Wow. I love that story and I’m glad nobody was hurt.
I wonder whether that happened as a result of unexpected behavior by the pitching machine or an incorrect assumption about the pitching machine in that coworker’s tests.
I find this story compelling because it illustrates the points about managing risk and the limits of testing, but it doesn’t sound like the typical story that’s obviously hyperbole and could never happen to me.
It happened because the programmer changed the API from a call that accepted integer values between 0 and 32767 (minimum and maximum wheel speeds) to one that accepted float values between 0.0 and 1.0. A very reasonable change to make, but he quick-fixed all the compiler errors that this produced by casting the passed integer parameters all through his code to float and then clamping the values between 0.0 and 1.0. The result was that formerly low-speed parameters (like 5000 and 6000, for example, which should have produced something like a 20 mph ball with topspin) were instead cast and clamped to 1.0 - maximum speed on both throwing wheels and the aforesaid 125 mph knuckleball. He rewrote his tests to check that passed params were indeed between 0.0 and 1.0, which was pointless since all input was clamped to that range anyway. And there was no way to really test for a “dangerous” throw anyway since the machine was required to be capable of this sort of thing if that’s what the coach using it wanted.
Yikes! That’s also a great cautionary tale for Primitive Obsession/Whole Value as well as a bunch of other design principles.
I’m thinking about how I’d have done that refactoring and now I wish I had the code base to try it on. It sounds like it would make a really good real-life exercise in a workshop. “Remember folks, you have to get this right. There’s not really a way to check this with the real hardware, and if you get it wrong, someone’s going to get hurt.”
API from a call that accepted integer values between 0 and 32767 (minimum and maximum wheel speeds) to one that accepted float values between 0.0 and 1.0.
This would cause alarm bells to ring in my head for sure. If I did something like that I would make a new type that was definitely not implicitly castable to or from the old type. Definitely not a raw integer or float type.
Indeed, this is a time for naming conventions that communicate the details that the type system can’t clarify. This leads to the long names that senior programmers make fun of. Don’t listen to them; let them laugh then make this kind of mistake.
This leads to the long names that senior programmers make fun of.
Hum… The notation that I’ve seen people making fun of is one where the long names encode the exact same information that C types can handle for you and nothing else. But YMMV.
Anyway, I don’t think any naming convention can save you after somebody goes over your entire codebase converting things without care for the semantics. If you are lucky, it’s one of the lazy people that do that, and you will “only” have to revise tens of thousands of lines to fix it. If you are unlucky, the same person will helpfully adjust the names for you too.
Yes, any programmer who doesn’t care will do damage, but when I see durationInMilliseconds, I think more about what the int means than when I see merely “duration”. I don’t know how to help the people who read that and ignore it.
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Wow. I love that story and I’m glad nobody was hurt.
I wonder whether that happened as a result of unexpected behavior by the pitching machine or an incorrect assumption about the pitching machine in that coworker’s tests.
I find this story compelling because it illustrates the points about managing risk and the limits of testing, but it doesn’t sound like the typical story that’s obviously hyperbole and could never happen to me.
Thank you for sharing it.
It happened because the programmer changed the API from a call that accepted integer values between 0 and 32767 (minimum and maximum wheel speeds) to one that accepted float values between 0.0 and 1.0. A very reasonable change to make, but he quick-fixed all the compiler errors that this produced by casting the passed integer parameters all through his code to float and then clamping the values between 0.0 and 1.0. The result was that formerly low-speed parameters (like 5000 and 6000, for example, which should have produced something like a 20 mph ball with topspin) were instead cast and clamped to 1.0 - maximum speed on both throwing wheels and the aforesaid 125 mph knuckleball. He rewrote his tests to check that passed params were indeed between 0.0 and 1.0, which was pointless since all input was clamped to that range anyway. And there was no way to really test for a “dangerous” throw anyway since the machine was required to be capable of this sort of thing if that’s what the coach using it wanted.
Yikes! That’s also a great cautionary tale for Primitive Obsession/Whole Value as well as a bunch of other design principles.
I’m thinking about how I’d have done that refactoring and now I wish I had the code base to try it on. It sounds like it would make a really good real-life exercise in a workshop. “Remember folks, you have to get this right. There’s not really a way to check this with the real hardware, and if you get it wrong, someone’s going to get hurt.”
Thanks again.
Well, I have a rule now which is “never test your shit on Little Leaguers” and nobody I’ve worked with has any idea what that means.
I don’t think I’ll forget.
This is true Customer empathy.
This would cause alarm bells to ring in my head for sure. If I did something like that I would make a new type that was definitely not implicitly castable to or from the old type. Definitely not a raw integer or float type.
That kind of code usually is written on a restricted dialect of C.
C is not a language that allows for that kind of safety practice even on the fully-featured version.
Even in C this is possible. Just wrap the float or whatever in a struct and all implicit conversions will be gone.
Indeed, this is a time for naming conventions that communicate the details that the type system can’t clarify. This leads to the long names that senior programmers make fun of. Don’t listen to them; let them laugh then make this kind of mistake.
Hum… The notation that I’ve seen people making fun of is one where the long names encode the exact same information that C types can handle for you and nothing else. But YMMV.
Anyway, I don’t think any naming convention can save you after somebody goes over your entire codebase converting things without care for the semantics. If you are lucky, it’s one of the lazy people that do that, and you will “only” have to revise tens of thousands of lines to fix it. If you are unlucky, the same person will helpfully adjust the names for you too.
Yes, any programmer who doesn’t care will do damage, but when I see durationInMilliseconds, I think more about what the int means than when I see merely “duration”. I don’t know how to help the people who read that and ignore it.
The story of the 125 mph knuckleball might help.