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I know that local arrays are created on the stack, and have automatic storage duration, since they are destroyed when the function they're in ends. They necessarily have a fixed size:

{
   int foo[16];
}

Arrays created with operator new[] have dynamic storage duration and are stored on the heap. They can have varying sizes.

{
    const int size = 16;
    int* foo = new int[size];
    // do something with foo
    delete[] foo;
}

The size of the stack is fixed and limited for every process.

My question is: Is there a rule of thumb when to switch from stack memory to heap memory, in order to reduce the stack memory consumption?

Example:

  • double a[2] is perfectly reasoable;
  • double a[1000000000] will most likely result in a stack overflow, if the stack size is 1mb

Where is a reasonable limit to switch to dynamic allocation?

  • Very close to this question and my answer there – Basile Starynkevitch Feb 28 '18 at 12:40
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    Rule of thumb: if it fits on the stack, allocated them on the stack (local variable), if it's too big to fit on the stack, allocate dynamically. – Jabberwocky Feb 28 '18 at 12:41
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    First of all I would rather recommend std::array instead of plain arrays, or std::vector instead of your own dynamic allocation. Then as for the "break point" where one should start using std::vector instead of std::array, that really depends on the use-case. The "rule of thumb" is that the element counter is "small enough", but how small that "small enough" is, is not something that can be generally advised. – Some programmer dude Feb 28 '18 at 12:43
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    For stack-allocated array, you need to know its size at compile time. In practice, size of data structures is usually not known until runtime. (Small buffer optimization can be of your interest if you want to dig deeper into the problem.) – Daniel says reinstate Monica Feb 28 '18 at 12:48
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See this answer for a discussion about heap allocation.

Where is a reasonable limit to switch to dynamic allocation?

In several cases, including:

  • too large automatic variables. As a rule of thumb, I recommend avoiding call frames of more than a few kilobytes (and a call stack of more than a megabytes). That limit might be increased if you are sure that your function is not usable recursively. On many small embedded systems, the stack is much more limited (e.g. to a few kilobytes) so you need to limit even more each call frame (e.g. to only a hundred bytes). BTW, on some systems, you can increase the call stack limit much more (perhaps to several gigabytes), but this is also a sysadmin issue.

  • non LIFO allocation discipline, which happens quite often.

Notice that most C++ standard containers allocate their data in the heap, even if the container is on the stack. For example, an automatic variable of vector type, e.g. a local std::vector<double> autovec; has its data heap allocated (and released when the vector is destroyed). Read more about RAII.

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