Problem: A large-scale simulation game has a ridiculous number of distinct objects which have to be tracked, updated, and used for both visual rendering and for logical model updating. With only 4 GB of address space, you can only fit so many things into memory. If you resort to disk, things start to slow down unless you get lucky and are constantly hitting the page cache. But even then, making a lot of updates/writes is going to be costly when the filesystem syncs to disk.
Let's assume the user has at least 32GB of RAM (a few have reported 64) and wants to play an enormous simulation, causing the model to carry around an order of magnitude more data than most of the stuff the game has been developed to handle. They of course have a 64-bit OS (let's say, Windows 7 x64 or Windows 8 x64). Naturally, if you just store all of this model data in virtual address space in-process, even with Large Address Aware you're going to run into an out of memory situation, even if the host has gigabytes and gigabytes of free RAM (because the 32-bit process is out of Virtual Address Space (VAS)).
Let's also assume that, for reasons entirely out of your control, you can't make the main binary 64-bit. You depend on some proprietary framework, have spent ridiculous man hours coding to that framework, and would have to start over from square one to move to something else. Your framework only ships a 32-bit version, so you're stuck.
I had a random thought, and it seems like a long shot, because I don't know if I could make it efficient or practical.
If I could create a child 64-bit process, it would be able to use, for all practical purposes, as much RAM as anyone today can afford to buy and slot into a motherboard, even on a very high-end server chassis.
Now, I want to be able to efficiently store and retrieve large chunks of data from the model that's been shoved into the child process, and get subsections of that data copied into the child process from time to time. So basically, the "main" model in all its gigabytes of glory (a series very huge tree-ish and hashtable-ish structures) will sit in the 64-bit process, and the 32-bit process will peek in there, grab a hunk of data, do stuff with it (or maybe I should ask the child process to do some processing in there to distill it down??), then get rid of it -- to keep the memory usage manageable in the 32-bit process.
All the model read/mutate/simulate algorithms are based around the assumption that the model is available locally in-process, so things like random array access are common. It would be hard for me to distill down my access patterns to a few chunk-based sequential reads from the main model, and a walk of the whole model isn't terribly uncommon either.
My goals are:
- Keep the darn thing from crashing due to out of memory (#1 goal)
- Performance (a very close #2, but people using an extreme amount of complexity may come to accept worse performance than those simulating a smaller, simpler game)
- Minimal refactoring of the existing code (more or less vanilla C++ with rendering calls and multithreading)
It seems like a pretty hefty project to even undertake, since going from a coherent memory model to having to essentially look through an aperture at a much larger model than I can grab at any one time will probably necessitate a lot of algorithm redesign.
- Is there any precedent for doing this?
- How would this best be done on Windows? Is there some kind of shared memory like on Linux, or lightweight very high-bandwidth random memory access IPC that can be integrated into C++ via something like an
- Is the performance of any IPC going to be so bad that it's not even worth trying? Should I just rely on the disk (you know, databases or key-value or whatever) and let the operating system / filesystem figure out how to use the RAM?
Keep in mind that I'd need support for an extremely "chatty" IPC mechanism, because a lot of the processing algorithms (AI, etc) are designed around small memory accesses and updates. This works well enough in-process, and there is even some attention towards cache locality, but all that turns weird when you are accessing it over IPC.