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179 lines
6.3 KiB
Plaintext
179 lines
6.3 KiB
Plaintext
Content caching
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===============
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NetSurf's existing fetch/cache architecture has a number of problems:
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1) Content dependencies are not modelled.
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2) Content source data for non-shareable contents is duplicated.
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3) Detection of content sharability is dependent on Content-Type, which
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requires content cloning (which will fail for dependent contents).
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4) Detection of cycles in content dependency graphs is not performed
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(e.g. content1 includes content2, which includes content1).
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5) All content caching is in-memory, there's no offline storage.
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Proposal
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--------
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A split-level cache.
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Low-level cache:
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+ Responsible for source data (+header) management.
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+ Interfaces with low-level fetch system to retrieve data from network.
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+ Is responsible for offline storage (if any) of cache objects.
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+ Returns opaque handles to low-level cache objects.
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+ Handles HTTP redirects, recording URLs encountered when retrieving resource.
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+ May perform content-type sniffing (requires usage context)
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High-level cache:
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+ Responsible for content objects.
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+ Tracks content dependencies (and potential cycles).
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+ Returns opaque handles to content objects.
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+ Manages content sharability & reusability (see below).
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+ Contents with unknown types are never shared and thus get unique handles.
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+ Content handles <> content objects: they're an indirection mechanism.
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Content sharability & reusability
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--------------------------------
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If a content is shareable, then it may have multiple concurrent users.
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Otherwise, it may have at most one user.
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If a content is reusable, then it may be retained in the cache for later use
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when it has no users. Otherwise, it will be removed from the cache when
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it has no users.
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Example: retrieving a top-level resource
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----------------------------------------
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1) Client requests an URL, specifying no parent handle.
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2) High-level cache asks low-level cache for low-level handle for URL.
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3) Low-level cache looks for appropriate object in its index.
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a) it finds one that's not stale and returns its handle
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b) it finds only stale entries, or no appropiate entry,
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so allocates a new entry, requests a fetch for it,
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and returns the handle.
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4) High-level cache looks for content objects that are using the low-level
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handle.
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a) it finds one that's shareable and selects its handle for use.
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b) it finds only non-shareable entries, or no appropriate entry,
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so allocates a new entry and selects its handle for use.
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5) High-level cache registers the parent and client with the selected handle,
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then returns the selected handle.
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6) Client carries on, happy in the knowledge that a content is available.
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Example: retrieving a child resource
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------------------------------------
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1) Client requests an URL, specifying parent handle.
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2) High-level cache searches parent+ancestors for requested URL.
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a) it finds the URL, so returns a non-fatal error.
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b) it does not find the URL, so proceeds from step 2 of the
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top-level resource algorithm.
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NOTE: this approach means that shareable contents may have multiple parents.
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Handling of contents of unknown type
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------------------------------------
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Contents of unknown type are, by definition, not shareable. Therefore, each
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client will be issued with a different content handle.
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Content types are only known once a resource's headers are fetched (or once
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the type has been sniffed from the resource's data when the headers are
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inconclusive).
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As a resource is fetched, users of the resource are informed of the fetch
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status. Therefore, the high-level cache is always informed of fetch progress.
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Cache clients need not care about this: they are simply interested in
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a content's readiness for use.
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When the high-level cache is informed of a low-level cache object's type,
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it is in a position to determine whether the corresponding content handles
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can share a single content object or not.
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If it detects that a single content object may be shared by multiple handles,
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it simply creates the content object and registers each of the handles as
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a user of the content.
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If it detects that each handle requires a separate content object, then it
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will create a content object for each handle and register the handle as a
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user.
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This approach requires that clients of the high-level cache get issued with
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handles to content objects, rather than content objects (so that the decision
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whether to create multiple content objects can be deferred until suitable
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information is available).
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Handles with no associated content object will act as if they had a content
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object that was not ready for use.
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A more concrete example
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-----------------------
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+ bw1 contains html1 which includes css1, css2, img1, img2
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+ bw2 contains html2 which includes css1, img1, img2
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+ bw3 contains img1
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Neither HTML nor CSS contents are shareable.
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All shareable contents are requested from the high-level cache
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once their type is known.
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Low-level cache contains source data for:
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1 - html1
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2 - html2
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3 - css1
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4 - css2
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5 - img1
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6 - img2
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High-level cache contains:
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Content objects (ll-handle in parentheses):
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+ c1 (1 - html1)
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+ c2 (2 - html2)
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+ c3 (3 - css1)
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+ c4 (4 - css2)
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+ c5 (5 - img1)
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+ c6 (6 - img2)
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+ c7 (3 - css1)
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Content handles (objects in parentheses):
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+ h1 (c1, used by bw1)
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+ h2 (c3, used by h1)
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+ h3 (c4, used by h1)
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+ h4 (c2, used by bw2)
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+ h5 (c7, used by h4)
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+ h6 (c5, used by h1,h4,bw3)
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+ h7 (c6, used by h1,h4)
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If img1 was not of known type when requested:
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Content handles (objects in parentheses):
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+ h1 (c1, used by bw1)
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+ h2 (c3, used by h1)
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+ h3 (c4, used by h1)
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+ h4 (c2, used by bw2)
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+ h5 (c7, used by h4)
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+ h6 (c5, used by h1)
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+ h7 (c6, used by h1,h4)
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+ h8 (c5, used by h4)
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+ h9 (c5, used by bw3)
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This achieves the desired effect that:
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+ source data is shared between contents
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+ content objects are only created when absolutely necessary
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+ content usage/dependency is tracked and cycles avoided
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+ offline storage is possible
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Achieving this requires the use of indirection objects, but these are expected
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to be small in comparison to the content objects / ll-cache objects that they
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are indirecting.
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