On 26.09.2023 20:57, David Hildenbrand wrote:
Having large virtio-mem devices that only expose little memory to a VM is currently a problem: we map the whole sparse memory region into the guest using a single memslot, resulting in one gigantic memslot in KVM. KVM allocates metadata for the whole memslot, which can result in quite some memory waste. Assuming we have a 1 TiB virtio-mem device and only expose little (e.g., 1 GiB) memory, we would create a single 1 TiB memslot and KVM has to allocate metadata for that 1 TiB memslot: on x86, this implies allocating a significant amount of memory for metadata: (1) RMAP: 8 bytes per 4 KiB, 8 bytes per 2 MiB, 8 bytes per 1 GiB -> For 1 TiB: 2147483648 + 4194304 + 8192 = ~ 2 GiB (0.2 %) With the TDP MMU (cat /sys/module/kvm/parameters/tdp_mmu) this gets allocated lazily when required for nested VMs (2) gfn_track: 2 bytes per 4 KiB -> For 1 TiB: 536870912 = ~512 MiB (0.05 %) (3) lpage_info: 4 bytes per 2 MiB, 4 bytes per 1 GiB -> For 1 TiB: 2097152 + 4096 = ~2 MiB (0.0002 %) (4) 2x dirty bitmaps for tracking: 2x 1 bit per 4 KiB page -> For 1 TiB: 536870912 = 64 MiB (0.006 %) So we primarily care about (1) and (2). The bad thing is, that the memory consumption *doubles* once SMM is enabled, because we create the memslot once for !SMM and once for SMM. Having a 1 TiB memslot without the TDP MMU consumes around: * With SMM: 5 GiB * Without SMM: 2.5 GiB Having a 1 TiB memslot with the TDP MMU consumes around: * With SMM: 1 GiB * Without SMM: 512 MiB ... and that's really something we want to optimize, to be able to just start a VM with small boot memory (e.g., 4 GiB) and a virtio-mem device that can grow very large (e.g., 1 TiB). Consequently, using multiple memslots and only mapping the memslots we really need can significantly reduce memory waste and speed up memslot-related operations. Let's expose the sparse RAM memory region using multiple memslots, mapping only the memslots we currently need into our device memory region container. The feature can be enabled using "dynamic-memslots=on" and requires "unplugged-inaccessible=on", which is nowadays the default. Once enabled, we'll auto-detect the number of memslots to use based on the memslot limit provided by the core. We'll use at most 1 memslot per gigabyte. Note that our global limit of memslots accross all memory devices is currently set to 256: even with multiple large virtio-mem devices, we'd still have a sane limit on the number of memslots used. The default is to not dynamically map memslot for now ("dynamic-memslots=off"). The optimization must be enabled manually, because some vhost setups (e.g., hotplug of vhost-user devices) might be problematic until we support more memslots especially in vhost-user backends. Note that "dynamic-memslots=on" is just a hint that multiple memslots *may* be used for internal optimizations, not that multiple memslots *must* be used. The actual number of memslots that are used is an internal detail: for example, once memslot metadata is no longer an issue, we could simply stop optimizing for that. Migration source and destination can differ on the setting of "dynamic-memslots". Signed-off-by: David Hildenbrand <david@xxxxxxxxxx> ---
The changes seem reasonable, so: Reviewed-by: Maciej S. Szmigiero <maciej.szmigiero@xxxxxxxxxx> Thanks, Maciej