I don't have specific experience with the arm. I do have experience (as a designer of embedded test coverage tools) of how to collect test coverage data in an embedded system.
You need the following:
- a tool which collects runtime test coverage data in a compact format, in a simple and easily located structure in your embedded system.
- Some additional space in your embedded system, sufficient to hold that runtime test coverage data. In some extremely space limited embedded systems, this can be an issue.
- An export mechanism, that can copy that data from the embedded system to a development system, at convenient moments.
- An import mechanism in the tool, that can accept such exported data
With these three elements in place, you can now collect test coverage data:
- Instrument you code based on the development system and compile it.
- Export the object file to the embedded system.
- Run your embedded application, executing tests by any means you see fit
- Export the coverage data to the development system
- Import into the test coverage tool to interpret results.
I can't speak for "bull eye", which does do some kind of instrumentation. Our Test Coverage tools cover a variety of languages (Java, C, C#, C++, many more) and have all the necessary properties (although I have trouble imagining an embedded PL/SQL application!).
Our tools store test coverage data as a dense block of tightly packed boolean byte/bit vectors (your choice for C and C++, byte vectors for other languages). This minimizes the extra storage demand on the embedded system. Should even this be too much, our tools will let you collect test coverage data on smaller parts of you application, and combine the results to give test coverage for the entire embedded application. You get to make multiple tests runs as a tradeoff but you at least can do it, and scripting can help ameliorate the tedium of the steps.
We don't dictate how the test coverage vectors (TCV) are exported from the embedded system, as that would limit which systems our tools could handle. We provide a "standard" export function that simply writes the block of vectors directly to a development system disk file; that export system is used unchanged when doing test coverage collection on the development system itself (as you have indicated you are already doing to some extent). The export function is added to, compiled/linked with the instrumented application to enable use. Normally it is called at program exit, but you can place calls to it at any convenient point in your application, including a point which is triggered by an outside event. The tool contains an interactive component that will read such files and construct summary reports as well as showing you interactively what code has been executed/not.
In an embedded context, you replace the export function with one of your own. It is only about 50 lines of code, so there's not much to replace. On most embedded systems there are available extra I/O ports (parallel output bits, serial ports, you name it); one codes a routine that sense the binary test coverage data to this output bit. Any embedded engineer can write a bit serializer or a send-byte-to-serial-port code block with little trouble. At this point, the test coverage data can be exported from the embedded system.
If your embedded system has a file system, then the changes to the code are trivial if not non-existent.
The last step is to capture this bit stream. This requires building a custom program running on the development system that reads some available hardware input (serial ports are easily found so this is popular) and regenerates the bit image of the test coverage data in memory. The default export function can be copied into the custom program with slight changes to move this data to a disk file. After this step, the test coverage interactive component can read the coverage data; it doesn't really care where it comes from.
So, with some customization of the export procedure, you can use our tools in pretty much arbitrary embedded contexts. (We had one customer use it to test microprocessors embedded in laptop batteries!). It takes about a day of a competent embedded engineer to fiddle the embedded version of the export function, and the development system resident part, and then you can collect test coverage to your heart's content.
This technique has been implemented by our customers with embedded systems with our C, C++, C#, and Java test coverage tools.