 2
    f(i++, i) was undefined. It's now unspecified. Stroustrup's string example was probably unspecified, not undefined. ` f(get_raw_a(),get_raw_a());` won't compile since the relevant unique_ptr constructor is explicit. Finally, x++ + ++x is undefined, period. – T.C. Jul 21 '16 at 17:26

Interleaving is prohibited in C++17

In C++14, the following was unsafe:

void foo(std::unique_ptr<A>, std::unique_ptr<B> );

foo(std::unique_ptr<A>(new A), std::unique_ptr<B>(new B));

There are four operations that happen here during the function call

  1. new A
  2. unique_ptr<A> constructor
  3. new B
  4. unique_ptr<B> constructor

The ordering of these was completely unspecified, and so a perfectly valid ordering is (1), (3), (2), (4). If this ordering was selected and (3) throws, then the memory from (1) leaks - we haven't run (2) yet, which would've prevented the leak.

In C++17, the new rules prohibit interleaving. From [intro.execution]:

For each function invocation F, for every evaluation A that occurs within F and every evaluation B that does not occur within F but is evaluated on the same thread and as part of the same signal handler (if any), either A is sequenced before B or B is sequenced before A.

There is a footnote to that sentence which reads:

In other words, function executions do not interleave with each other.

This leaves us with two valid orderings: (1), (2), (3), (4) or (3), (4), (1), (2). It is unspecified which ordering is taken, but both of these are safe. All the orderings where (1) (3) both happen before (2) and (4) are now prohibited.

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