Compression
You can compress and uncompress row data in tables and fragments and simple large objects in dbspaces. You can compress B-tree indexes.You can compress data in tables and table fragments to reduce the amount of disk space. You can also consolidate free space in a table or fragment and you can return this free space to the dbspace. Before you compress data, you can estimate the amount of disk space that you can save.
Compressing data, simple large objects, or indexes, consolidating data, and returning free space have the following benefits:
Compressing data, consolidating data, and returning free space have the following benefits:
- Significant savings in disk storage space
- Reduced disk usage for compressed fragments
- Significant saving of logical log usage, which saves more space and can prevent bottlenecks for high-throughput OLTP after the compression operation is completed.
- Fewer page reads because more rows can fit on a page
- Smaller buffer pools because more data fits in the same size pool
- Reduced I/O activity:
- More compressed rows than uncompressed rows fit on a page
- Log records for insert, update, and delete operations of compressed rows are smaller
- Ability to compress older fragments of time-fragmented data that are not often accessed, while leaving more recent data that is frequently accessed in uncompressed form
- Ability to free space no longer required for a table
- Faster backup and restore
If your applications run with high buffer cache hit ratios and high performance is more important than space usage, you might not want to compress your data, because compression might slightly decrease performance.
You can compress data and indexes in parallel.
Queries can access data in a compressed table.
Because compressed data covers fewer pages and has more rows per page than uncompressed data, the query optimizer might choose different plans after compression.
If you use Enterprise Replication, compressing data on one replication server does not affect the data on any other replication server.
If you use high-availability clusters, data that is compressed in the source table is compressed in the target table. You cannot perform compression operations on secondary servers, because secondary servers must have the same data and physical layout as the primary server.
The main alternative to compression is to buy more physical storage. The main alternative for reducing bottlenecks in IO-bound workloads is to buy more physical memory to enable the expansion of the buffer pools.