Rev 1085 | Go to most recent revision | Details | Compare with Previous | Last modification | View Log | RSS feed
Rev | Author | Line No. | Line |
---|---|---|---|
1085 | pj | 1 | The following changes have been made to debug spatial scalability: |
2 | |||
3 | gethdr.c |
||
4 | -------- |
||
5 | |||
6 | Temporal_reference is used to compute the frame number of each frame, |
||
7 | named true_framenum. The periodic reset at each GOP header as well as |
||
8 | the wrap of temporal_reference at 1024 cause a base value |
||
9 | temp_ref_base to be incremented accordingly. |
||
10 | |||
11 | spatscal.c |
||
12 | ---------- |
||
13 | |||
14 | getspatref() |
||
15 | |||
16 | A potential problem: Variable char fname[32] was dimensioned |
||
17 | statically and too small. |
||
18 | |||
19 | true_framenum is used instead of lower_layer_temporal_reference to |
||
20 | determine the lower layer frame to be read for spatial prediction. |
||
21 | |||
22 | The verification of lower_layer_temporal_reference is not possible |
||
23 | since the temporal reference values that have been encoded into the |
||
24 | base layer bitstream are not available to the enhancement layer |
||
25 | decoder. |
||
26 | |||
27 | Since there is no decoder timing information available, the rules on |
||
28 | which frames can legally be used as spatial prediction frames cannot |
||
29 | be checked. |
||
30 | |||
31 | Lower layer frames are read field-wise or frame-wise, depending on the |
||
32 | lower_layer_progressive_frame flag. Consistency between layers is |
||
33 | checked since the file format for frame and field pictures differs. |
||
34 | |||
35 | Note that the base layer decoder must not use the -f option to enforce |
||
36 | frame-wise storage. |
||
37 | |||
38 | Note further that only yuv image format (option -o0) is supported as |
||
39 | input format. |
||
40 | |||
41 | spatpred() |
||
42 | |||
43 | The code for the various combinations of llprog_frame, llfieldsel and |
||
44 | prog_frame has been completed and verified with the tceh_conf23 |
||
45 | bitstream that uses all permissive combinations. |
||
46 | |||
47 | |||
48 | getpic.c |
||
49 | -------- |
||
50 | |||
51 | A small bug when storing an I- or P-frame: The prog_frame flag that |
||
52 | the decoder knows when storing the oldrefframe belongs to the current |
||
53 | refframe. Therefore the old value of the flag needs to be memorized. |
||
54 | |||
55 | |||
56 | store.c |
||
57 | ------- |
||
58 | |||
59 | A potential problem: the filename variables char outname[32], |
||
60 | tmpname[32] are statically dimensioned and quite small. |
||
61 | |||
62 | |||
63 | The concept of time in this video decoder software |
||
64 | -------------------------------------------------- |
||
65 | |||
66 | When decoding a non-scalable bitstream, the frame number (i.e. |
||
67 | temporal position) of the current I- or P-frame can be derived |
||
68 | implicitly from the number of preceding B-frames after they have been |
||
69 | decoded. Therefore the temporal_reference entry in the picture header |
||
70 | is somewhat redundant and does not necessarily have to be evaluated in |
||
71 | the decoding process. |
||
72 | |||
73 | Decoding of the enhancement layer of a spatial scalable hierarchy, |
||
74 | however, requires to know the temporal position of each frame at the |
||
75 | instant when it is decoded, since data from a lower layer reference |
||
76 | frame has to be incorporated. |
||
77 | |||
78 | In the architecture of this video-only decoder decoding of a spatial |
||
79 | scalable hierarchy of bitstreams is done by calling mpeg2decode once |
||
80 | for the base layer bitstream and a second time for the enhancement |
||
81 | layer bitstream, indicating where the decoded base layer frames can be |
||
82 | found (option -s<filename>). |
||
83 | |||
84 | Here the concept of time is only present in the form of frame numbers. |
||
85 | Therefore spatial scalable bitstream hierarchies can only be handled |
||
86 | under the assumption that base and enhancement layer bitstreams are |
||
87 | decoded to image sequences where corresponding images of both layers |
||
88 | have identical frame numbers. |
||
89 | |||
90 | More specifically this means that base and enhancement layer |
||
91 | bitstreams must contain video with the same frame rate. Furthermore |
||
92 | only the temporally coincident frame of the base layer can be accessed |
||
93 | for spatial prediction by the enhancement layer decoder, since it is |
||
94 | not possible to resolve unambiguously the lower_layer_temporal_reference |
||
95 | which is meant to further specify the lower layer reference frame. |
||
96 | |||
97 | ======================== SPATIAL.DOC ========================0 |
||
98 | |||
99 | Decoding a spatial scalable hierarchy of bitstreams |
||
100 | --------------------------------------------------- |
||
101 | |||
102 | With this video-only decoder decoding of a spatial scalable hierarchy |
||
103 | of bitstreams is done by calling mpeg2decode once for the base layer |
||
104 | bitstream and a second time for the enhancement layer bitstream, |
||
105 | indicating where the decoded base layer frames can be found |
||
106 | (using option -s and supplying <spatial base filename>). |
||
107 | |||
108 | mpeg2decode -r -o0 base.mpg base%d%c |
||
109 | mpeg2decode -r -o0 -f -s base%d%c enh.mpg enh%d |
||
110 | |||
111 | Note that the base layer decoder must not use the -f option to enforce |
||
112 | frame-wise storage. |
||
113 | |||
114 | Note further that only yuv image format (option -o0) is supported as |
||
115 | input format. |
||
116 | |||
117 | |||
118 | Timing / layer synchronisation in this video decoder software |
||
119 | ------------------------------------------------------------- |
||
120 | |||
121 | When decoding a non-scalable bitstream, the frame number (i.e. |
||
122 | temporal position) of the current I- or P-frame can be derived |
||
123 | implicitly from the number of preceding B-frames after they have been |
||
124 | decoded. Therefore the temporal_reference entry in the picture header |
||
125 | is somewhat redundant and does not necessarily have to be evaluated in |
||
126 | the decoding process. |
||
127 | |||
128 | Decoding of the enhancement layer of a spatial scalable hierarchy, |
||
129 | however, requires to know the temporal position of each frame at the |
||
130 | instant when it is decoded, since data from a lower layer reference |
||
131 | frame has to be incorporated. |
||
132 | |||
133 | The concept of time is only present in the form of frame numbers. |
||
134 | Therefore spatial scalable bitstream hierarchies can only be handled |
||
135 | under the assumption that base and enhancement layer bitstreams are |
||
136 | decoded to image sequences where corresponding images of both layers |
||
137 | have identical frame numbers. |
||
138 | |||
139 | More specifically this means that base and enhancement layer |
||
140 | bitstreams must contain video with the same frame rate. Furthermore |
||
141 | only the temporally coincident frame of the base layer can be accessed |
||
142 | for spatial prediction by the enhancement layer decoder, since it is |
||
143 | not possible to resolve unambiguously the lower_layer_temporal_reference |
||
144 | which is meant to further specify the lower layer reference frame. |
||
145 | |||
146 | Lower layer frames are read field-wise or frame-wise, depending on the |
||
147 | lower_layer_progressive_frame flag. Consistency between layers in this |
||
148 | respect is checked since the file format for frame and field pictures |
||
149 | differs. |
||
150 | |||
151 | |||
152 | |||
153 | |||
154 |