>> 2. For the demotion path, a common case would be from high-performance memory, like HBM >> or Multi-Channel DRAM, to DRAM, then to PMEM, and finally to disks, right? More general >> case for demotion path would be derived from the memory performance description from HMAT[1], >> right? Do you have any algorithm to form such a path from HMAT? > > Yes, I have a PoC for the kernel setting up a demotion path based on > HMAT properties here: > > https://git.kernel.org/pub/scm/linux/kernel/git/kbusch/linux.git/commit/?h=mm-migrate&id=4d007659e1dd1b0dad49514348be4441fbe7cadb > > The above is just from an experimental branch. Got it. Thanks. > >> 3. Do you have a plan for promoting pages from lower-level memory to higher-level memory, >> like from PMEM to DRAM? Will this one-way demotion make all pages sink to PMEM and disk? > > Promoting previously demoted pages would require the application do > something to make that happen if you turn demotion on with this series. > Kernel auto-promotion is still being investigated, and it's a little > trickier than reclaim. > > If it sinks to disk, though, the next access behavior is the same as > before, without this series. This means, when demotion is on, the path for a page would be DRAM->PMEM->Disk->DRAM->PMEM->… . This could be a start point. I actually did something similar here for two-level heterogeneous memory structure: https://github.com/ysarch-lab/nimble_page_management_asplos_2019/blob/nimble_page_management_4_14_78/mm/memory_manage.c#L401. What I did basically was calling shrink_page_list() periodically, so pages will be separated in active and inactive lists. Then, pages in the _inactive_ list of fast memory (like DRAM) are migrated to slow memory (like PMEM) and pages in the _active_ list of slow memory are migrated to fast memory. It is kinda of abusing the existing page lists. :) My conclusion from that experiments is that you need high-throughput page migration mechanisms, like multi-threaded page migration, migrating a bunch of pages in a batch (https://github.com/ysarch-lab/nimble_page_management_asplos_2019/blob/nimble_page_management_4_14_78/mm/copy_page.c), and a new mechanism called exchange pages (https://github.com/ysarch-lab/nimble_page_management_asplos_2019/blob/nimble_page_management_4_14_78/mm/exchange.c), so that using page migration to manage multi-level memory systems becomes useful. Otherwise, the overheads (TLB shootdown and other kernel activities in the page migration process) of page migration may kill the benefit. Because the performance gap between DRAM and PMEM is supposed to be smaller than the one between DRAM and disk, the benefit of putting data in DRAM might not compensate the cost of migrating cold pages from DRAM to PMEM. Namely, directly putting data in PMEM after DRAM is full might be better. >> 4. In your patch 3, you created a new method migrate_demote_mapping() to migrate pages to >> other memory node, is there any problem of reusing existing migrate_pages() interface? > > Yes, we may not want to migrate everything in the shrink_page_list() > pages. We might want to keep a page, so we have to do those checks first. At > the point we know we want to attempt migration, the page is already > locked and not in a list, so it is just easier to directly invoke the > new __unmap_and_move_locked() that migrate_pages() eventually also calls. Right, I understand that you want to only migrate small pages to begin with. My question is why not using the existing migrate_pages() in your patch 3. Like: diff --git a/mm/vmscan.c b/mm/vmscan.c index a5ad0b35ab8e..0a0753af357f 100644 --- a/mm/vmscan.c +++ b/mm/vmscan.c @@ -1261,6 +1261,20 @@ static unsigned long shrink_page_list(struct list_head *page_list, ; /* try to reclaim the page below */ } + if (!PageCompound(page)) { + int next_nid = next_migration_node(page); + int err; + + if (next_nid != TERMINAL_NODE) { + LIST_HEAD(migrate_list); + list_add(&migrate_list, &page->lru); + err = migrate_pages(&migrate_list, alloc_new_node_page, NULL, + next_nid, MIGRATE_ASYNC, MR_DEMOTION); + if (err) + putback_movable_pages(&migrate_list); + } + } + /* * Anonymous process memory has backing store? * Try to allocate it some swap space here. Because your new migrate_demote_mapping() basically does the same thing as the code above. If you are not OK with the gfp flags in alloc_new_node_page(), you can just write your own alloc_new_node_page(). :) > >> 5. In addition, you only migrate base pages, is there any performance concern on migrating THPs? >> Is it too costly to migrate THPs? > > It was just easier to consider single pages first, so we let a THP split > if possible. I'm not sure of the cost in migrating THPs directly. AFAICT, when migrating the same amount of 2MB data, migrating a THP is much quick than migrating 512 4KB pages. Because you save 511 TLB shootdowns in THP migration and copying 2MB contiguous data achieves higher throughput than copying individual 4KB pages. But it highly depends on whether any subpage in a THP is hotter than others, so migrating a THP as a whole might hurt performance sometimes. Just some of my observation in my own experiments. -- Best Regards, Yan Zi