2016-12-05 21:12:24 +00:00
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# Caps
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Caps are lightweight refcounted objects describing media types. They are
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composed of an array of `GstStructure` plus, optionally, a
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`GstCapsFeatures` set for the `GstStructure`.
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2016-12-05 21:12:24 +00:00
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2016-12-21 06:47:20 +00:00
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Caps are exposed on `GstPadTemplates` to describe all possible types a
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given pad can handle. They are also stored in the registry along with a
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description of the element.
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Caps are exposed on the element pads via `CAPS` and `ACCEPT_CAPS` queries.
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This function describes the possible types that the pad can handle or
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produce ([negotiation](additional/design/negotiation.md)).
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Various methods exist to work with the media types such as subtracting
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or intersecting.
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## Operations
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### Fixating
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Caps are fixed if they only contain a single structure and this
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structure is fixed. A structure is fixed if none of its fields
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is of an unfixed type, for example a range, list or array.
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For fixating caps only the first structure is kept, as the order in
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which they appear is meant to express their precedence.
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Afterwards, each unfixed field of this structure is set to
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the value that makes most sense for the media format by the element or
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pad implementation and then every remaining unfixed field is set to an
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arbitrary value that is a subset of the unfixed field’s values.
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EMPTY caps are fixed caps and ANY caps are not. Caps with ANY caps
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features are not fixed.
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### Subset
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One caps "A" is a subset of another caps "B" if for each structure in
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"A" there exists a structure in "B" that is a superset of the structure
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in "A".
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A structure "a" is the subset of a structure "b" if it has the same
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structure name, the same caps features and each field in "b" either does not
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exist in "a", or the value of the field in "a" is a subset of the value of the
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field in "b". "a" must not have additional fields that are not in "b". Fields
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that are in "b" but not in "a" (aka, an empty field) are always a subset.
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This is different to the intuitive mathematical definition as an empty field
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is defined to contain all possible values. This means that the empty field is
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always a superset of any other field.
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`EMPTY` caps are a subset of every other caps. Every caps are a subset of
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`ANY` caps.
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### Equality
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Caps "A" and "B" are equal if "A" is a subset of "B" and "B" is a subset
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of "A". This means that both caps are expressing the same possibilities
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but their structures can still be different if they contain unfixed
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fields.
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### Intersection
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The intersection of caps "A" and caps "B" are the caps that contain the
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intersection of all their structures with each other.
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The intersection of structure "a" and structure "b" is empty if their
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structure name or their caps features are not equal, or if "a" and "b"
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contain the same field but the intersection of both field values is
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empty. If one structure contains a field that is not existing in the
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other structure it will be copied over to the intersection with the same
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value.
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The intersection with `ANY` caps is always the other caps and the
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intersection with `EMPTY` caps is always `EMPTY`.
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### Union
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The union of caps "A" and caps "B" are the caps that contain the union
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of all their structures with each other.
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The union of structure "a" and structure "b" are the two structures "a"
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and "b" if the structure names or caps features are not equal.
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Otherwise, the union is the structure that contains the union of each
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fields value. If a field is only in one of the two structures it is not
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contained in the union.
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The union with ANY caps is always ANY and the union with EMPTY caps is
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always the other caps.
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### Subtraction
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The subtraction of caps "A" from caps "B" is the most generic subset of
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"B" that has an empty intersection with "A" but only contains structures
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with names and caps features that are existing in "B".
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## Basic Rules
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### Semantics of caps and their usage
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A caps can contain multiple structures, in which case any of the
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structures would be acceptable. The structures are in the preferred
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order of the creator of the caps, with the preferred structure being
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first and during negotiation of caps this order should be considered to
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select the most optimal structure.
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Each of these structures has a name that specifies the media type, e.g.
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"video/x-theora" to specify Theora video. Additional fields in the
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structure add additional constraints and/or information about the media
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type, like the width and height of a video frame, or the codec profile
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that is used. These fields can be non-fixed (e.g. ranges) for non-fixed
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caps but must be fixated to a fixed value during negotiation. If a field
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is included in the caps returned by a pad via the `CAPS` query, it imposes
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an additional constraint during negotiation. The caps in the end must
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have this field with a value that is a subset of the non-fixed value.
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Additional fields that are added in the negotiated caps give additional
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information about the media but are treated as optional. Information
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that can change for every buffer and is not relevant during negotiation
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must not be stored inside the caps.
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For each of the structures in caps it is possible to store caps
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features. The caps features are expressing additional requirements for a
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specific structure, and only structures with the same name *and* equal
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caps features are considered compatible. Caps features can be used to
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require a specific memory representation or a specific meta to be set on
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buffers, for example a pad could require for a specific structure that
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it is passed `EGLImage` memory or buffers with the video meta. If no caps
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features are provided for a structure, it is assumed that system memory
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is required unless later negotiation steps (e.g. the `ALLOCATION` query)
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detect that something else can be used. The special `ANY` caps features
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can be used to specify that any caps feature would be accepted, for
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example if the buffer memory is not touched at all.
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### Compatibility of caps
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Pads can be linked when the caps of both pads are compatible. This is
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the case when their intersection is not empty.
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For checking if a pad actually supports a fixed caps an intersection is
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not enough. Instead the fixed caps must be at least a subset of the
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pad’s caps but pads can introduce additional constraints which would
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be checked in the `ACCEPT_CAPS` query handler.
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Data flow can only happen after pads have decided on common fixed caps.
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These caps are distributed to both pads with the `CAPS` event.
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