On Wed, Dec 02, 2020 at 07:51:07PM +0100, Michal Hocko wrote:
On Wed 02-12-20 09:54:29, Minchan Kim wrote:
On Wed, Dec 02, 2020 at 05:48:34PM +0100, Michal Hocko wrote:
On Wed 02-12-20 08:15:49, Minchan Kim wrote:
On Wed, Dec 02, 2020 at 04:49:15PM +0100, Michal Hocko wrote:
[...]
Well, what I can see is that this new interface is an antipatern to our allocation routines. We tend to control allocations by gfp mask yet you are introducing a bool parameter to make something faster... What that really means is rather arbitrary. Would it make more sense to teach cma_alloc resp. alloc_contig_range to recognize GFP_NOWAIT, GFP_NORETRY resp. GFP_RETRY_MAYFAIL instead?
If we use cma_alloc, that interface requires "allocate one big memory chunk". IOW, return value is just struct page and expected that the page is a big contiguos memory. That means it couldn't have a hole in the range. However the idea here, what we asked is much smaller chunk rather than a big contiguous memory so we could skip some of pages if they are randomly pinned(long-term/short-term whatever) and search other pages in the CMA area to avoid long stall. Thus, it couldn't work with exising cma_alloc API with simple gfp_mak.
I really do not see that as something really alient to the cma_alloc interface. All you should care about, really, is what size of the object you want and how hard the system should try. If you have a problem with an internal implementation of CMA and how it chooses a range and deal with pinned pages then it should be addressed inside the CMA allocator. I suspect that you are effectivelly trying to workaround those problems by a side implementation with a slightly different API. Or maybe I still do not follow the actual problem.
I am not deeply familiar with the cma allocator so sorry for a potentially stupid question. Why does a bulk interface performs better than repeated calls to cma_alloc? Is this because a failure would help to move on to the next pfn range while a repeated call would have to deal with the same range?
Yub, true with other overheads(e.g., migration retrial, waiting writeback PCP/LRU draining IPI)
Why cannot this be implemented in the cma_alloc layer? I mean you can cache failed cases and optimize the proper pfn range search.
So do you suggest this?
enum cma_alloc_mode { CMA_ALLOC_NORMAL, CMA_ALLOC_FAIL_FAST, };
struct page *cma_alloc(struct cma *cma, size_t count, unsigned int align, enum cma_alloc_mode mode);
From now on, cma_alloc will keep last failed pfn and then start to
search from the next pfn for both CMA_ALLOC_NORMAL and CMA_ALLOC_FAIL_FAST if requested size from the cached pfn is okay within CMA area and then wraparound it couldn't find right pages from the cached pfn. Othewise, the cached pfn will reset to the zero so that it starts the search from the 0. I like the idea since it's general improvement, I think.
Yes something like that. There are more options to be clever here - e.g. track ranges etc. but I am not sure this is worth the complexity.
Agree. Just last pfn caching would be good enough as simple start.
Furthemore, With CMA_ALLOC_FAIL_FAST, it could avoid several overheads at the cost of sacrificing allocation success ratio like GFP_NORETRY.
I am still not sure a specific flag is a good interface. Really can this be gfp_mask instead?
I am not strong(even, I did it with GFP_NORETRY) but David wanted to have special mode and I agreed when he mentioned ALLOC_CONTIG_HARD as one of options in future(it would be hard to indicate that mode with gfp flags).
I think that would solve the issue with making the API more flexible. Before diving into it, I'd like to confirm we are on same page. Please correct me if I misunderstood.
I am not sure you are still thinking about a bulk interface.
No I am thinking of just using cma_alloc API with cached pfn as interal improvement and adding new fast fail mode to the API so driver could call the API repeatedly until then can get enough pages.