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Embedded software development has its own set of unique development challenges. What best practices have you found that work and what practices do not work so well?

For example,

I have found that:

  1. a well layered approach is essential for testing embedded systems. This allows some code to be unit tested on a more capable target such as a PC that would not easily be unit testable.
  2. automated continuous integration / testing on the embedded target is not likely worth the effort.
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10 Answers 10

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I've written code for 8-bit 20Mhz PIC processors and 32-bit 200Mhz ARM processors. Techniques differ depending on just how small the environment is. But assuming you're talking about teeny processors and writing C code, here's what I've found:

  1. Unit tests can run on the desktop, but be sure you're using explicit integer types (e.g. uint32_t, sint8_t) and not int and short. These will be defined differently on the desktop than in the embedded environment, so algorithms that might e.g. wrap when sizeof(int) == 2 but pass a unit test when sizeof(int) == 4.
  2. Unit tests cannot be overlooked. It's hard to use debuggers and loggers when you have real-time applications, so getting rid of little bugs is important.
  3. Never allocate memory. "Never" is extreme, but I've written code for 18 different embedded applications and never once had to use malloc(). No allocation means no memory leaks. Every limit should be in a #define so you can change your mind, but you'll be surprised how often you don't need strings to be "any number" of characters in length.
  4. Simple wins! Simple algorithms, going complex only if a profiler or similar dictates that you must. Simple architecture -- pointers and indirection and dynamic structures are extra slow in embedded environments.
  5. Profile. The littlest things can have a big effect. In one application we were getting only 12 k/s in a test where we transmitted a 1 MB file over the web server. Eliminating some unnecessary memcpy()s bought us 40 k/s, but then we discovered that the library implementation of memcpy() was "dumb" with things like word-aligned moves. After a little Internet research and a little assembly code, we sped up memcpy() so much that the test now ran at 140 k/s!
  6. Separation of concerns. Modules and encapsulation are always useful to some extent, but for embedded environments it works even better. You often know the complete set of ways and contexts that a piece of code will be used, so you really can test and document it thoroughly unlike with e.g. a Java class in a complex web-app with constantly changing requirements.
  7. Test modes. This can range from artificial tight loops where you do an operation as fast as possible or mock-inputs. Test modes allow you to run code millions of times over a weekend. This matters in embedded development because when you have to communicate with e.g. some microchip you can't test that with unit tests. Sure there's the spec, but there's line noise and hidden bugs and incorrect voltages and all sorts of things that can't be captured in unit tests. You just have to burn it in.
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" using explicit integer types"---I like this one, and it is very true. –  No Name Dec 20 '13 at 18:15
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We do some work with Atmel 8 bit AVR micros. We currently test all of the "business" logic with nunit and RhinoMocks including as part of a Cruise Control based continuous integration process.

  1. Create a C project that builds with WinAVR (and AVR Studio). This is partitioned into three logical components: The main driver, hardware compatibility layer and the common logic. The common logic or "business" logic is the bulk of the code and is designed to be tested.
  2. Create a C project in Visual Studio that includes the common component above and either a C++/CLI wrapper OR Win32 DLL. In the case of the C++/CLI wrapper, you get the managed component that can be tested with nunit. In the Win32 DLL -- you get something that can be P/Invoked from the tests.
  3. The common code should expose a function(s) that accepts function pointers that implement the hardware specific layers (essentially a IOC/DI mechanism).
  4. The native AVR driver (i.e., where main lives) initializes the common component to use the native hardware libraries (this includes things likes ports and other hardware specific things like "sleep").
  5. The nunit tests initialize the managed wrapper (C++/CLI or pinvokes to a DLL) with delegates that point to a managed implementation. This includes being able to use mocking tool like Rhino Mocks.

So we get unit tests, dependency injection, mocking, continuous integration all for an 8 bit micro.

Integration tests might use something the Phidgets products to drive the hardware as a black box. Importantly, if the unit tests and partitioning are done right this becomes a relatively small part of the development effort.

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Unit testing can't easily (or practically) be performed on the target, but integration testing can.

Vehicle ECUs require in system testing, and the project I'm working on at the moment is building a HIL (Hardware in the Loop) tester, with continuous integration and testing.

There are several USB I/O devices connected to the ECU, and a debugger. Software on the PC runs testing scripts which toggle real I/O, vary voltages and loads, and read inputs, take measurements, etc.

I'm working on having a system pull the commits down, recompile, reprogram the target, and run all the tests. The nature of the software requires a long test (lights remain on for so many seconds after the doors close, etc) so real continuous integration is unlikely, but a nightly test of all the latest commits is doable.

This would save vast amounts of time in debugging and hand testing - right now when a new baseline comes out everyone has to hand test their code. Many don't, and it may be several baselines later before the error is found, and then it must be tracked down.

This is on a 16 bit processor, but the principles and application are the same across the gamut, the difference is that people don't want to spend a lot of time and money on this sort of solution when there's only one hardware guy and one software guy doing the majority of the work, and the projects are small enough that a test by hand of all the features takes minutes instead of hours.

Further, it offers great traceability to the customer. Each test case has a list of requirements it tests. At the end of a regression test the program generates reams of HTML reports with all the requirements that passed and failed, graphs of the I/O for that test over the period of the test, etc.

So... Yeah, automated testing is usually not worth this level of effort for very small, limited projects, but if the setup and cost were low (ie, most of it is setup time and cost) then everyone would want to use it on every project just as much as they use unit testing on PC targeted programs.

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I was thinking about the small 8 bit microcontrollers where the differences are more apparent.

In an embedded system you have code which is tied tightly to the hardware and (hopefully) the rest of the code which is not tied to the hardware and instead using the abstracted hardware layer.

The code in the upper layer should architected such that it could be built on a build server with continuous integration / unit testing off target.

The hardware dependent code cannot be tested this way. I suppose it can be built via continuous integration targeting the hardware to verify the build is not broken. But you would need emulation to perform unit tests.

Hopefully, there is confidence in the hardware layer through manual testing and the code is re-usable from project to project. It helps if you do not switch platforms frequently.

Does anyone use emulation for automated testing or automated testing of code via a hardware test jig?

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I like Jason's answers, but I think eschewing automated testing as you proposed in your answer is a bad idea when the target environment becomes larger and more complex.

I think you have to really think about the size and complexity of individual embedded systems before coming to some conclusions about best practice.

Here's an interesting contrast, look at the system requirements for Windows 95

Compare those requirements with a modern smart phone such as Nokia n95, that'll have 128MB RAM (iirc), a ROM size of about 90MB. This is considered an embedded evironment too.

These are large systems, anyone not considering a high level of automated testing in these environments is probably going to develop some pretty low quality products.

So here's my answer: there's really very few good practices which can't be translated from non-embedded systems to the embedded environment Admittedly there maybe some significant effort to create these environments which for 'simple' systems may not be necessary.

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To expand on the OP examples, consider that an embedded system running on custom hardware often contains elements that are not present in a PC or smartphone application, such as control logic and direct hardware interfaces. To make fully automated tests might require the construction of a special test hardware rig, or the development of a simulator to recreate the embedded environment. In many cases this is impractical or unwarranted, perhaps requiring more development resources than the actual product.

In the case of a system that combines data processing with control and hardware, it is often helpful to separate the data processing into its own layer, so it can be recompiled for a PC platform where the full range of development tools and methods are available.

Another important practice in embedded programming is to learn about the mechanisms, strengths and weaknesses of the embedded hardware. Know the size and number of registers, the instruction set features, arithmetic operators in particular. (For example, many embedded processors have no floating point unit or integer divide instruction.) Be aware of how best to write code so the compiler can generate efficient instructions. Learn the speed of various types of memory accesses. When designing algorithms, prefer simplicity wherever possible; often in embedded systems the number of elements to be processed is guaranteed to be small, and almost everything is fast for small N. Usually the best algorithm is one that requires minimum constant space and so allows you to avoid allocating memory.

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When the hardware integration gets sufficiently complex in my experience it is worth going developing a automated test environment if the hw has the capacity. Most of the testing i've been involved with has been the regression testing of base port/board support package i.e. very h/w centric –  tonylo Sep 6 '08 at 23:11
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  • Know thy hardware

  • Know thy hardware API's

  • Use standard C libraries when you can

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@Jeff. I refined my original post. The answers here have been very interesting. To my mind it's not necessarily whether what you are doing is tied to the h/w or not it really depends on the complexity of the system being developed. I've worked on complex hardware integrations which involve 10-15 seperate device drivers, and multiple processors (ASSP/DSPs) involving complex power management schemes. On systems of this size it is definitely worth creating (or adapting if you're lucky) remote ROM image download and some sort of automated execution environment.

We use emulation to validate the functionality of more h/w agnostic components.

In these systems there are also some best practices you should try to get your h/w designers to adopt, specifically provide h/w with:

  1. the fastest simplest external debug comms possible
  2. a power control mechanism which can be remotely/automatically controlled
  3. anything which will facilitate automated rom download

Of course this very much depends on the type of environment you're working in.

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The best practices available and used are more interesting / challenging as we get to the smallest devices. It really changes the way we work. –  JeffV Sep 7 '08 at 1:55
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This thread is pretty old but I thought I would throw in that I disagree about not unit testing on the target. I develop a lot of applications for the NetBurner 5272. A 32 bit process with 2MB Ram and 8MB Flash and built-in ethernet and a web server. Now that's a pretty capable system so I realize what follows won't apply to a tiny 8 bit system with 16K of RAM. I was able to develop a unit testing framework that runs on the chip. After I finish writing code, hitting build, downloading and going to the unit test page takes under 30 seconds. I can then run my tests right on the platform. I usually write integration tests using this same framework so they too are only a button click away. I find one of the keys to being a productive embedded developer is the creation of well-tested reliable, reusable libraries.

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I propose using C macro-enabled run-time collection of run statistics for vital parts of the program. This way you'll get early warning if inept programmers are developing poor code. –  Olof Forshell Oct 27 '12 at 7:08
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Do the math. A modern 32-bit RISC MCU can roughly sustain one instruction per Hz of clock speed. A 50% CPU utilization safety margin halves this to one half instruction. Data coming in at 2 MBaud (200 K chars per second) must be efficiently collected, otherwise there won't be CPU capacity left to process it.

"Modern processors are so fast that we have all the capability we could ever need." "Modern compilers are so smart that they can do wonders with any source code." "The architecture breaks up the application into functions to aid understandability and performance." Dangerous misconceptions promoted by (probably) well-meaning individuals and listened to by decision makers hounded by budgetary constraints.

I would insert macro-enabled C code to continuously measure elapsed time in critical code. This way you both get early warning of inept code (produced by less-competent programmers) or inept SW architecture (produced by un-creative system architects).

Profiling a completed system is often a depressing experience regardless of whether it's on a web server ("who's going to tell the client he needs three times as many servers?"), a user PC or on an embedded system ("who tells the client he needs to reduce the raw data output from his radar array by two thirds AND relax his real-time requirements?"). What if performance issues had been identified early and been nipped in the bud?

Be wary of the "we'll fix it later" developers. The ones fitting the paraphrase (of an Oscar Wilde quote) "everyone speaks of performance but no one does anything about it." Or, as I would end it, "... nobody ever does the math."

Weed out less-competent programmers as soon as they're identified. A single individual can wreak more havoc than several competent ones can sort out.

Be prepared and don't be afraid to use assembly. Twenty to one hundred lines of tuned assembly in a few functions can often do wonders with a seemingly hopeless software application of any kind. A small investment in relation to the twenty to one hundred THOUSAND lines of variable-quality C code comprising the rest of the application. Coding guidelines usually prohibit inline assembly but say little or nothing about using pure assembly.

"Keep it simple" often works but if you're faced with a simple but slow algorithm and the alternative is a complex but fast algorithm it's a no-brainer.

Pro-crastinating on (or not taking seriously) performance issues has caused the downfall of numerous projects. "A stich in time saves nine."

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