Note: 32 bit application, which is not planned to be migrated to 64 bit.
I'm working with a very memory consuming application and have pretty much optimized all the relevant paths in respect to memory allocation/de-allocation. (there are no memory leaks, no handle leaks, no any other kind of leaks in the application itself AFAIK and tested. 3rd party libs which I cannot touch are of course candidates but unlikely in my scenario)
The application will frequently allocate large single and bi-dimensional dynamic arrays of single and packed records of up to 4 singles. By large I mean 5000x5000 of record(single,single,single,single) is normal. Also having even 6 or 7 such arrays in work at a given time. This is needed as there are a lot of cross-computations made on these arrays and having them read from disk would be a real performance killer.
Having this clarified, I am getting out of memory errors a lot because of these large dynamic arrays which will not go away after releasing them, no matter if I setlength them to 0 or finalize them. This is of course something FastMM is doing in order to be fast, I know that much.
I am tracking both FastMM allocated blocks and process consumed memory (RAM + PF) by using:
function CurrentProcessMemory(AWaitForConsistentRead:boolean): Cardinal; var MemCounters: TProcessMemoryCounters; LastRead:Cardinal; maxCnt:integer; begin result := 0;// stupid D2010 compiler warning maxCnt := 0; repeat Inc(maxCnt); // this is a stabilization loop; // in tight loops, the system doesn't get // much chance to release allocated resources, which in turn will get falsely // reported by this function as still being used, resulting in a false-positive // memory leak report in the application. // so we do a tight loop here, waiting, until the application reported memory // gets stable. LastRead := result; MemCounters.cb := SizeOf(MemCounters); if GetProcessMemoryInfo(GetCurrentProcess, @MemCounters, SizeOf(MemCounters)) then Result := MemCounters.WorkingSetSize + MemCounters.PagefileUsage else RaiseLastOSError; if AWaitForConsistentRead and (LastRead <> 0) and (abs(LastRead - result)>1024) then begin sleep(60); application.processmessages; end; until (not AWaitForConsistentRead) or (abs(LastRead - result)<1024) or (maxCnt>1000); // 60 seconds wait is a bit too much // so if the system is that "unstable", let's just forget it. end; function CurrentFastMMMemory:Cardinal; var mem:TMemoryManagerUsageSummary; begin GetMemoryManagerUsageSummary(mem); result := mem.AllocatedBytes + mem.OverheadBytes; end;
I am running the code on a 64bit computer and my top memory consumption before crashes is about 3.3 - 3.4 GB. After that, I get memory/resources related crashes anywhere in the application. Took me some time to pin it down on the large dynamic arrays usage which were buried down in some 3rd party library.
The way I am getting over this is that I made the application resume itself from where it left off, by re-starting itself and closing with certain parameters. This is all nice and dandy if memory consumption is fair and current operation finishes.
The big problem happens when the current memory usage is 1GB and the next operation to process requires 2.5 GB memory or more to be processed. My current code limited itself to an upper value of 1.5 GB used memory before resuming, but in this situation, I'd have to drop the limit down under 1 GB which would basically have the application resume itself after each operation and not even that guaranteeing that everything will be fine.
What if another operation will have a larger data set to process and it will require a total of 4GB or more memory?
To note that I am not talking about actual 4 GB in memory, but consumed memory by allocating huge dynamic arrays which the OS doesn't get back once de-allocated and hence it still sees it as consumed, so it adds up.
So, my next point of attack is to force fastmm to release all (or at least part of) memory to the OS. I'm specifically targeting the huge dynamic arrays here. Again, these are in a 3rd party library so re-coding that is not really in the top options. It's much easier and faster to tinker in the fastmm code and write a proc to release the memory.
I can't switch from FastMM as currently the entire application and some of the 3rd party libs are heavily coded around the use of PushAllocationGroup in order to quickly find and pinpoint any memory leaks. I know I can write a dummy FastMM unit to solve the compilation references, but I will be left without this quick and certain leak detection.
In conclusion: is there any way I can force FastMM to release at least some of it's large blocks to the OS? (well, sure there is, the actual question is: did anybody write it and if so, mind sharing?)
I will come up with a small relevant test application soon. It doesn't appear to be that easy to mock up one