If we're talking about doing this in an x86 environment it shouldn't be impossible. It should be used with caution though because x86 instructions are variable-length. A long instruction may overwrite the following instruction(s) and a shorter one will leave residual data from the overwritten instruction which should be noped (NOP instruction).
When the x86 first became protected the intel reference manuals recommended the following method for debugging access to XO (execute only) areas:
- create a new, empty selector ("high" part of far pointers)
- set its attributes to that of the XO area
- the new selector's access properties must be set RO DATA if you only want to look at what's in it
- if you want to modify the data the access properties must be set to RW DATA
So the answer to the problem is in the last step. The RW is necessary if you want to be able to insert the breakpoint instruction which is what debuggers do. More modern processors than the 80286 have internal debug registers to enable non-intrusive monitoring functionality which could result in a breakpoint being issued.
Windows made available the building blocks for doing this starting with Win16. They are probably still in place. I think Microsoft calls this class of pointer manipulation "thunking."
I once wrote a very fast 16-bit database engine in PL/M-86 for DOS. When Windows 3.1 arrived (running on 80386s) I ported it to the Win16 environment. I wanted to make use of the 32-bit memory available but there was no PL/M-32 available (or Win32 for that matter).
to solve the problem my program used thunking in the following way
- defined 32-bit far pointers (sel_16:offs_32) using structures
- allocated 32-bit data areas (<=> >64KB size) using global memory and received them in 16-bit far pointer (sel_16:offs_16) format
- filled in the data in the structures by copying the selector, then calculating the offset using 16-bit multiplication with 32-bit results.
- loaded the pointer/structure into es:ebx using the instruction size override prefix
- accessed the data using a combination of the instruction size and operand size prefixes
Once the mechanism was bug free it worked without a hitch. The largest memory areas my program used were 2304*2304 double precision which comes out to around 40MB. Even today, I would call this a "large" block of memory. In 1995 it was 30% of a typical SDRAM stick (128 MB PC100).