SQLancer (Synthesized Query Lancer) is a tool to automatically test Database Management Systems (DBMS) in order to find logic bugs in their implementation. We refer to logic bugs as those bugs that cause the DBMS to fetch an incorrect result set (e.g., by omitting a record).
SQLancer operates in the following two phases:
- Database generation: The goal of this phase is to create a populated database, and stress the DBMS to increase the probability of causing an inconsistent database state that could be detected subsequently. First, random tables are created. Then, randomly SQL statements are chosen to generate, modify, and delete data. Also other statements, such as those to create indexes as well as views and to set DBMS-specific options are sent to the DBMS.
- Testing: The goal of this phase is to detect the logic bugs based on the generated database. See Testing Approaches below.
Requirements:
- Java 11 or above
- Maven (
sudo apt install maven
on Ubuntu) - The DBMS that you want to test (embedded DBMSs such as DuckDB, H2, and SQLite do not require a setup)
The following commands clone SQLancer, create a JAR, and start SQLancer to test SQLite using Non-optimizing Reference Engine Construction (NoREC):
git clone https://github.com/sqlancer/sqlancer
cd sqlancer
mvn package -DskipTests
cd target
java -jar sqlancer-*.jar --num-threads 4 sqlite3 --oracle NoREC
If the execution prints progress information every five seconds, then the tool works as expected. Note that SQLancer might find bugs in SQLite. Before reporting these, be sure to check that they can still be reproduced when using the latest development version. The shortcut CTRL+C can be used to terminate SQLancer manually. If SQLancer does not find any bugs, it executes infinitely. The option --num-tries
can be used to control after how many bugs SQLancer terminates. Alternatively, the option --timeout-seconds
can be used to specify the maximum duration that SQLancer is allowed to run.
If you launch SQLancer without parameters, available options and commands are displayed. Note that general options that are supported by all DBMS-testing implementations (e.g., --num-threads
) need to precede the name of DBMS to be tested (e.g., sqlite3
). Options that are supported only for specific DBMS (e.g., --test-rtree
for SQLite3), or options for which each testing implementation provides different values (e.g. --oracle NoREC
) need to go after the DBMS name.
Approach | Description |
---|---|
Pivoted Query Synthesis (PQS) | PQS is the first technique that we designed and implemented. It randomly selects a row, called a pivot row, for which a query is generated that is guaranteed to fetch the row. If the row is not contained in the result set, a bug has been detected. It is fully described here. PQS is the most powerful technique, but also requires more implementation effort than the other two techniques. It is currently unmaintained. |
Non-optimizing Reference Engine Construction (NoREC) | NoREC aims to find optimization bugs. It is described here. It translates a query that is potentially optimized by the DBMS to one for which hardly any optimizations are applicable, and compares the two result sets. A mismatch between the result sets indicates a bug in the DBMS. |
Ternary Logic Partitioning (TLP) | TLP partitions a query into three partitioning queries, whose results are composed and compare to the original query's result set. A mismatch in the result sets indicates a bug in the DBMS. In contrast to NoREC and PQS, it can detect bugs in advanced features such as aggregate functions. |
Please find the .bib
entries here.
Since SQL dialects differ widely, each DBMS to be tested requires a separate implementation.
DBMS | Status | Expression Generation | Description |
---|---|---|---|
SQLite | Working | Untyped | This implementation is currently affected by a significant performance regression that still needs to be investigated |
MySQL | Working | Untyped | Running this implementation likely uncovers additional, unreported bugs. |
PostgreSQL | Working | Typed | |
Citus (PostgreSQL Extension) | Working | Typed | This implementation extends the PostgreSQL implementation of SQLancer, and was contributed by the Citus team. |
MariaDB | Preliminary | Untyped | The implementation of this DBMS is very preliminary, since we stopped extending it after all but one of our bug reports were addressed. Running it likely uncovers additional, unreported bugs. |
CockroachDB | Working | Typed | |
TiDB | Working | Untyped | |
DuckDB | Working | Untyped, Generic | |
ClickHouse | Preliminary | Untyped, Generic | Implementing the different table engines was not convenient, which is why only a very preliminary implementation exists. |
TDEngine | Removed | Untyped | We removed the TDEngine implementation since all but one of our bug reports were still unaddressed five months after we reported them. |
OceanBase | Working | Untyped |
SQLancer stores logs in the target/logs
subdirectory. By default, the option --log-each-select
is enabled, which results in every SQL statement that is sent to the DBMS being logged. The corresponding file names are postfixed with -cur.log
. In addition, if SQLancer detects a logic bug, it creates a file with the extension .log
, in which the statements to reproduce the bug are logged.
After finding a bug, it is useful to produce a minimal test case before reporting the bug, to save the DBMS developers' time and effort. For many test cases, C-Reduce does a great job. In addition, we have been working on a SQL-specific reducer, which we plan to release soon.
We would appreciate it if you mention SQLancer when you report bugs found by it. We would also be excited to know if you are using SQLancer to find bugs, or if you have extended it to test another DBMS (also if you do not plan to contribute it to this project). SQLancer has found over 400 bugs in widely-used DBMS, which are listed here.
We have created a Slack workspace to discuss SQLancer, and DBMS testing in general. SQLancer's official Twitter handle is @sqlancer_dbms.
Official release are available on:
- A talk on Ternary Logic Partitioning (TLP) and SQLancer is available on YouTube.
- An (older) Pivoted Query Synthesis (PQS) talk is available on YouTube.
- PingCAP has implemented PQS, NoREC, and TLP in a tool called go-sqlancer.
- More information on our DBMS testing efforts and the bugs we found is available here.