exec call replaces the child's entire address space with a whole new address space. Any shared address space would be replaced completely by the call.
vfork function exists only as an optimization. For some operating systems,
fork is very expensive because the child process could potentially modify any page mapped into memory, so every single page must be modified to copy on write (or, originally, actually copied!) so as not to modify the parent's corresponding pages. A very common sequence is
fork followed immediately by
exec, forcing these systems to remap all the pages just to throw them all away a split second later. Rather than going to the trouble of modifying all the mappings,
vfork allows you to leave the mappings in an undefined state in the child process under the assumption that you're not going to use them anyway.
As a result, doing certain things after a
vfork can create a mess. But as soon as you call
exec, all the undefined mappings are gone anyway.
In practice, operating systems handle
vfork one of two ways: For operating systems where changing all mappings to copy on write is inexpensive or that haven't implemented
vfork is identical to
fork. For operating systems that do use
vfork leaves the parent and child fully sharing most pages, causing bad things to happen if the child modifies them (they modify in the parent).
So the short answer to your question is that if
vfork was designed that way, it wouldn't be usable for its sole intended purpose.