The answer to this question is context dependent. When you write for an operating system kernel, for example, the stack might be quite limited, and allocating more than a thousand bytes in a stack frame could cause a problem.
In modern consumer systems, the space available for the stack is typically quite large. One problem systems used to have was that address space was limited and, once the stack was assigned an address, it could not grow any further than the next object in the address space in the direction of stack growth, regardless of the availability of physical memory or of virtual memory elsewhere in the address space. This is less of a problem with today’s address spaces.
Commonly, megabytes of space can be allocated in a stack frame, and doing so is cheap and easy. However, if many routines that allocate large amounts of space are called, or one or a few routines that allocate large amounts of space are called recursively, then problems can occur because too much space is used, running into some limit (such as address space or physical memory).
Of course, running into a physical memory limit will not be alleviated by allocating space from the heap. So only the issue of consuming the address space available for the stack is relevant to the question of whether to use stack or heap.
A simple test for whether this is a problem is to insert use of a great deal of stack space in your
main routine. If you use additional stack space and your application still functions under a load that uses large amounts of stack space normally, then, when you remove this artificial reservation in
main, you will have plenty of margin.
A better way would be to calculate the maximum your program could use and compare that to the stack space available from the system. But that is rarely easy with today’s software.
If you are running into stack space limits, your linker or your operating system may have options to make more available.