Coding of a spatial sampling of a two-dimensional information signal using sub-division

What is claimed is: 1. A decoder comprising: an extractor configured to extract a maximum region size and multi-tree subdivision information from a data stream representing an encoded video sequence; a sub-divider configured to spatially divide an array of information samples representing a spatially sampled portion of the video sequence into tree root regions of the maximum region size and subdividing, in accordance with a multi-tree subdivision information, at least some of the tree root regions into smaller simply connected regions of different sizes by recursively multi-partitioning said some tree root regions; and a reconstructor configured to reconstruct the array of samples from the data stream using the subdivision into the smaller simply connected regions, wherein the reconstructor is configured to perform a prediction of the array of information samples at a granularity which depends on the subdivision into smaller simply connected regions and the extractor is configured to extract subordinate multi-tree subdivision information of a subordinate multi-tree-subdivision from the data stream, and wherein the decoder further comprises a further subdivider configured to subdivide, in accordance with the subordinate multi-tree-subdivision information, at least some of the smaller simply connected regions into even smaller simply connected regions by recursively multi-partitioning said some of the smaller simply connected regions, wherein the reconstructor is configured to perform a retransformation from spectral to spatial domain in units of the even smaller simply connected regions, wherein the extractor is configured to extract a further maximum region size from the data stream, and wherein the further sub-divider is configured to divide each smaller simply connected region exceeding the further maximum region size into tree root sub-regions of the further maximum region size and subdivide, in accordance with the subordinate multi-tree- subdivision information, at least some of the tree root sub-regions into the even smaller simply connected regions, wherein the further sub-divider is configured to, in subdividing said some of smaller simply connected regions, check, for each smaller simply connected region, as to whether the respective smaller simply connected region exceeds the further maximum region size, and, if the respective smaller simply connected region does exceed the further maximum region size, divide the respective smaller simply connected region into tree root sub-regions of the further maximum region size; for each tree root sub-region, check the subordinate multi-tree-subdivision information as to whether the respective tree root sub-region is to be partitioned, and if the respective tree root sub-region is to be partitioned, partition the respective tree root sub-region into sub-sub-regions, and recursively repeat the check and partitioning for the sub-sub regions until no further partition is to be performed according to the subordinate multi-tree-subdivision information or a maximum hierarchy level of the subordinate multi-tree-subdivision is reached, and wherein for smaller simply connected region not exceeding the further maximum region size, the division into tree root sub-regions is skipped. 2. The decoder according to claim 1 , wherein the sub-divider is configured to perform the division of the array of information samples into tree root regions such that the tree root regions are rectangular blocks of a size determined by the maximum region size, regularly arranged in order to gaplessly cover the array of information samples. 3. The decoder according to claim 1 , wherein the sub-divider is configured to, check, for each tree root region, the multi-tree-subdivision information as to whether the respective tree root region is to be partitioned, and if the respective tree root region is to be partitioned, partition the respective tree root region into regions of a first hierarchy level according to a partition rule associated with the first hierarchy level, and recursively repeat the check and partitioning for the regions of the first hierarchy level in order to obtain regions of higher-order hierarchy levels using partition rules associated therewith, with stopping the recursive repetition when no further partitioning is to be performed according to the multi-tree subdivision information, or a maximum hierarchy level of the primary multi-tree-subdivision is reached, wherein regions of said at least some of tree root regions to be subdivided not further partitioned in accordance with the multi-tree-subdivision information, represent the smaller simply connected regions and the leaf regions of the multi-tree subdivision, respectively. 4. The decoder according to claim 3 , wherein the extractor is configured to extract also information about the maximum hierarchy level of the primary multi-tree-subdivision from the data stream. 5. The decoder according to claim 3 , wherein the sub-divider is configured to, in accordance with the partition rules associated with the first and higher-order hierarchy levels, perform a partition into sub-regions of equal size, the number of sub-regions thus obtained by one partitioning being common to all hierarchy levels. 6. The decoder according to claim 3 , wherein the extractor is configured to extract syntax elements associated with the leaf regions of said at least some of tree root regions to be subdivided, in a depth-first traversal processing order starting from first hierarchy level, from the data stream. 7. The decoder according to claim 3 , wherein the multi-tree subdivision information has a partition indication flag associated with each tree root region and region of the first and higher-order hierarchy levels not belonging to the regions of the maximum hierarchy level of the primary multi-tree-subdivision, respectively, the partition indication flags indicating as to whether the associated tree root region and region of the first and higher-order hierarchy level, respectively, is partitioned. 8. The decoder according to claim 7 , wherein the extractor is configured to context-adaptively decode each of the partition indication flags in a depth-first traversal processing order defined among the associated tree root regions and regions of the first and higher-order hierarchy levels, respectively, using contexts which are the same for partition indication flags relating to the same hierarchy level, but different for partition indication flags relating to different hierarchy levels. 9. The decoder according to claim 3 , wherein each leaf region has associated therewith coding parameters, the coding parameters being, for each leaf region, represented by a respective set of syntax elements, each syntax element being of a respective syntax element type out of a set of syntax element types, and wherein the extractor is configured to extract, for each tree root region, an inheritance information from the data stream, the inheritance information indicating as to whether inheritance of the coding parameter information is used within the respective tree root region or not, and if inheritance is indicated to be used; an inheritance region among the regions of the respective tree root region, which, according to the subdivision information, are to be partitioned, for the inheritance region of the tree root regions within which, according to the respective inheritance information inheritance is used, extract an inheritance subset including at least one syntax element of a predetermined syntax element type from the data stream, and copy the inheritance subset into, or use the inheritance subset as a prediction for, a corresponding inheritance subset of syntax elements within the