LazyIO of non-filter columns in the presence of filters

Background

This feature request started as a result of a large search that is performed with the following characteristics:

• The search fields are not part of partition, bucket or sort fields.
• The table is a very large table.
• The predicates result in very few rows compared to the scan size.
• The search columns are a significant subset of selection columns in the query.

Initial analysis showed that we could have a significant benefit by lazily reading the non-search columns only when we have a match. We explore the design and some benchmarks in subsequent sections.

Design

ORC-577 introduced filters during the read process. However the optimization did not include IO skips of non-filter columns.

We propose that the following take place during the read on a high level:

• Read the filter columns
• Apply the filter
• On the first hit read the non-filter columns

Read

The read process has the following changes:

The read process changes:

• Read Stripe used to plan the read of all (search + select) columns. This is enhanced to plan and fetch only the search columns. The rest of the stripe planning process optimizations remain unchanged e.g. partial read planning of the stripe based on RowGroup statistics.
• Next Batch identifies the processing that takes place when RecordReader.nextBatch is invoked.
  • Read Search Columns takes place instead of reading all the selected columns. This is in sync with the planning that has taken place during Read Stripe where only the search columns have been planned.
  • Apply Filter on the batch that at this point only includes search columns. Evaluate the result of the filter:
    • Size = 0 indicates all records have been filtered out. Given this we proceed to the next batch of search columns.
    • Size > 0 indicates that at least one record accepted by the filter. This record needs to be substantiated with other columns.
  • Plan Select Columns is invoked to perform read of the select columns. The planning happens as follows:
    • Determine the current position of the read within the stripe and plan the read for the select columns from this point forward to the end of the stripe.
    • The Read planning of select columns respects the row groups filtered out as a result of the stripe planning.
    • Fetch the select columns using the above plan.
  • Read Select Columns into the vectorized row batch
  • Return this batch.

The current implementation performs a single read for the select columns in a stripe.

The above diagram depicts a stripe with 7 Row Groups out of which RG2 and RG5 are selected by the filter. The current implementation does the following:

• Start the read planning process from the first match RG2
• Read to the end of the stripe that includes RG6
• Based on the above fetch skips RG0 and RG1 subject to compression block boundaries

The above logic could be enhanced to perform say 2 or n reads before reading to the end of stripe. The current implementation allows 0 reads before reading to the end of the stripe. The value of n could be configurable but should avoid too many short reads.

The read behavior changes as follows with multiple reads being allowed within a stripe for select columns:

The figure shows that we could read significantly fewer bytes by performing an additional read before reading to the end of stripe. This shall be included as a subsequent enhancement to this patch.

Tests

This offers significant savings on IO and CPU in scans that result in very rows as a result of the predicates.

We have seen the following from our tests:

• Table
  • Size: ~420 TB
  • Data fields: ~120
  • Partition fields: 3
• Scan
  • Search fields: 3 data fields with large (~ 1000 value) IN clauses compounded by OR.
  • Select fields: 16 data fields (includes the 3 search fields), 1 partition field
  • Search:
    • Size: ~180 TB
    • Records: 3.99 T
  • Selected:
    • Size: ~100 MB
    • Records: 1 M

We have observed the following reductions:

• The savings are more significant as you increase the number of select columns with respect to the search columns
• When the filter selects most data, no significant penalty observed as a result of 2 IOs compared to a single IO
  • We do have a penalty as a result of the filter application on the selected records.