SAP HANA Hardware Questions
Below are the SAP HANA Hardware questions you might arise when you attend any interview or certification.
1.What is the reason for going In-memory?
One reason is the number of CPU cycles per second is increasing and the cost of processors is decreasing. For managing the data in memory, there is five-minute rule which is based on the suggestion that it costs more to wait for the data to be fetched from disk than it costs to keep data in memory so it depends on how often you fetch the data.
For example there is a table and no matter how large it is and this table is touched by a query at least once every 55 minutes, it is less expensive (in hardware costs) to keep it in memory than to read it from memory and if it is frequently accessed it is less expensive to store it in memory.
2.What is a Five-minute rule?
It is a rule of thumb for deciding whether a data item should be kept in memory, or stored on disk and read back into memory when required. The rule is “randomly accessed disk pages of cache are re-used every 5 minutes”.
3.What is multi-core CPU?
Multiple CPU’s on one chip or in one package is called multi-core CPU. .
Traditional databases for online transaction processing (OLTP) do not use current hardware efficiently.
4.What is Stall?
Waiting for data to be loaded from main memory into the CPU cache is called as Stalls.
5.What is SAP In-Memory Appliance (SAP HANA)?
HANA is an in-memory technique to store data that is particularly suited for handling very large amounts of tabular, or relational, data with extra ordinary performance. Common databases store tabular data row-wise. Reorganizing the data in memory column-wise brings a tremendous speed increase when accessing a subset of the data in each table row.
6.What are the components or products of HANA?
SAP HANA contains the following components.
• SAP HANA DATABASE
• SAP HANA Studio SAP HANA CLIENT
SAP HOST AGENT 7.2
• SAP HANA INFORMATION COMPOSER
• DIAGNOSTIC AGENT 7.3
SAP HANA client package for MS excel
SAP HANA UI for Information Access (INA)
SAP HANA AFL 1.0
Software Update Manager for SAP HANA
SAP LT Replication AddOn
SAP LT Replication Server
SAP HANA Direct Extractor Connection (DXC)
SAP Data Services 4.0
7.What are the different editions available in HANA appliance software?
Platform and Enterprise edition.
Platform edition is intended for customers who want to use ETL-based replication and already have a license for SAP BO Data Services.
Enterprise edition is intended for customers who want to use either trigger-based replication or ETL-based replication and do not already have all of the necessary licenses for SAP BO Data Services.
8.What is columnar and Row-Based Data Storage?
Fig: Row and Column-based storage
A database table contains data in the form of rows and columns. However Computer memory is organized as a linear structure. To store a table in linear memory, there are two options. A row-based storage stores a table as a sequence of records, each of which contains the fields of one row. In a columnar storage the entries of a column are stored in contiguous memory locations.
The SAP HANA database allows to specify whether a table is to be stored column-wise or row-wise. It is also possible to alter an existing table from columnar to row-based and vice versa.
Search operations in tabular data can be accelerated by organizing data in columns instead in rows.
9.What are the advantages of Column based tables?
Calculations are typically executed on single or a few columns only.
The table is searched based on values of a few columns.
The table has a large number of columns.
The table has a large number of rows and columnar operations are required (aggregate, scan, etc.).
High compression rates can be achieved because the majority of the columns contain only few distinct values (compared to number of rows).
10.What are the advantages of Row-based tables?
The application needs to only process a single record at one time (many selects and/or updates of single records).
The application typically needs to access a complete record (or row).
The columns contain mainly distinct values so that the compression rate would be low.
Neither aggregations nor fast searching are required.
The table has a small number of rows (e. g. configuration tables).
11.In which case the data to be stored in columnar storage?
To enable fast on-the-fly aggregations, ad-hoc reporting, and to benefit from compression mechanisms it is recommended that transaction data to be stored in a column-based table.
12.Is it possible to join tables of row-based with column-based tables?
13.Are column-based tables always the better choice than row-based tables?
No. There are also situations in which row based tables are advantageous.
14.What are the advantages of Columnar tables?
Higher Data Compression Rates
Higher Performance for Column Operations
Elimination of Additional Indexes
Elimination of Materialized Aggregates
15.What are the different Compression Techniques you know?
16.Why materialized aggregates are not required?
With a scanning speed of several gigabytes per millisecond, in-memory column stores, make it possible to calculate aggregates on large amounts of data on the fly with high performance. This is expected to eliminate the need for materialized aggregates in many cases.
17.What are the advantages of Eliminating materialized aggregates?
No additional tables for storing aggregate results means:
Simplified data model
Simplified application logic
Higher level of concurrency and
With the fly Aggregation we have aggregated values up to date
18.What is parallelization?
Column-based storage makes it easy to execute operations in parallel using multiple processor cores. In a column store data is already vertically partitioned means that operations on different columns can easily be processed in parallel. If multiple columns need to be searched or aggregated, each of these operations can be assigned to a different processor core. In addition operations on one column can be parallelized by partitioning the column into multiple sections that can be processed by different processor cores (core 3 and 4 below).