What made it hard to find? How did you track it down?
Not close enough to close but see also
What made it hard to find? How did you track it down?
Not close enough to close but see also
locked by Robert Harvey♦ Oct 5 '11 at 2:27
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closed as not constructive by Kev Aug 18 '11 at 22:24
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This requires knowing a bit of Z-8000 assembler, which I'll explain as we go.
I was working on an embedded system (in Z-8000 assembler). A different division of the company was building a different system on the same platform, and had written a library of functions, which I was also using on my project. The bug was that every time I called one function, the program crashed. I checked all my inputs; they were fine. It had to be a bug in the library -- except that the library had been used (and was working fine) in thousands of POS sites across the country.
Now, Z-8000 CPUs have 16 16-bit registers, R0, R1, R2 ...R15, which can also be addressed as 8 32-bit registers, named RR0, RR2, RR4..RR14 etc. The library was written from scratch, refactoring a bunch of older libraries. It was very clean and followed strict programming standards. At the start of each function, every register that would be used in the function was pushed onto the stack to preserve its value. Everything was neat & tidy -- they were perfect.
Nevertheless, I studied the assembler listing for the library, and I noticed something odd about that function --- At the start of the function, it had PUSH RR0 / PUSH RR2 and at the end to had POP RR2 / POP R0. Now, if you didn't follow that, it pushed 4 values on the stack at the start, but only removed 3 of them at the end. That's a recipe for disaster. There an unknown value on the top of the stack where return address needed to be. The function couldn't possibly work.
Except, may I remind you, that it WAS working. It was being called thousands of times a day on thousands of machines. It couldn't possibly NOT work.
After some time debugging (which wasn't easy in assembler on an embedded system with the tools of the mid-1980s), it would always crash on the return, because the bad value was sending it to a random address. Evidently I had to debug the working app, to figure out why it didn't fail.
Well, remember that the library was very good about preserving the values in the registers, so once you put a value into the register, it stayed there. R1 had 0000 in it. It would always have 0000 in it when that function was called. The bug therefore left 0000 on the stack. So when the function returned it would jump to address 0000, which just so happened to be a RET, which would pop the next value (the correct return address) off the stack, and jump to that. The data perfectly masked the bug.
Of course, in my app, I had a different value in R1, so it just crashed....
the toughest bug i ever had was not caused by me, although it caused my code to crash! this was TurboPascal on DOS. The TurboPascal compiler compiler had a minor upgrade and all of a sudden my binary started crashing. turned out that in the new version, memory was allocated starting on segment boundaries only. of course my program never checked for such things because why? how would a programmer know such things? someone on the old compuserve special interest groups posted this clue and the workaround:
since segments were 4 words long the fix was to always do a mod(4) to calculate the size of memory to allocate.
Mine was a hardware problem...
Back in the day, I used a DEC VaxStation with a big 21" CRT monitor. We moved to a lab in our new building, and installed two VaxStations in opposite corners of the room. Upon power-up,my monitor flickered like a disco (yeah, it was the 80's), but the other monitor didn't.
Okay, swap the monitors. The other monitor (now connected to my VaxStation) flickered, and my former monitor (moved across the room) didn't.
I remembered that CRT-based monitors were susceptable to magnetic fields. In fact, they were -very- susceptable to 60 Hz alternating magnetic fields. I immediately suspected that something in my work area was generating a 60 Hz alterating magnetic field.
At first, I suspected something in my work area. Unfortunately, the monitor still flickered, even when all other equipment was turned off and unplugged. At that point, I began to suspect something in the building.
To test this theory, we converted the VaxStation and its 85 lb monitor into a portable system. We placed the entire system on a rollaround cart, and connected it to a 100 foot orange construction extension cord. The plan was to use this setup as a portable field strength meter,in order to locate the offending piece of equipment.
Rolling the monitor around confused us totally. The monitor flickered in exactly one half of the room, but not the other side. The room was in the shape of a square, with doors in opposite corners, and the monitor flickered on one side of a diagnal line connecting the doors, but not on the other side. The room was surrounded on all four sides by hallways. We pushed the monitor out into the hallways, and the flickering stopped. In fact, we discovered that the flicker only occurred in one triangular-shaped half of the room, and nowhere else.
After a period of total confusion, I remembered that the room had a two-way ceiling lighting system, with light switches at each door. At that moment, I realized what was wrong.
I moved the monitor into the half of the room with the problem, and turned the ceiling lights off. The flicker stopped. When I turned the lights on, the flicker resumed. Turning the lights on or off from either light switch, turned the flicker on or off within half of the room.
The problem was caused by somebody cutting corners when they wired the ceiling lights. When wiring up a two-way switch on a lighting circuit, you run a pair of wires between the SPDT switch contacts, and a single wire from the common on one switch, through the lights, and over to the common on the other switch.
Normally, these wires are bundeled together. They leave as a group from one switchbox, run to the overhead ceiling fixture, and on to the other box. The key idea, is that all of the current-carrying wires are bundeled together.
When the building was wired, the single wire between the switches and the light was routed through the ceiling, but the wires travelling between the switches were routed through the walls.
If all of the wires ran close and parallel to each other, then the magnetic field generated by the current in one wire was cancelled out by the magnetic field generated by the equal and opposite current in a nearby wire. Unfortunately, the way that the lights were actually wired meant that one half of the room was basically inside a large, single-turn transformer primary. When the lights were on, the current flowed in a loop, and the poor monitor was basically sitting inside of a large electromagnet.
Moral of the story: The hot and neutral lines in your AC power wiring are next to each other for a good reason.
Now, all I had to do was to explain to management why they had to rewire part of their new building...
While testing some new functionality that I had recently added to a trading application, I happened to notice that the code to display the results of a certain type of trade would never work properly. After looking at the source control system, it was obvious that this bug had existed for at least a year, and I was amazed that none of the traders had ever spotted it.
After puzzling for a while and checking with a colleague, I fixed the bug and went on testing my new functionality. About 3 minutes later, my phone rang. On the other end of the line was an irate trader who complained that one of his trades wasn’t showing correctly.
Upon further investigation, I realized that the trader had been hit with the exact same bug I had noticed in the code 3 minutes earlier. This bug had been lying around for a year, just waiting for a developer to come along and spot it so that it could strike for real.
This is a good example of a type of bug known as a Schroedinbug. While most of us have heard about these peculiar entities, it is an eerie feeling when you actually encounter one in the wild.
I once had a bug in a .NET app that would cause the CLR to crash - yes the CLR would just exit with a non-zero result and there'd be no debug info.
I peppered the code with console trace messages trying to find out where the issue was (the error would occur at startup) and eventually found the few lines causing the problem. I tried isolating the issue but every time I did the isolated case would work!
In the end I changed the code from:
Don't ask me why, but this worked.
I fixes someone's bug with the code below :
He was expecting
I'm currently attending university and the hardest bug I encountered was from a programming class there. In the previous two semesters, we simply wrote all of our own code. But for the third semester, the professor and TA would write half the code, and we were to write the other half. This was to help us learn to read code.
Our first assignment for that semester was to write a program that simulates DNA gene splitting. Basically, we just had to find a substring in a larger one and process the results. Apparently, the professor and TA were both busy that week and gave us their half of the code without having their own full implementation finished yet. They hadn't had time to write the other half to act as a solution. Their half would compile, but without a full solution coded, there wasn't a way for them to test it. We were told not to alter the professors code. Everyone in the class had the exact same bug, but we all still assumed we were just all making the same mistake.
The program was gobbling gigabytes of memory and then running out and crashed. We (the students) all assumed that our half the code must have some obscure memory leak in it. Everyone in the class was scouring the code for two weeks and running it through a debugger over and over again. Our input file was a 5.7 MB string and we were finding hundreds of substrings in it and storing them. The professor/TA's code used this.
See the problem? When you assign a string variable to its own substring, the memory is not reallocated. That's a tidbit of information nobody (not even the professor or TA) knew. So myString had 5.7 MB of allocated memory only to hold a few bytes of actual data. This was repeated hundreds of times; thus the massive memory usage. I spent two weeks on this problem. I spent the first week checking my own code for memory leaks. In my frustration I finally concluded the professor/TA's half must have the leak, so I spent the second week checking their code. But even then, it took me so long to find because this wasn't technically a leak. All allocations were eventually being freed and the program worked fine when our input data was only a dozen kilobytes. The only reason I found it was because I sent psycho crazy and decided to analyze every single last variable; even the temporary throw-away stuff. I was also spending a lot of time checking how many chars the string actually had, not how much was allocated. I assumed the string class was taking care of this. Here was the solution, a one line change that fixed weeks of frustrated and earned me an A on the assignment for finding/fixing the teacher's code.
The swap method, does force a reallocation.
We had a problem where our users would timeout for apparently no reason. I monitored the SQL Server for a while and found that every once in a while there would be a lot of blocking going on. So I need to find the cause of this and fix it.
If there was blocking going on, than there must have been exclusive locks somewhere in the chain of stored proc calls…. Right?
I walked thru the full list of stored procs that were called, and all of the subsequent stored procs, functions and views. Sometimes this hierarchy was deep and even recursive.
I was looking for any UPDATE or INSERT statements…. There weren’t any (except on temporary tables that only had the scope of the stored proc so they didn’t count.)
On further research I found the locking is caused by the following:
A. If you use a SELECT INTO to create your temp table then SQL Sever places locks on system objects. The following was in our getUserPrivileges proc:
The getUserPrivileges proc is called with every page request (it is in the base pages.) It was not cached like you might expect. It doesn’t look like it, but the SQL above references 23 tables in the FROM or JOIN clauses. None of these table have the “with(nolock)” hint on it so it is taking longer than it should. If I remove the WHERE clause to get an idea of the number of rows involved it returns 159,710 rows and takes 3 to 5 seconds to run (after hours with no one else on the server.)
So if this stored proc can only be run one-at-a-time because of the lock, and it is being called once per page, and it holds the locks on the system tables for the duration of the select and temp table creation, you can see how it might be affecting the performance of the whole application.
The fix for this would be: 1. Use session level caching so this is only called once per session. 2. Replace the SELECT INTO with code that creates the table using standard Transact-SQL DDL statements, and then use INSERT INTO to populate the table. 3. Put “with(nolock)” on everything involved with this call.
B. If the stored proc getUserPrivileges didn’t have enough problems for you, then let me add: it probably gets recompiled on each call. So SQL Server acquires a COMPILE lock on each call.
The reason it gets recompiled is because the temp table gets created and then a lot of rows are deleted from it (if a @locationId or @permissionLocationId are passed in). This will cause the stored proc to be recompiled on the SELECT that follows (yes, in the middle of running the stored proc.) In other procs I’ve noticed a DECLARE CURSOR statement whose SELECT statement references a temporary table – this will force a recompile too.
For more info on recompilation see: http://support.microsoft.com/kb/243586/en-us
The fix for this would be: 1. Again, hit this stored proc far fewer times by using caching. 2. Have the @locationId or @permissionLocationId filtering applied in the WHERE clause while the table is being created. 3. Replace the temp tables with table variables – they result in fewer recompilations.
If things don’t work like you expect them to then you can spend a lot of time staring at something without every figuring out what is wrong.
The toughest bugs I ever fixed actually came quite early in my career. I was working on a real-time system for a power station that used pairs of GEC 2050 computers with shared memory.
2050 RTOS had a main scheduling table which consisted of one slot per process, the contents of which were either an add 1,X instruction for an inactive process or a jump for an executable process. Executing this table with X set to zero meant that the first runnable process automatically got entered with the X register being the process number. Whoever designed this obviously felt he was being very clever!
The 2050 architecture also had a security feature where an unrecognised opcode always caused a halt. Since the 2050 had a full-blown front panel, you could then use that to try and work out what had crashed. Since the X register always held the current process ID, this was usually fairly straight-forward.
There was no memory segmentation or protection, so it was perfectly possible for a process to corrupt either any other process currently in memory or indeed anything in the system area.
So far so consistent for the era (late 70s).
Since this particular system had shared memory between the two CPUs, the system configuration placed the system tables in the shared memory, to allow one CPU to start and stop processes in the other without having to go through any namby pamby secure interface.
Unfortunately this also allowed one CPU's wild process to corrupt the tables for the other CPU, so one CPU could happily crash the other. If this happened, what was running in the crashed CPU bore no relationship at all to the actual fault. Meanwhile the other CPU had happily carried on so there was no way to tell if it had caused the problem.
Needless to say, this provided a few hard to fix issues!
After a little bit of hair tearing, I ended up writing a fairly substantial patch to the O/S which looked for corruption in the scheduler table for the other CPU and crashed the CPU it was running on. This was hooked into a regular interrupt so while not being perfectly synchronised, at least it had a good chance of catching the offending process.
This helped me clear up quite a few mutual-CPU issues...
We had an RMI server running on a DOS prompt Someone "selected" the window - which paused the process
The fix was quite simple...press enter.
It was quite an agonizing day...
A legacy database based application (with only part of the source avaliable) crashed when one particular user accessed a certain inventory feature. It worked perfectly for all other users. The user profile right? Nope. When logging in as a different user (even as admin) the same user had the same problem.
Computer problem? Nope. Same user, different PC (under her login or any other login) still crashed.
The problem: when logging in the program displayed a copyright splash screen that could be closed either by clicking the "X" to close the window, or by pressing any key. When logging in this user always clicked the "X" where other users always pressed a key. This resulted in a memory leak that caused but only when the inventory lookup was accessed.
Fix: Don't click the X.
A box had crashed at a big customer's site, and we had to connect via a WebX session to an IT guy's computer, which was connected to our box. I poked around for about an hour, grabbing stack traces, register dumps, statistics, counters, and dumping sections of memory that seemed relevant.
Their IT guys then emailed me a transcript of my session, and I got to work.
After a few hours, I'd traced it back to an array of structures which contained packet metadata followed by packet data. One of the packet's metadata was corrupt, and it looked like it had been overwritten by a few bytes of packet data. Bugzilla had no record of anything similar.
Delving into the code, I checked all the obvious things. The code that copied packet data into the buffer was meticulous about not exceeding its bounds: the buffer was the MTU size for the interface, and the copy routine checked that the data didn't exceed the MTU size. My memory dumps allowed me to validate that, yes, foo->bar was indeed 4 when the crash happened. Nothing added up. Nothing was wrong in a way that should have caused the problem. There were what looked like 16 bytes of packet data in the next header.
A couple days later, I started checking anything and everything that I could think of.
I noticed that the length of the data buffer was actually correct. That is, the number of bytes from start of data until end of data was an MTU, even though the next header started at MTU-16.
When these structs were malloc'd, pointers to each element were placed in an array, and I'd dumped that array. I started measuring distance between these pointers. 6888... 6888... 6888... 6872... 6904... 6880... 6880...
I started looking at the internal pointers and offsets in both structures. Everything added up. It just looked like my one bad structure - the one that'd been partially clobbered - was just 16 bytes too soon in memory.
The allocation routine malloc'd these guys as a chunk, and then carved them up in a loop:
(with allowances for alignment, etc.).
When the array was filled the value for my corrupt pointer must have been read as 0x8a112**8**ac instead of 0x8a112**9**ac.
I came to the conclusion that I'd been the victim of a 1-bit memory error during allocation (I know, I know! I didn't believe it either, but we'd seen them before on this hardware -- NULL values that were read as 0x00800000). In any case, I managed to convince my boss and co-workers that there was no other reasonable explanation, and that my explanation exactly explained what we were seeing.
So, box RMA'd.
might seem funny but when i was learing i spent an entire afternoon trying to figure out why an if statment always evaluate to true i used = instead of == :d i ve rewritten everything twice on an other computer :)
A Heisenbug where the main difficulty was not realizing it wasn't my bug at all.
The problem was an API interface. Calling any real function (as opposed to the setup stuff) had a very high probability of crashing with a protection violation. Single-stepping through the function (to the extent possible, it would hit an interrupt and you couldn't trace past that point--this was back when you used interrupts to talk to the system) produced the correct output, no crash.
After a long search in vain for what I was doing wrong I finally dug through the RTL routines to try to understand what I was doing wrong. What I was doing wrong was believing the routines worked--all the routines that bombed were manipulating a real-mode pointer with a protected-mode pointer type. Unless the real-mode segment value happened to be valid in protected mode this went boom.
However, something about the debugger's manipulation of the program caused correct operation while single-stepping, I never bothered to figure out why.
Years ago I spent several days trying to track down and fix a small bug in dbx, the text-based debugger on AIX. I don't remember the exact bug. What made it tough was I was using the installed dbx to debug the dev version of dbx I was working on. It was very tough to keep track of where I was. More than once, I prepared to leave for the day and exited dbx twice (the dev version and the installed version) only to see that I was still running inside dbx, sometimes two or more levels "deep".
A crash happening in a DLL, loaded from a service. Triggered by shutting the system down.
The bug was simple to fix, but it took about a week - and a lot of frustration - to locate.
In Python, I had a thread doing something like this:
It's because the thread was doing the pause while maintaining the mutex. Thus it rarely let other threads acquire the mutex. It may seem obvious here, but I took me two days to figure it out. The solution is simply to remove an indent level:
A race between Oracle's OracleDecimal class's ToString method (which P/Invokes the native version of the same functionality) and the garbage collector caused by a missing GC.KeepAlive call which can cause OracleDecimal.ToString() to return essentially arbitrary junk if its heap space happens to be overwritten before the call finishes.
I wrote a detailed bug report and never heard back, for all I know this is still out there. I even had a test harness that did nothing but create new OracleDecimal representations of the number 1, call ToString on them, and compare the result with "1". It would fail every ten-millionth time or so with crazy gibberish (huge numbers, negative numbers, and even alphanumeric junk strings).
Be careful out there with your P/Invoke calls! It is legal for the .NET garbage collector to collect your instance while a call to an instance method on that instance is still pending, as long as the instance method has finished using the
Reflector is an absolute lifesaver for stuff like this.
The toughest bug would have to be when a programmer output to a log "General Error!". After looking through the code, it was scattered everywhere with the text "General Error!". Try nailing that one down.
At least writing a macro to output __LINE__ or __FUNCTION__ would have been a little more helpful to add to the debug output.
It was during my diploma thesis. I was writing a program to simulate the effect of high intensity laser on a helium atom using FORTRAN.
One test run worked like this:
These should be constant in total, but they weren't. They did all kinds of weird things.
After debugging for two weeks I went berserk on the logging and logged every variable in every step of the simulation including the constants.
That way I found out that I wrote over an end of an array, which changed a constant!
A friend said he once changed the literal 2 with such a mistake.
A deadlock in a Java Server Application. But not a simple deadlock with two threads. I tracked down a deadlock involving eight threads. Thread 1 waits for thread 2 that waits for thread 3, etc, and finally thread 8 waits for thread 1.
It took me about one entire day to understand what was going on and then just 15 minutes to fix it. I use eclipse to monitor about 40 threads till I discovered the deadlock.
In CS435 back at Purdue, we had to write a raytracer for our final project. Everything mine produced had a strong orange tint to it, but I could see every one of the objects in my scene. I finally gave up and submitted it as is, and had the professor look over my code to find the bug, and when he couldn't find it, I spent most of the summer digging to find just what the hell was wrong.
Buried deep in the code, as part of a color calculation function, I finally realized I was dividing an int and passing it to an OpenGL function that expected a float value. One of the color components was just low enough throughout most of the scene that it would round down to 0, causing the orange tint. Casting it to a float in just one place (before the division) fixed the bug.
Always check your inputs and expected types.
I had a bug with a custom synchronization program once. It used the date/time stamp of files/folders to compare what was modified to synchronize data from a flash key to a network share in windows, with some extra integrity and business logic built in it.
One day, an operator reported that his sync was taking forever...after reviewing the logs, for some reason, the software thought every file on the stick (or the server) was 3 hours older than it should be, refreshing all 8 gigs of data! I was using UTC, how the heck could this be?
It turns out, this particular operator did indeed set his time zone to Pacific time instead of Eastern, causing the problem, but it shouldn't have, because all the code was using UTC - good god what could it be?! It worked when testing it on my local system...what gives?
At this point, we requested all operators ensure that their laptops were set to eastern time before they synced, and the bug stayed in the queue until we had more time to investigate.
Then, October came around and BOOM! Daylight savings time! What the heck!? Now everyone was complaining syncing was taking forever! Had to be fixed, and fast!
I tracked it down by modifying the test case to run off a stick instead of off my local hard drive, and sure enough, it failed...phew, must a a memory stick thing - wait a sec, is it formatted FAT32... AH HA! FAT32 uses localtime when recording the timestamp of a file!
So, the software was rewritten so that when writing to FAT32 media, we programatically set it to UTC...
DevExpress XPO talking to an Oracle database crashing hard (as in: program exits silently) if directory path that the application is installed to does not contain at least one space, and the data dictionary XPO checks for isn't 100% correctly cased in the database.
Problem described here.
I can tell you this: I was this >< close to crying when we figured out how to circumvent the problem. I still don't know what the actual, real, cause of the problem is, but our product is not going to support Oracle in future version so I'm actually not giving a .... any more.
I work for a large community college and we switched over from Blackboard to Moodle last year. Moodle uses the nomenclature of "courses" and "groups". A course might be Microeconomics ECO-150, for example, and groups are what we would call sections (OL1, OL2, 01, 14, W09 as examples).
Anyway we are primitive. We don't even have LDAP. Everything is text files, excel spreadsheets and GD microsoft Access databases. My job is to create a web application that takes all of the above as input and produces still more text files than can then be uploaded into Moodle to create courses, groups in courses and users and put users into courses and groups. The whole setup is positively byzantine, with about 17 individual steps that must be done in order. But the thing works and replaces a process that previously took days during the busiest time of the semester.
But there was one problem. Sometimes we got what I dubbed "Crazy Groups". So instead of creating a course with 4 groups of 20 students each it would create a course with 80 groups of 1 student each. The worst part, there is no way programmatically short of getting into cpanel(which I don't have access to) to delete a group once it is created. It is a manual process that takes about 5 button clicks. So every time a course with Crazy Groups got created I either had to delete the course, which is preferable but not an option if the teacher had already started putting content in the course, or I had to spend an hour repetitively following the same pattern: Select group, display group, edit group, delete group, Are you sure you want to delete group? Yes for godsake!
And there was no way to know if crazy groups had occured unless you manually opened up each course and looked (with hundreds of courses) or until you got a complaint. Crazy Groups seemed to happen randomly and Google and the Moodle forums were no help, it seems everyone else uses this thing called LDAP or a REAL database so they've never encountered the problem.
Finally, after I don't know how much investigating and more time deleting crazy groups than I ever want to admit I figured it out. It was a bug in Moodle not my code! This gave me not a little pleasure. You see the way to create a group is just try to enroll someone into the group and if the group does not already exist then Moodle creates it. And this worked fine for groups named OL1 or W12 or even SugarCandyMountain but if you tried to create a group with a number as the name, say 01 or 14 THAT is when crazy groups would occur. Moodle does not properly compare numbers as strings. No matter how many groups named 01 inside a course there are it will always think that group does not exist yet and will therefore create it. That is how you end up with 80 groups with 1 person in each.
Proud of my discovery I went to the Moodle forum and posted my findings complete with steps to reproduce the problem at will. That was about a year ago and the problem still exists inside of Moodle to my knowledge, no one seems motivated to fix it because no one but us primitives uses the text file enrollment. My solution, simply to make sure that all our group names contained at least 1 non-numeric character. Crazy groups are gone forever at least for us but I feel for that guy who works at a community college in outer Mongolia who just uploaded a semester's worth of courses and is about to have a rude awakening. At least this time Google may help him because I've written him this message in a bottle on the tides of cyberspace.
I heard about a classic bug back in high school; a terminal that you could only log into if you sat in the chair in front of it. (It would reject your password if you were standing.)
It reproduced pretty reliably for most people; you could sit in the chair, log in, log out... but if you stand up, you're denied, every time.
Eventually it turned out some jerk had swapped a couple of adjacent keys on the keyboard, E/R and C/V IIRC, and when you sat down, you touch-typed and got in, but when you stood, you had to hunt 'n peck, so you looked at the incorrent labels and failed.
I had a piece of delphi code that ran a long processing routine updating a progress bar as it went. The code ran fine in 16bit Delphi 1 however when we upgraded to delphi 2 a process that was taking 2 minutes suddenly took about an hour.
After weeks of pulling the routine apart it turns out it was the line that updated the progress bar that caused the issue, for every itteration we were checking the record count using table1.recordcount, in delphi 1 this worked fine but it seems in later versions of delphi calling table.recordcount on a dbase table takes a copy of the table counts the records and returns the amount, calling this on every itteration of our progress was causing the table to be downloaded from the network with every ittteration and counted. The solution was to count the records before the processing started and stored the amount in a variable.
Took ages to find but turned out to be so simple.
I can't imagine how did they code this: You can't assign IP address 127.0.0.1 to the loopback adapter, because it is a reserved address for loopback devices --Microsoft(r) WindowsXP PROFESSIONAL
I diffed the (cleaned up) logfile of a working run against a breaking run, to see at what point they first started to diverge. By re-running and adding lots of breakpoints, I found my way to the chain of events that lead up to the failure. Somewhere in there was a line of code that, if written slightly differently, solved the problem! (It was something very simple, like nextNode() should return null instead of IndexOutOfBounds.)
Two weeks after that I realised my fix broke scripts in certain other situations, and I changed the line to work well for all the cases.
I was in an unfamiliar environment. So I just tried a lot of different things, until one of them worked, or at least helped to make some progress/understanding. It did take a while, but I was pleased to get there in the end!
If I was doing it again now, I would look for the project's IRC channel (not only its mailing list), to ask a few polite questions and seek pointers.
In a game I was working on, a particular sprite would not display anymore in Release mode, but worked fine in Debug mode, and only in one particular edition. Another programmer tried to find this bug for 2 days, then left for vacation. It ended up on my shoulders to try to find the bug ~5 hours before release.
Since the Debug build worked, I had to debug with the release build. Visual Studio supports some debugging in the Release build, but you can't rely on everything the debugger tells you to be correct (especially with the aggressive optimization settings we were using). Therefore, I had to step through half code listings and half assembler listings, sometimes looking at objects directly in the hex dump instead of in the nicely formatted debugger view.
After spending a while making sure that all the correct draw calls were being made, I found out that the material color of the sprite was incorrect - it was supposed to be full opacity orange, but instead was set to black and completely transparent. The color was grabbed from a palette residing in a const array in our EditionManager class. It was setup initially as the correct orange color, but when the actual color was retrieved from the sprite drawing code, it was that transparent black again. I set a memory breakpoint, which was triggered in the EditionManager constructor. A write to a different array caused the value in the palette array to change.
As it turns out, the other programmer changed an essential enum of the system: