| Frontswap provides a "transcendent memory" interface for swap pages. |
| In some environments, dramatic performance savings may be obtained because |
| swapped pages are saved in RAM (or a RAM-like device) instead of a swap disk. |
| |
| (Note, frontswap -- and cleancache (merged at 3.0) -- are the "frontends" |
| and the only necessary changes to the core kernel for transcendent memory; |
| all other supporting code -- the "backends" -- is implemented as drivers. |
| See the LWN.net article "Transcendent memory in a nutshell" for a detailed |
| overview of frontswap and related kernel parts: |
| https://lwn.net/Articles/454795/ ) |
| |
| Frontswap is so named because it can be thought of as the opposite of |
| a "backing" store for a swap device. The storage is assumed to be |
| a synchronous concurrency-safe page-oriented "pseudo-RAM device" conforming |
| to the requirements of transcendent memory (such as Xen's "tmem", or |
| in-kernel compressed memory, aka "zcache", or future RAM-like devices); |
| this pseudo-RAM device is not directly accessible or addressable by the |
| kernel and is of unknown and possibly time-varying size. The driver |
| links itself to frontswap by calling frontswap_register_ops to set the |
| frontswap_ops funcs appropriately and the functions it provides must |
| conform to certain policies as follows: |
| |
| An "init" prepares the device to receive frontswap pages associated |
| with the specified swap device number (aka "type"). A "store" will |
| copy the page to transcendent memory and associate it with the type and |
| offset associated with the page. A "load" will copy the page, if found, |
| from transcendent memory into kernel memory, but will NOT remove the page |
| from from transcendent memory. An "invalidate_page" will remove the page |
| from transcendent memory and an "invalidate_area" will remove ALL pages |
| associated with the swap type (e.g., like swapoff) and notify the "device" |
| to refuse further stores with that swap type. |
| |
| Once a page is successfully stored, a matching load on the page will normally |
| succeed. So when the kernel finds itself in a situation where it needs |
| to swap out a page, it first attempts to use frontswap. If the store returns |
| success, the data has been successfully saved to transcendent memory and |
| a disk write and, if the data is later read back, a disk read are avoided. |
| If a store returns failure, transcendent memory has rejected the data, and the |
| page can be written to swap as usual. |
| |
| If a backend chooses, frontswap can be configured as a "writethrough |
| cache" by calling frontswap_writethrough(). In this mode, the reduction |
| in swap device writes is lost (and also a non-trivial performance advantage) |
| in order to allow the backend to arbitrarily "reclaim" space used to |
| store frontswap pages to more completely manage its memory usage. |
| |
| Note that if a page is stored and the page already exists in transcendent memory |
| (a "duplicate" store), either the store succeeds and the data is overwritten, |
| or the store fails AND the page is invalidated. This ensures stale data may |
| never be obtained from frontswap. |
| |
| If properly configured, monitoring of frontswap is done via debugfs in |
| the /sys/kernel/debug/frontswap directory. The effectiveness of |
| frontswap can be measured (across all swap devices) with: |
| |
| failed_stores - how many store attempts have failed |
| loads - how many loads were attempted (all should succeed) |
| succ_stores - how many store attempts have succeeded |
| invalidates - how many invalidates were attempted |
| |
| A backend implementation may provide additional metrics. |
| |
| FAQ |
| |
| 1) Where's the value? |
| |
| When a workload starts swapping, performance falls through the floor. |
| Frontswap significantly increases performance in many such workloads by |
| providing a clean, dynamic interface to read and write swap pages to |
| "transcendent memory" that is otherwise not directly addressable to the kernel. |
| This interface is ideal when data is transformed to a different form |
| and size (such as with compression) or secretly moved (as might be |
| useful for write-balancing for some RAM-like devices). Swap pages (and |
| evicted page-cache pages) are a great use for this kind of slower-than-RAM- |
| but-much-faster-than-disk "pseudo-RAM device" and the frontswap (and |
| cleancache) interface to transcendent memory provides a nice way to read |
| and write -- and indirectly "name" -- the pages. |
| |
| Frontswap -- and cleancache -- with a fairly small impact on the kernel, |
| provides a huge amount of flexibility for more dynamic, flexible RAM |
| utilization in various system configurations: |
| |
| In the single kernel case, aka "zcache", pages are compressed and |
| stored in local memory, thus increasing the total anonymous pages |
| that can be safely kept in RAM. Zcache essentially trades off CPU |
| cycles used in compression/decompression for better memory utilization. |
| Benchmarks have shown little or no impact when memory pressure is |
| low while providing a significant performance improvement (25%+) |
| on some workloads under high memory pressure. |
| |
| "RAMster" builds on zcache by adding "peer-to-peer" transcendent memory |
| support for clustered systems. Frontswap pages are locally compressed |
| as in zcache, but then "remotified" to another system's RAM. This |
| allows RAM to be dynamically load-balanced back-and-forth as needed, |
| i.e. when system A is overcommitted, it can swap to system B, and |
| vice versa. RAMster can also be configured as a memory server so |
| many servers in a cluster can swap, dynamically as needed, to a single |
| server configured with a large amount of RAM... without pre-configuring |
| how much of the RAM is available for each of the clients! |
| |
| In the virtual case, the whole point of virtualization is to statistically |
| multiplex physical resources acrosst the varying demands of multiple |
| virtual machines. This is really hard to do with RAM and efforts to do |
| it well with no kernel changes have essentially failed (except in some |
| well-publicized special-case workloads). |
| Specifically, the Xen Transcendent Memory backend allows otherwise |
| "fallow" hypervisor-owned RAM to not only be "time-shared" between multiple |
| virtual machines, but the pages can be compressed and deduplicated to |
| optimize RAM utilization. And when guest OS's are induced to surrender |
| underutilized RAM (e.g. with "selfballooning"), sudden unexpected |
| memory pressure may result in swapping; frontswap allows those pages |
| to be swapped to and from hypervisor RAM (if overall host system memory |
| conditions allow), thus mitigating the potentially awful performance impact |
| of unplanned swapping. |
| |
| A KVM implementation is underway and has been RFC'ed to lkml. And, |
| using frontswap, investigation is also underway on the use of NVM as |
| a memory extension technology. |
| |
| 2) Sure there may be performance advantages in some situations, but |
| what's the space/time overhead of frontswap? |
| |
| If CONFIG_FRONTSWAP is disabled, every frontswap hook compiles into |
| nothingness and the only overhead is a few extra bytes per swapon'ed |
| swap device. If CONFIG_FRONTSWAP is enabled but no frontswap "backend" |
| registers, there is one extra global variable compared to zero for |
| every swap page read or written. If CONFIG_FRONTSWAP is enabled |
| AND a frontswap backend registers AND the backend fails every "store" |
| request (i.e. provides no memory despite claiming it might), |
| CPU overhead is still negligible -- and since every frontswap fail |
| precedes a swap page write-to-disk, the system is highly likely |
| to be I/O bound and using a small fraction of a percent of a CPU |
| will be irrelevant anyway. |
| |
| As for space, if CONFIG_FRONTSWAP is enabled AND a frontswap backend |
| registers, one bit is allocated for every swap page for every swap |
| device that is swapon'd. This is added to the EIGHT bits (which |
| was sixteen until about 2.6.34) that the kernel already allocates |
| for every swap page for every swap device that is swapon'd. (Hugh |
| Dickins has observed that frontswap could probably steal one of |
| the existing eight bits, but let's worry about that minor optimization |
| later.) For very large swap disks (which are rare) on a standard |
| 4K pagesize, this is 1MB per 32GB swap. |
| |
| When swap pages are stored in transcendent memory instead of written |
| out to disk, there is a side effect that this may create more memory |
| pressure that can potentially outweigh the other advantages. A |
| backend, such as zcache, must implement policies to carefully (but |
| dynamically) manage memory limits to ensure this doesn't happen. |
| |
| 3) OK, how about a quick overview of what this frontswap patch does |
| in terms that a kernel hacker can grok? |
| |
| Let's assume that a frontswap "backend" has registered during |
| kernel initialization; this registration indicates that this |
| frontswap backend has access to some "memory" that is not directly |
| accessible by the kernel. Exactly how much memory it provides is |
| entirely dynamic and random. |
| |
| Whenever a swap-device is swapon'd frontswap_init() is called, |
| passing the swap device number (aka "type") as a parameter. |
| This notifies frontswap to expect attempts to "store" swap pages |
| associated with that number. |
| |
| Whenever the swap subsystem is readying a page to write to a swap |
| device (c.f swap_writepage()), frontswap_store is called. Frontswap |
| consults with the frontswap backend and if the backend says it does NOT |
| have room, frontswap_store returns -1 and the kernel swaps the page |
| to the swap device as normal. Note that the response from the frontswap |
| backend is unpredictable to the kernel; it may choose to never accept a |
| page, it could accept every ninth page, or it might accept every |
| page. But if the backend does accept a page, the data from the page |
| has already been copied and associated with the type and offset, |
| and the backend guarantees the persistence of the data. In this case, |
| frontswap sets a bit in the "frontswap_map" for the swap device |
| corresponding to the page offset on the swap device to which it would |
| otherwise have written the data. |
| |
| When the swap subsystem needs to swap-in a page (swap_readpage()), |
| it first calls frontswap_load() which checks the frontswap_map to |
| see if the page was earlier accepted by the frontswap backend. If |
| it was, the page of data is filled from the frontswap backend and |
| the swap-in is complete. If not, the normal swap-in code is |
| executed to obtain the page of data from the real swap device. |
| |
| So every time the frontswap backend accepts a page, a swap device read |
| and (potentially) a swap device write are replaced by a "frontswap backend |
| store" and (possibly) a "frontswap backend loads", which are presumably much |
| faster. |
| |
| 4) Can't frontswap be configured as a "special" swap device that is |
| just higher priority than any real swap device (e.g. like zswap, |
| or maybe swap-over-nbd/NFS)? |
| |
| No. First, the existing swap subsystem doesn't allow for any kind of |
| swap hierarchy. Perhaps it could be rewritten to accomodate a hierarchy, |
| but this would require fairly drastic changes. Even if it were |
| rewritten, the existing swap subsystem uses the block I/O layer which |
| assumes a swap device is fixed size and any page in it is linearly |
| addressable. Frontswap barely touches the existing swap subsystem, |
| and works around the constraints of the block I/O subsystem to provide |
| a great deal of flexibility and dynamicity. |
| |
| For example, the acceptance of any swap page by the frontswap backend is |
| entirely unpredictable. This is critical to the definition of frontswap |
| backends because it grants completely dynamic discretion to the |
| backend. In zcache, one cannot know a priori how compressible a page is. |
| "Poorly" compressible pages can be rejected, and "poorly" can itself be |
| defined dynamically depending on current memory constraints. |
| |
| Further, frontswap is entirely synchronous whereas a real swap |
| device is, by definition, asynchronous and uses block I/O. The |
| block I/O layer is not only unnecessary, but may perform "optimizations" |
| that are inappropriate for a RAM-oriented device including delaying |
| the write of some pages for a significant amount of time. Synchrony is |
| required to ensure the dynamicity of the backend and to avoid thorny race |
| conditions that would unnecessarily and greatly complicate frontswap |
| and/or the block I/O subsystem. That said, only the initial "store" |
| and "load" operations need be synchronous. A separate asynchronous thread |
| is free to manipulate the pages stored by frontswap. For example, |
| the "remotification" thread in RAMster uses standard asynchronous |
| kernel sockets to move compressed frontswap pages to a remote machine. |
| Similarly, a KVM guest-side implementation could do in-guest compression |
| and use "batched" hypercalls. |
| |
| In a virtualized environment, the dynamicity allows the hypervisor |
| (or host OS) to do "intelligent overcommit". For example, it can |
| choose to accept pages only until host-swapping might be imminent, |
| then force guests to do their own swapping. |
| |
| There is a downside to the transcendent memory specifications for |
| frontswap: Since any "store" might fail, there must always be a real |
| slot on a real swap device to swap the page. Thus frontswap must be |
| implemented as a "shadow" to every swapon'd device with the potential |
| capability of holding every page that the swap device might have held |
| and the possibility that it might hold no pages at all. This means |
| that frontswap cannot contain more pages than the total of swapon'd |
| swap devices. For example, if NO swap device is configured on some |
| installation, frontswap is useless. Swapless portable devices |
| can still use frontswap but a backend for such devices must configure |
| some kind of "ghost" swap device and ensure that it is never used. |
| |
| 5) Why this weird definition about "duplicate stores"? If a page |
| has been previously successfully stored, can't it always be |
| successfully overwritten? |
| |
| Nearly always it can, but no, sometimes it cannot. Consider an example |
| where data is compressed and the original 4K page has been compressed |
| to 1K. Now an attempt is made to overwrite the page with data that |
| is non-compressible and so would take the entire 4K. But the backend |
| has no more space. In this case, the store must be rejected. Whenever |
| frontswap rejects a store that would overwrite, it also must invalidate |
| the old data and ensure that it is no longer accessible. Since the |
| swap subsystem then writes the new data to the read swap device, |
| this is the correct course of action to ensure coherency. |
| |
| 6) What is frontswap_shrink for? |
| |
| When the (non-frontswap) swap subsystem swaps out a page to a real |
| swap device, that page is only taking up low-value pre-allocated disk |
| space. But if frontswap has placed a page in transcendent memory, that |
| page may be taking up valuable real estate. The frontswap_shrink |
| routine allows code outside of the swap subsystem to force pages out |
| of the memory managed by frontswap and back into kernel-addressable memory. |
| For example, in RAMster, a "suction driver" thread will attempt |
| to "repatriate" pages sent to a remote machine back to the local machine; |
| this is driven using the frontswap_shrink mechanism when memory pressure |
| subsides. |
| |
| 7) Why does the frontswap patch create the new include file swapfile.h? |
| |
| The frontswap code depends on some swap-subsystem-internal data |
| structures that have, over the years, moved back and forth between |
| static and global. This seemed a reasonable compromise: Define |
| them as global but declare them in a new include file that isn't |
| included by the large number of source files that include swap.h. |
| |
| Dan Magenheimer, last updated April 9, 2012 |