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In a visitor context, I need to temporarily set a variable before visiting children, and revert that variable afterward. I'm using the following code, but I'm sure there's a more elegant and proper way to do this:

template <typename TYPE> class TemporaryAssignment {
    TYPE& mVariable;
    TYPE mOriginalValue;
    TemporaryAssignment(TYPE& inVariable, TYPE inValue) 
        : mVariable(inVariable), mOriginalValue(inVariable) {
        mVariable = inValue;
    ~TemporaryAssignment(void) {
        mVariable = mOriginalValue;

This allows me to write something like the following:

    TemporaryAssignment<string> t(myVariable, myTemporaryValue);
// previous value of myVariable is restored

The variable will revert to its previous value when the temporary assignment object goes out of scope. What is a better way to do this?

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That seems optimal to me. What kind of answer do you anticipate? – wallyk Nov 14 '12 at 17:12
@wallyk, the usage is awkward. It would be nice to have the template type inferred automatically, and perhaps to write this more like an assignment, but I'm not sure how to pull that off without std::pair. As for anticipated answers, I half expect someone will point me toward a well-known pattern, or will point out possible pitfalls as Steve Jessop has done. – Neil Steiner Nov 14 '12 at 18:49

3 Answers 3

up vote 6 down vote accepted

Looks OK to me except that the destructor can throw, which is bad. swap with the original value instead of assigning (edit: this deals with std::string, but see the comments for possible problems with classes that are less user-friendly than string).

If you back off a little from this part of the code, perhaps you can find a way to not need to set a temporary value at all. Shared mutable state in an object can be bad for the same reason that mutable globals are bad, but to a lesser extent because it only messes up your class instead of messing up your whole program.

For example perhaps you could copy the whole object, set a new value for the variable and visit the copy instead of visiting yourself. Obviously that's not necessarily possible or efficient, you have to look for alternatives on a case by case basis. Maybe the copy can be shallow as far as the children are concerned (i.e. refer to the same child objects), that might be sufficient to make it cheap.

Regarding usage, you could deduce the type like this (untested code):

template <typename T, typename ARG>
TemporaryAssignment<T> temp_value(T &var, ARG &&newvalue) {
    return TemporaryAssignment(var, std::forward<ARG>(newValue));


auto t = temp_value(myVariable, myTemporaryValue);

Then you need a move constructor for TemporaryAssignment:

template <typename TYPE> class TemporaryAssignment {
    // change data member
    TYPE *mVariable;
    TYPE mOriginalValue;
    TemporaryAssignment(TYPE &inVariable, TYPE inValue) 
    : mVariable(&inVariable), mOriginalValue(std::move(inVariable)) {
        *mVariable = std::move(inValue);
    TemporaryAssignment(TemporaryAssignment &&rhs) {
        mOriginalValue = std::move(rhs.mOriginalValue);
        mVariable = rhs.mVariable;
        rhs.mVariable = 0;
    ~TypeAssignment() {
        using std::swap;
        if (mVariable) {
            swap(*mVariable, mOriginalValue);
    // can't remember whether this is needed
    TemporaryAssignment(const TemporaryAssignment &) = delete;
    TemporaryAssignment &operator=(const TemporaryAssignment &) = delete;
    TemporaryAssignment &operator=(TemporaryAssignment &&) = delete;

I thought a bit about specifying operator= for TemporaryAssignment so as to make the usage look like an assignment, but I didn't come up with anything good.

auto t = (temporary(myVariable) = myTemporaryValue);

is plausible, but you probably don't want TemporaryAssignment to have operator= defined because the meaning of:

t = otherTemporaryValue;

isn't necessarily clear and probably shouldn't be allowed. Maybe with a second class to be returned from temporary, and that returns TemporaryAssignment from its operator=.

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why it may throw? thanks – xiaoyi Nov 14 '12 at 17:14
Also, using swap or (C++11) move for the initial copies would be more efficient in some cases (e.g. string). – ecatmur Nov 14 '12 at 17:14
why would swap not throw? Doesn't it depend on the assignment and copy constructor? – japreiss Nov 14 '12 at 17:16
@xiaoyi: assignment copies the string, and to do that it (usually) allocates memory, which can fail. – Steve Jessop Nov 14 '12 at 17:16
@japriess: std::string has a swap member function which does not throw, and an overload of the free swap function that calls it. Other well-written classes will likewise provide a nothrow swap. But you have a point, if this template is supposed to work with badly-written classes for which there is no way to assign the old value back with a guarantee of success, then there's a problem here. Allowing the destructor to throw (and perhaps the program to terminate) might be the only way out. Catching and ignoring the failure is wrong, it doesn't restore the variable to the required state. – Steve Jessop Nov 14 '12 at 17:17

swap is not the best solution, because if TYPE has a std::string member, the crash problem might happen too. I think we can use some methods like this:

char buffer[sizeof(TYPE)];
memcpy(buffer, &mVariable, sizeof(TYPE));
memcpy(&mVariable, &mOriginalValue, sizeof(TYPE));
memcpy(&mOriginalValue, buffer, sizeof(TYPE));
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If this were a generally-valid way to swap two values of any type, then std::swap would use it. It isn't, but there are a lot of types that it will work for. Including some of the badly-written types for which swap can throw, but not necessarily including all of the well-written types for which swap cannot throw. – Steve Jessop Nov 15 '12 at 9:47
could you give me an example that this method will lead an error ??? – idy Nov 15 '12 at 14:43
struct Foo { int a; int *ptr_to_a; Foo() : a(0), ptr_to_a(&a) {}; Foo(const Foo &rhs) : a(rhs.a), ptr_to_a(&a) {}; Foo &operator=(const Foo &rhs) { a = rhs.a; }; ~Foo() { assert(&a == ptr_to_a); }. By copying this type with memcpy instead of operator=, you violate the class invariant that's asserted in the destructor. – Steve Jessop Nov 17 '12 at 3:11
For a slightly less pointless example, imagine a class that registers itself with some kind of central manager (which perhaps has an index from the value of a to a list of all objects currently holding that value, by pointer). It unregisters itself in its destructor, and updates its registration info when assigned, because its value of a has changed and so the lists need to be updated. If you copy with memcpy then the central register is not updated, and holds incorrect information, so the class won't work properly any more. memcpy breaks encapsulation that copy assignment enforces. – Steve Jessop Nov 17 '12 at 3:20

Adding on to the answer from Steve Jessop. From the RIIA (or RAII) point of view, your classes' destructor might end up acquiring resource(memory) where it should only be releasing resources. To avoid this, you could probably think of using a myVar which points to right object at the right time, so new objects could be rightly created only at construction or acquisition time and only delete and pointer re-assignment would happen at the time of release.

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