On x86/64 if page translation enabled and the memory at virtual address 0 isn't accessible (because of the way physical memory is mapped into the virtual address space), 1 ... 4095 won't be accessible either because all these 4096 addresses correspond to a single page of memory and it can only be available or unavailable as a whole. It is a good idea to never map memory at virtual address 0. Not mapping it will help to catch many NULL pointer dereferences. The CPU here will generate a page fault (aka #PF) on unmapped locations or locations requiring higher privilege than the currently executing code.
In 64-bit mode the CPU may implement fewer (48+) than 64 virtual address bits and 64-bit addresses must contain either all zeroes or all ones in the bits that aren't implemented (the value, 0 or 1, must be the same as the value of the most significant implemented address bit, all of which can be interpreted as address sign-extension). Such addresses are called canonical. If you try to read or write memory using a non-canonical address, you'll get a general protection fault (AKA #GP).
So, depending on the OS (effectively, on its memory layout) and actual CPU you may come up with ranges of "invalid" memory addresses. If you try to read/write the kernel's memory from a user mode application, you'll get #PF. If you try to read/write unmapped memory (e.g. at address 0 through 4095), you'll get #PF. If you try to read/write at a non-canonical address, you'll get a #GP.
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