The ARM world is a bit messy.
For the C programmers, things are simple: all ARM architectures offer a regular, 32-bit with flat addressing programming model. As long as you stay with C source code, the only difference you may see is about endianness and performance. Most ARM processors (even old models) can be both big-endian and little-endian; the choice is then made by the logic board and the operating system. Good C code is endian neutral: it compiles and works correctly, regardless of the platform endianness (endian neutrality is good for reliability and maintainability, but also for performance: non-neutral code is code which accesses the same data through pointers of distinct sizes, and this wreaks havoc with the strict aliasing rules that the compiler uses to optimize code).
The situation is quite different if you consider binary compatibility (i.e. reusing code which has been compiled once):
- There are several instruction sets:
- the original ARM instruction set with a 26-bit program counter (very old, very unlikely to be encountered nowadays)
- the ARM instruction set with a 32-bit program counter (often called "ARM code")
- the Thumb instruction set (16-bit simplified opcodes)
- the Thumb-2 instruction set (Thumb with extensions)
A given processor may implement several instruction sets. The newest processor which knows only ARM code is the StrongARM, an ARMv4 representative which is already quite old (15 years). The ARM7TDMI (ARMv4T architecture) knows both ARM and Thumb, as do almost all subsequent ARM systems except the Cortex-M. ARM and Thumb code can be mixed together within the same application, as long as the proper glue is inserted where conventions change; this is called thumb interworking and can be handled automatically by the C compiler.
The Cortex-M0 knows only Thumb instructions. It knows a few extensions, because in "normal" ARM processors, the operating system must use ARM code (for handling interrupts); thus, the Cortex-M0 knows a few Thumb-for-OS things. This does not matter for application code.
The other Cortex-M know only Thumb-2. Thumb-2 is mostly backward compatible with Thumb, at least at assembly level.
- Some architectures add extra instructions.
Thus, if some code is compiled with a compiler switch telling that this is for an ARMv6, then the compiler may use one of the few instructions with the ARMv6 has but not the ARMv5. This is a common situation, encountered on almost all platforms: e.g., if you compile C code on a PC, with GCC, using the
-march=core2 flag, then the resulting binary may fail to run on an older Pentium processor.
- There are several call conventions.
The call convention is the set of rules which specify how functions exchange parameters and return values. The processor knows only of its registers, and has no notion of a stack. The call convention tells in which registers parameters go, and how they are encoded (e.g. if there is a
char parameter, it goes in the low 8 bits of a register, but is the caller supposed to clear/sign-extend the upper 24 bits, or not ?). It describes the stack structure and alignment. It normalizes alignment conditions and padding for structure fields.
There are two main conventions for ARM, called ATPCS (old) and AAPCS (new). They are quite different on the subject of floating point values. For integer parameters, they are mostly identical (but AAPCS requires a stricter stack alignment). Of course, conventions vary depending on the instruction set, and the presence of Thumb interworking.
In some cases, it is possible to have some binary code which conforms to both ATPCS and AAPCS, but that is not reliable and there is no warning on mismatch. So the bottom-line is: you cannot have true binary compatibility between systems which use distinct call conventions.
- There are optional coprocessors.
The ARM architecture can be extended with optional elements, which add their own instructions to the core instruction set. The FPU is such an optional coprocessor (and it is very rarely encountered in practice). Another coprocessor is NEON, a SIMD instruction set found on some of the newer ARM processors.
Code which uses a coprocessor will not run on a processor which does not feature that coprocessor, unless the operating system traps the corresponding opcodes and emulates the coprocessor in software (this is more or less what happens with floating-point arguments when using the ATPCS call convention, and it is slow).
To sum up, if you have C code, then recompile it. Do not try to reuse code compiled for another architecture or system.