JPWO2020159989A5 - - Google Patents

Description

The details of one or more variations of the subject matter described in this specification are set forth in the accompanying drawings and the description below. Other features and advantages of the subject matter described herein will be apparent from the description and drawings, and from the claims.
The present invention provides, for example, the following.
(Item 1)
A decoder, said decoder comprising a circuit, said circuit comprising:
receiving a bitstream;
dividing the current block into a first region, a second region, and a third region via a geometric division mode;
determining a motion vector associated with a region of the first region, the second region, and the third region, further comprising building a candidate list; , and
decoding the current block using the determined motion vector;
A decoder configured to:
(Item 2)
The decoder of item 1, wherein building the candidate list includes evaluating a bottom left candidate, a left candidate, a top left candidate, a top candidate, and a top right candidate.
(Item 3)
the determined motion vector is with respect to the first region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
the lower left candidate is located at a third luma place immediately to the left and directly below the second luma place;
the left candidate is located at a fourth luma place immediately to the left of the second luma place;
the upper left candidate is located at a fifth luma place directly above and immediately to the left of the upper left most luma place of the first region;
the top candidate is located at a sixth luma place directly above the first luma place;
3. The decoder of item 2, wherein the upper right candidate is located at a seventh luma place directly above and to the right of the first luma place.
(Item 4)
the determined motion vector is with respect to the second region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
The lower left candidate is located at a third luma place immediately left and directly below the lower leftmost luma place of the third region;
the left candidate is located at a fourth luma place immediately to the left of the lower leftmost luma place of the third region;
the top left candidate is located at a fifth luma location directly above the first location;
The upper candidate is located at a sixth luma place directly above the upper right most luma place of the second region;
3. The decoder of item 2, wherein the upper right candidate is located at a seventh luma place directly above and to the right of the upper right most luma place of the second region.
(Item 5)
the determined motion vector is with respect to the third region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
The lower left candidate is located at a third luma place immediately left and directly below the lower leftmost luma place of the third region;
the left candidate is located at a fourth luma place immediately to the left of the lower leftmost luma place of the third region;
the upper left candidate is located at a fifth luma location co-located with the first region;
said top candidate is located at a sixth luma place immediately to the left of said second place;
3. The decoder of item 2, wherein the upper right candidate is located at a seventh luma location aligned with the second region.
(Item 6)
The determined motion vector is with respect to the second region, and the decoder further marks the candidate as unavailable in response to determining that the candidate is co-located with the third region. 3. The decoder of item 2, configured to mark.
(Item 7)
the determined motion vector is with respect to the second region;
3. The method of claim 2, wherein the decoder is further configured to automatically mark the top left candidate as unavailable in response to determining that the geometric partitioning mode is enabled. decoder.
(Item 8)
the determined motion vector is with respect to the third region;
3. The method of clause 2, wherein the decoder is further configured to automatically mark the upper right candidate as unavailable in response to determining that the geometric partitioning mode is enabled. decoder.
(Item 9)
the determined motion vector is with respect to the third region;
3. The method of claim 2, wherein the decoder is further configured to automatically mark the upper left candidate as unavailable in response to determining that the geometric partitioning mode is enabled. decoder.
(Item 10)
The decoder of item 1, further configured to determine that merge mode is enabled for the first region.
(Item 11)
2. The decoder of item 1, further configured to determine that an advanced motion vector prediction mode is enabled for the first region.
(Item 12)
The decoder of item 1, further configured to reconstruct pixel data of the current block.
(Item 13)
13. The decoder of item 12, wherein the first region and the second region are non-rectangular.
(Item 14)
The decoder of item 1, wherein the geometric partitioning mode is signaled within the bitstream.
(Item 15)
Dividing the current block into the first region, the second region, and the third region via the geometric division mode is characterized by a first luma location and a second luma location. 2. The decoder of item 1, comprising dividing the current block using attached line segments.
(Item 16)
determining whether the geometric split mode is enabled;
determining a first line segment for the current block;
determining a second line segment for the current block;
is further configured to do
decoding the current block includes reconstructing pixel data using the first line segment and the second line segment;
The decoder of item 1, wherein the first line segment and the second line segment divide the current block into the first region, the second region and the third region.
(Item 17)
The decoder of item 1, wherein the geometric partitioning mode is available for block sizes of 64x64 luma samples or greater, or 128x128 luma samples or greater.
(Item 18)
an entropy decoder processor configured to receive the bitstream and decode the bitstream into quantized coefficients;
an inverse quantization and inverse transform processor configured to process said quantized coefficients, including performing an inverse discrete cosine transform;
a deblocking filter;
a framebuffer and
intra prediction processor and
The decoder of item 1, further comprising:
(Item 19)
The decoder of item 1, wherein the bitstream includes a parameter indicating whether the geometric partitioning mode is enabled for the current block.
(Item 20)
Decoder according to item 1, wherein the current block forms part of a quadtree plus a binary decision tree.
(Item 21)
21. The decoder of item 20, wherein the current block is a non-leaf node of the quadtree plus binary decision tree.
(Item 22)
Decoder according to item 1, wherein the current block is a coding tree unit or a coding unit.
(Item 23)
The decoder of item 1, wherein the first region is a coding unit or a prediction unit.
(Item 24)
A method, the method comprising:
a decoder receiving a bitstream;
the decoder dividing a current block into a first region, a second region and a third region via a geometric partitioning mode;
The decoder determining a motion vector associated with a region of the first region, the second region and the third region, said determining building a candidate list. including to
the decoder decoding the current block using the determined motion vector;
A method, including
(Item 25)
25. The method of item 24, wherein building the candidate list includes evaluating bottom left candidates, left candidates, top left candidates, top candidates, and top right candidates.
(Item 26)
the determined motion vector is with respect to the first region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
the lower left candidate is located at a third luma place immediately to the left and directly below the second luma place;
the left candidate is located at a fourth luma place immediately to the left of the second luma place;
the upper left candidate is located at a fifth luma place directly above and immediately to the left of the upper left most luma place of the first region;
the top candidate is located at a sixth luma place directly above the first luma place;
26. The method of item 25, wherein the upper right candidate is located at a seventh luma place directly above and to the right of the first luma place.
(Item 27)
the determined motion vector is with respect to the second region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
The lower left candidate is located at a third luma place immediately left and directly below the lower leftmost luma place of the third region;
the left candidate is located at a fourth luma place immediately to the left of the lower leftmost luma place of the third region;
the top left candidate is located at a fifth luma location directly above the first location;
The upper candidate is located at a sixth luma place directly above the upper right most luma place of the second region;
26. The method of item 25, wherein the upper right candidate is located at a seventh luma place directly above and to the right of the upper right most luma place of the second region.
(Item 28)
the determined motion vector is with respect to the third region;
the geometric splitting mode includes a line segment between a first luma location and a second luma location;
The lower left candidate is located at a third luma place immediately left and directly below the lower leftmost luma place of the third region;
the left candidate is located at a fourth luma place immediately to the left of the lower leftmost luma place of the third region;
the upper left candidate is located at a fifth luma location co-located with the first region;
said top candidate is located at a sixth luma place immediately to the left of said second place;
26. The method of item 25, wherein the upper right candidate is located at a seventh luma location co-located with the second region.
(Item 29)
The determined motion vector is relative to the second region, and further marking the candidate as unavailable in response to determining that the candidate is co-located with the third region. 26. The method of item 25, comprising:
(Item 30)
The determined motion vector relates to the second region and automatically marks the top left candidate as unavailable in response to determining that the geometric partitioning mode is enabled. 26. The method of item 25, further comprising:
(Item 31)
The determined motion vector relates to the third region and automatically marks the upper right candidate as unavailable in response to determining that the geometric partitioning mode is enabled. 26. The method of item 25, further comprising:
(Item 32)
The determined motion vector relates to the third region and automatically marks the upper left candidate as unavailable in response to determining that the geometric partitioning mode is enabled. 26. The method of item 25, further comprising:
(Item 33)
25. The method of item 24, further comprising determining that merge mode is enabled for the first region.
(Item 34)
25. The method of item 24, further comprising determining that an advanced motion vector prediction mode is enabled for the first region.
(Item 35)
25. The method of item 24, further comprising reconstructing pixel data of the current block.
(Item 36)
25. The method of item 24, wherein each of the first region and the second region is non-rectangular.
(Item 37)
25. The method of item 24, wherein the geometric partitioning mode is signaled within the bitstream.
(Item 38)
Dividing the current block into the first region, the second region, and the third region via the geometric division mode is characterized by a first luma location and a second luma location. 25. The method of item 24, comprising dividing the current block using attached line segments.
(Item 39)
determining whether the geometric split mode is enabled;
determining a first line segment for the current block;
determining a second line segment for the current block;
further comprising
decoding the current block includes reconstructing pixel data using the first line segment and the second line segment;
25. The method of item 24, wherein the first line segment and the second line segment divide the current block into the first region, the second region and the third region.
(Item 40)
25. The method of item 24, wherein the geometric partitioning mode is available for block sizes of 64 x 64 luma samples or greater, or 128 x 128 luma samples or greater.
(Item 41)
The decoder further:
an entropy decoder processor configured to receive the bitstream and decode the bitstream into quantized coefficients;
an inverse quantization and inverse transform processor configured to process said quantized coefficients, including performing an inverse discrete cosine transform;
a deblocking filter;
a framebuffer and
intra prediction processor and
25. The method of item 24, comprising:
(Item 42)
25. The method of item 24, wherein the bitstream includes a parameter indicating whether the geometric partitioning mode is enabled for the current block.
(Item 43)
25. Method according to item 24, wherein the current block forms part of a quadtree plus a binary decision tree.
(Item 44)
44. The method of item 43, wherein the current block is a non-leaf node of the quadtree plus binary decision tree.
(Item 45)
25. The method of item 24, wherein the current block is a coding tree unit or a coding unit.
(Item 46)
25. The method of item 24, wherein the first region is a coding unit or a prediction unit.

Claims (14)

A decoder, said decoder comprising a circuit, said circuit comprising:
receiving a bitstream, the bitstream comprising a current picture, the current picture comprising a current block of pixels with a plurality of partition boundaries, the plurality of partition boundaries separating the block from a first and at least a first division boundary that divides into a second non-rectangular region, and a second division boundary that is non-parallel to and intersects with the at least first division boundary There is, and
dividing the second non-rectangular region of the current block via a division mode to divide the current block into three parts;
Determining a first predictor for use on a first side of the at least first partition boundary using a first motion vector selected from a first list of motion vector candidates. and,
Determining a second predictor for use on a second side of the at least first partition boundary using a second motion vector selected from a second list of motion vector candidates. and,
decoding the current block using the first motion vector and the second motion vector, decoding comprising:
smoothing the first predictor and the second predictor across the at least first partition boundary;
adding residual pixel values to the first predictor and the second predictor;
further comprising
A decoder configured to: 2. The decoder of claim 1, wherein the current block further comprises a coding tree unit. 2. The decoder of claim 1, further configured to determine that merge mode is enabled for the first of the three parts. 4. The decoder of claim 3, further configured to decode the first portion according to the merge mode. 2. The decoder of claim 1, further configured to determine that merge mode is disabled for the first of the three parts. 6. The decoder of claim 5, further configured to decode the first portion as a function of motion vector difference. an entropy decoder processor configured to receive the bitstream and decode the bitstream into quantized coefficients;
an inverse quantization and inverse transform processor configured to process said quantized coefficients, including performing an inverse discrete cosine transform;
a deblocking filter;
a framebuffer and
intra prediction processor and
2. The decoder of claim 1, further comprising: A method, the method comprising:
A decoder receives a bitstream, the bitstream comprising a current picture, the current picture comprising a current block of pixels with a plurality of partition boundaries, the plurality of partition boundaries comprising the block into first and second non-rectangular regions, and a second partition non-parallel to and intersecting the at least first partition boundary being a split boundary;
the decoder, via a split mode, splitting the second non-rectangular region of the current block to split the current block into three parts;
The decoder uses a first motion vector selected from a first list of motion vector candidates to create a first predictor for use on a first side of the at least first partition boundary. and
The decoder uses a second motion vector selected from a second list of motion vector candidates to generate a second predictor for use on a second side of the at least first partition boundary. and
the decoder decoding the current block using the first motion vector and the second motion vector, decoding comprising:
smoothing the first predictor and the second predictor across the at least first partition boundary;
adding residual pixel values to the first predictor and the second predictor;
further comprising
A method, including 9. The method of Claim 8, wherein the current block further comprises a coding tree unit. 9. The method of claim 8, further comprising determining that merge mode is enabled for the first of the three parts. 11. The method of claim 10, further comprising decoding said first portion according to said merge mode. 9. The method of claim 8, further comprising determining that merge mode is disabled for the first of the three parts. 13. The method of claim 12, further comprising decoding the first portion as a function of motion vector difference. The decoder is
an entropy decoder processor configured to receive the bitstream and decode the bitstream into quantized coefficients;
an inverse quantization and inverse transform processor configured to process said quantized coefficients, including performing an inverse discrete cosine transform;
a deblocking filter;
a framebuffer and
intra prediction processor and
9. The method of claim 8, further comprising: