On Tue, Jan 11, 2022 at 04:32:56AM +0000, Matthew Wilcox wrote: > On Mon, Jan 10, 2022 at 08:41:26PM -0400, Jason Gunthorpe wrote: > > On Mon, Jan 10, 2022 at 07:34:49PM +0000, Matthew Wilcox wrote: > > > > > Finally, it may be possible to stop using scatterlist to describe the > > > input to the DMA-mapping operation. We may be able to get struct > > > scatterlist down to just dma_address and dma_length, with chaining > > > handled through an enclosing struct. > > > > Can you talk about this some more? IMHO one of the key properties of > > the scatterlist is that it can hold huge amounts of pages without > > having to do any kind of special allocation due to the chaining. > > > > The same will be true of the phyr idea right? > > My thinking is that we'd pass a relatively small array of phyr (maybe 16 > entries) to get_user_phyr(). If that turned out not to be big enough, > then we have two options; one is to map those 16 ranges with sg and use > the sg chaining functionality before throwing away the phyr and calling > get_user_phyr() again. Then we are we using get_user_phyr() at all if we are just storing it in a sg? Also 16 entries is way to small, it should be at least a whole PMD worth so we don't have to relock the PMD level each iteration. I would like to see a flow more like: cpu_phyr_list = get_user_phyr(uptr, 1G); dma_phyr_list = dma_map_phyr(device, cpu_phyr_list); [..] dma_unmap_phyr(device, dma_phyr_list); unpin_drity_free(cpu_phy_list); Where dma_map_phyr() can build a temporary SGL for old iommu drivers compatability. iommu drivers would want to implement natively, of course. ie no loops in drivers. > The question is whether this is the right kind of optimisation to be > doing. I hear you that we want a dense format, but it's questionable > whether the kind of thing you're suggesting is actually denser than this > scheme. For example, if we have 1GB pages and userspace happens to have > allocated pages (3, 4, 5, 6, 7, 8, 9, 10) then this can be represented > as a single phyr. A power-of-two scheme would have us use four entries > (3, 4-7, 8-9, 10). That is not quite what I had in mind.. struct phyr_list { unsigned int first_page_offset_bytes; size_t total_length_bytes; phys_addr_t min_alignment; struct packed_phyr *list_of_pages; }; Where each 'packed_phyr' is an aligned page of some kind. The packing has to be able to represent any number of pfns, so we have four major cases: - 4k pfns (use 8 bytes) - Natural order pfn (use 8 bytes) - 4k aligned pfns, arbitary number (use 12 bytes) - <4k aligned, arbitary length (use 16 bytes?) In all cases the interior pages are fully used, only the first and last page is sliced based on the two parameters in the phyr_list. The first_page_offset_bytes/total_length_bytes mean we don't need to use the inefficient coding for many common cases, just stick to the 4k coding and slice the first/last page down. The last case is, perhaps, a possible route to completely replace scatterlist. Few places need true byte granularity for interior pages, so we can invent some coding to say 'this is 8 byte aligned, and n bytes long' that only fits < 4k or something. Exceptional cases can then still work. I'm not sure what block needs here - is it just 512? Basically think of list_of_pages as showing a contiguous list of at least min_aligned pages and first_page_offset_bytes/total_length_bytes taking a byte granular slice out of that logical range. >From a HW perspective I see two basic modalities: - Streaming HW, which read/writes in a single pass (think NVMe/storage/network). Usually takes a list of dma_addr_t and length that HW just walks over. Rarely cares about things like page boundaries. Optimization goal is to minimize list length. In this case we map each packed_phyr into a HW SGL - Random Access HW, which is randomly touching memory (think RDMA, VFIO, DRM, IOMMU). Usually stores either a linear list of same-size dma_addr_t pages, or a radix tree page table of dma_addr_t. Needs to have a minimum alignment of each chunk (usually 4k) to represent it. Optimization goal is to have maximum page size. In this case we use min_alignment to size the HW array and decode the packed_phyrs into individual pages. > Using a (dma_addr, size_t) tuple makes coalescing adjacent pages very > cheap. With the above this still works, the very last entry in list_of_pages would be the 12 byte pfn type and when we start a new page the logic would then optimize it down to 8 bytes, if possible. At that point we know we are not going to change it: - An interior page that is up perfectly aligned is represented as a natural order - A starting page that ends on perfect alignment is widened to natural order and first_page_offset_bytes is corrected - An ending page that starts on perfect alignment is widened to natural order and total_length_bytes is set (though no harm in keeping the 12 byte represetation I suppose) The main detail is to make the extra 4 bytes needed to store the arbtiary pfn counts optional so when we don't need it, it isn't there. > > VFIO would like this structure as well as it currently is a very > > inefficient page at a time loop when it iommu maps things. > > I agree that you need these things. I think I'll run into trouble > if I try to do them for you ... so I'm going to stop after doing the > top end (pinning pages and getting them into an sg list) and let > people who know that area better than I do work on that. I agree, that is why I was asking for the datastructure 'phyr_list', with chaining and so on. I would imagine a few steps to this process: 1) 'phyr_list' datastructure, with chaining, pre-allocation, etc 2) Wrapper around existing gup to get a phyr_list for user VA 3) Compat 'dma_map_phyr()' that coverts a phyr_list to a sgl and back (However, with full performance for iommu passthrough) 4) Patches changing RDMA/VFIO/DRM to this API 5) Patches optimizing get_user_phyr() 6) Patches implementing dma_map_phyr in the AMD or Intel IOMMU driver Obviously not all done by you.. I'm happy to help and take a swing at the RDMA and VFIO parts. I feel like we can go ahead with RDMA so long as the passthrough IOMMU case is 100% efficient. VFIO is already maximually inefficient here, so no worry there already. If VFIO and RDMA consume these APIs then the server IOMMU driver owners should have a strong motivation to implement. My feeling is that at the core this project is about making a better datastructure than scattterlist that can mostly replace it, then going around the kernel and converting scatterlist users. Given all the usage considerations I think it is an interesting datastructure. Jason