Static recompilation is a promising way of translating binaries from a foreign architecture to another target architecture. It would be faster than Just-In-Time (JIT), because it doesn't have to compile the code right before running, and because the extra compilation time it could take is useful to optimize the generate code.
However JIT compilation uses dynamic program analysis, while static recompilation relies on static program analysis (hence the name).
In static analysis, you don't have runtime information on an execution.
A major problem with this is posed by indirect jumps. The term covers code that might be generated from certain
switch statements, from the use of function pointers or from runtime polymorphism (think virtual table).
It all boils down to an instruction of the form:
Let's say you know the start address of your program, and you decided start to recompile instructions from this point. When you encounter a direct jump, you go to its target address, and you continue the recompilation from there. When you encounter an indirect jump though, you're stuck.
In this assembly instruction, the content of
reg_A is not known statically.
Therefore, we don't know the address of the next instruction. Note that in dynamic recompilation, we don't have this problem, because we emulate the virtual state of the registers, and we know the current content of
reg_A. Besides, in static recompilation, you are interested in finding all possible values for
reg_A at this point, because you want to have all possible paths compiled. In dynamic analysis, you only need the current value to generate the path that you're currently executing, should
reg_A change its value, you would still be able to generate the other paths.
In some cases, static analysis can find a list of candidates (if it is a
switch there must be a table of possible offset somewhere), but in the general case we simply don't know.
Fine, you say, let's recompile all instructions in the binary then!
The problem here is that in most binaries contain both code and data.
Depending on the architecture, you might not be able to tell which is which.
Worse, in some architectures there are no alignment constraints and variable width instructions, and you may start to dissassemble at some point, only to discover that you've started you recompilation with an offset.
Let's take a simplified instruction set comprising two instructions and a single register
41 xx (size 2): Add xx to `A`.
42 (size 1): Increment `A` by one.
Let's take the following binary program:
Let's say the start point is the first byte
41 42 (size 2): Add 42 to `A`.
But what if 41 is a piece of data? Then your program becomes:
42 (size 1): Increment `A` by one.
This problem is magnified in old games, which were often optimised directly in assembly, and where the programmer might intentionally expect some byte to be interpreted as both code and data, depending on the context!
Even worse, the recompiled program could be generating code itself! Imagine recompiling a JIT compiler. The result would still output code for the source architecture and try to jump to it, most likely causing the program to die very soon. Statically recompiling code that is only available at runtime requires infinite trickery!
Static binary analysis is a very live area of research (mainly in the field of security, to look for vulnerabilities in systems whose sources are not available), and actually I know of an attempt to produce a NES emulator that tries to statically recompile programs.
The article is very interesting.
A compromise between JIT and static recompilation would be to statically recompile as much code as possible, keeping only the bits that cannot be translated statically.