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mirror of https://github.com/koreader/koreader synced 2024-11-04 12:00:25 +00:00
koreader/frontend/cache.lua
NiLuJe 18687e4666
DocCache: Allow disabling it (again) (#8198)
* Ensure DocCache will always have at least one slot
Fix #8181
2021-09-10 01:07:04 +02:00

344 lines
11 KiB
Lua

--[[
A LRU cache, based on https://github.com/starius/lua-lru
]]--
local lfs = require("libs/libkoreader-lfs")
local logger = require("logger")
local lru = require("ffi/lru")
local md5 = require("ffi/sha2").md5
local CanvasContext = require("document/canvascontext")
if CanvasContext.should_restrict_JIT then
jit.off(true, true)
end
local Cache = {
-- Cache configuration:
-- Max storage space, in bytes...
size = nil,
-- ...Average item size, used to compute the amount of slots in the LRU.
avg_itemsize = nil,
-- Or, simply set the number of slots, with no storage space limitation.
-- c.f., GlyphCache, CatalogCache
slots = nil,
-- Should LRU call the object's onFree method on eviction? Implies using CacheItem instead of plain tables/objects.
-- c.f., DocCache
enable_eviction_cb = false,
-- Generally, only DocCache uses this
disk_cache = false,
cache_path = nil,
}
function Cache:new(o)
o = o or {}
setmetatable(o, self)
self.__index = self
if o.init then o:init() end
return o
end
function Cache:init()
if self.slots then
-- Caller doesn't care about storage space, just slot count
self.cache = lru.new(self.slots, nil, self.enable_eviction_cb)
else
-- Compute the amount of slots in the LRU based on the max size & the average item size
self.slots = math.ceil(self.size / self.avg_itemsize)
self.cache = lru.new(self.slots, self.size, self.enable_eviction_cb)
end
if self.disk_cache then
self.cached = self:_getDiskCache()
else
-- No need to go through our own check or even get methods if there's no disk cache, hit lru directly
self.check = self.cache.get
end
if not self.enable_eviction_cb or not self.size then
-- We won't be using CacheItem here, so we can pass the size manually if necessary.
-- e.g., insert's signature is now (key, value, [size]), instead of relying on CacheItem's size field.
self.insert = self.cache.set
-- With debug info (c.f., below)
--self.insert = self.set
end
end
--[[
-- return a snapshot of disk cached items for subsequent check
--]]
function Cache:_getDiskCache()
local cached = {}
for key_md5 in lfs.dir(self.cache_path) do
local file = self.cache_path .. key_md5
if lfs.attributes(file, "mode") == "file" then
cached[key_md5] = file
end
end
return cached
end
-- For documentation purposes, here's a battle-tested shell version of calcFreeMem
--[[
if grep -q 'MemAvailable' /proc/meminfo ; then
# We'll settle for 85% of available memory to leave a bit of breathing room
tmpfs_size="$(awk '/MemAvailable/ {printf "%d", $2 * 0.85}' /proc/meminfo)"
elif grep -q 'Inactive(file)' /proc/meminfo ; then
# Basically try to emulate the kernel's computation, c.f., https://unix.stackexchange.com/q/261247
# Again, 85% of available memory
tmpfs_size="$(awk -v low=$(grep low /proc/zoneinfo | awk '{k+=$2}END{printf "%d", k}') \
'{a[$1]=$2}
END{
printf "%d", (a["MemFree:"]+a["Active(file):"]+a["Inactive(file):"]+a["SReclaimable:"]-(12*low))*0.85;
}' /proc/meminfo)"
else
# Ye olde crap workaround of Free + Buffers + Cache...
# Take it with a grain of salt, and settle for 80% of that...
tmpfs_size="$(awk \
'{a[$1]=$2}
END{
printf "%d", (a["MemFree:"]+a["Buffers:"]+a["Cached:"])*0.80;
}' /proc/meminfo)"
fi
--]]
-- And here's our simplified Lua version...
function Cache:_calcFreeMem()
local memtotal, memfree, memavailable, buffers, cached
local meminfo = io.open("/proc/meminfo", "r")
if meminfo then
for line in meminfo:lines() do
if not memtotal then
memtotal = line:match("^MemTotal:%s-(%d+) kB")
if memtotal then
-- Next!
goto continue
end
end
if not memfree then
memfree = line:match("^MemFree:%s-(%d+) kB")
if memfree then
-- Next!
goto continue
end
end
if not memavailable then
memavailable = line:match("^MemAvailable:%s-(%d+) kB")
if memavailable then
-- Best case scenario, we're done :)
break
end
end
if not buffers then
buffers = line:match("^Buffers:%s-(%d+) kB")
if buffers then
-- Next!
goto continue
end
end
if not cached then
cached = line:match("^Cached:%s-(%d+) kB")
if cached then
-- Ought to be the last entry we care about, we're done
break
end
end
::continue::
end
meminfo:close()
else
-- Not on Linux?
return 0, 0
end
if memavailable then
-- Leave a bit of margin, and report 85% of that...
return math.floor(memavailable * 0.85) * 1024, memtotal * 1024
else
-- Crappy Free + Buffers + Cache version, because the zoneinfo approach is a tad hairy...
-- So, leave an even larger margin, and only report 75% of that...
return math.floor((memfree + buffers + cached) * 0.75) * 1024, memtotal * 1024
end
end
function Cache:insert(key, object)
-- If this object is single-handledly too large for the cache, don't cache it.
if not self:willAccept(object.size) then
logger.warn("Too much memory would be claimed by caching", key)
return
end
self.cache:set(key, object, object.size)
-- Accounting debugging
--self:_insertion_stats(key, object.size)
end
--[[
function Cache:set(key, object, size)
self.cache:set(key, object, size)
-- Accounting debugging
self:_insertion_stats(key, size)
end
function Cache:_insertion_stats(key, size)
print(string.format("Cache %s (%d/%d) [%.2f/%.2f @ ~%db] inserted %db key: %s",
self,
self.cache:used_slots(), self.slots,
self.cache:used_size() / 1024 / 1024, (self.size or 0) / 1024 / 1024, self.cache:used_size() / self.cache:used_slots(),
size or 0, key))
end
--]]
--[[
-- check for cache item by key
-- if ItemClass is given, disk cache is also checked.
--]]
function Cache:check(key, ItemClass)
local value = self.cache:get(key)
if value then
return value
elseif ItemClass then
local cached = self.cached[md5(key)]
if cached then
local item = ItemClass:new{}
local ok, msg = pcall(item.load, item, cached)
if ok then
self:insert(key, item)
return item
else
logger.warn("Failed to load on-disk cache:", msg)
--- It's apparently unusable, purge it and refresh the snapshot.
os.remove(cached)
self:refreshSnapshot()
end
end
end
end
-- Shortcut when disk_cache is disabled
function Cache:get(key)
return self.cache:get(key)
end
function Cache:willAccept(size)
-- We only allow a single object to fill 75% of the cache
return size*4 < self.size*3
end
function Cache:serialize()
if not self.disk_cache then
return
end
-- Calculate the current disk cache size
local cached_size = 0
local sorted_caches = {}
for _, file in pairs(self.cached) do
table.insert(sorted_caches, {file=file, time=lfs.attributes(file, "access")})
cached_size = cached_size + (lfs.attributes(file, "size") or 0)
end
table.sort(sorted_caches, function(v1, v2) return v1.time > v2.time end)
-- Only serialize the second most recently used cache item (as the MRU would be the *hinted* page).
local mru_key
local mru_found = 0
for key, item in self.cache:pairs() do
-- Only dump cache items that actually request persistence
if item.persistent and item.dump then
mru_key = key
mru_found = mru_found + 1
if mru_found >= 2 then
-- We found the second MRU item, i.e., the *displayed* page
break
end
end
end
if mru_key then
local cache_full_path = self.cache_path .. md5(mru_key)
local cache_file_exists = lfs.attributes(cache_full_path)
if not cache_file_exists then
logger.dbg("Dumping cache item", mru_key)
local cache_item = self.cache:get(mru_key)
local cache_size = cache_item:dump(cache_full_path)
if cache_size then
cached_size = cached_size + cache_size
end
end
end
-- Allocate the same amount of storage to the disk cache than the memory cache
while cached_size > self.size do
-- discard the least recently used cache
local discarded = table.remove(sorted_caches)
if discarded then
cached_size = cached_size - lfs.attributes(discarded.file, "size")
os.remove(discarded.file)
else
logger.warn("Cache accounting is broken")
break
end
end
-- We may have updated the disk cache's content, so refresh its state
self:refreshSnapshot()
end
-- Blank the cache
function Cache:clear()
self.cache:clear()
end
-- Terribly crappy workaround: evict half the cache if we appear to be redlining on free RAM...
function Cache:memoryPressureCheck()
local memfree, memtotal = self:_calcFreeMem()
-- Nonsensical values? (!Linux), skip this.
if memtotal == 0 then
return
end
-- If less that 20% of the total RAM is free, drop half the Cache...
local free_fraction = memfree / memtotal
if free_fraction < 0.20 then
logger.warn(string.format("Running low on memory (~%d%%, ~%.2f/%d MiB), evicting half of the cache...",
free_fraction * 100, memfree / 1024 / 1024, memtotal / 1024 / 1024))
self.cache:chop()
-- And finish by forcing a GC sweep now...
collectgarbage()
collectgarbage()
end
end
-- Refresh the disk snapshot (mainly used by ui/data/onetime_migration)
function Cache:refreshSnapshot()
if not self.disk_cache then
return
end
self.cached = self:_getDiskCache()
end
-- Evict the disk cache (ditto)
function Cache:clearDiskCache()
if not self.disk_cache then
return
end
for _, file in pairs(self.cached) do
os.remove(file)
end
self:refreshSnapshot()
end
return Cache