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121 lines
4.1 KiB
Plaintext
121 lines
4.1 KiB
Plaintext
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This directory contains an SQLite extension that implements a virtual
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table type that allows users to create, query and manipulate r-tree[1]
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data structures inside of SQLite databases. Users create, populate
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and query r-tree structures using ordinary SQL statements.
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1. SQL Interface
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1.1 Table Creation
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1.2 Data Manipulation
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1.3 Data Querying
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1.4 Introspection and Analysis
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2. Compilation and Deployment
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3. References
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1. SQL INTERFACE
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1.1 Table Creation.
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All r-tree virtual tables have an odd number of columns between
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3 and 11. Unlike regular SQLite tables, r-tree tables are strongly
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typed.
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The leftmost column is always the pimary key and contains 64-bit
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integer values. Each subsequent column contains a 32-bit real
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value. For each pair of real values, the first (leftmost) must be
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less than or equal to the second. R-tree tables may be
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constructed using the following syntax:
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CREATE VIRTUAL TABLE <name> USING rtree(<column-names>)
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For example:
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CREATE VIRTUAL TABLE boxes USING rtree(boxno, xmin, xmax, ymin, ymax);
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INSERT INTO boxes VALUES(1, 1.0, 3.0, 2.0, 4.0);
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Constructing a virtual r-tree table <name> creates the following three
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real tables in the database to store the data structure:
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<name>_node
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<name>_rowid
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<name>_parent
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Dropping or modifying the contents of these tables directly will
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corrupt the r-tree structure. To delete an r-tree from a database,
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use a regular DROP TABLE statement:
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DROP TABLE <name>;
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Dropping the main r-tree table automatically drops the automatically
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created tables.
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1.2 Data Manipulation (INSERT, UPDATE, DELETE).
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The usual INSERT, UPDATE or DELETE syntax is used to manipulate data
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stored in an r-tree table. Please note the following:
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* Inserting a NULL value into the primary key column has the
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same effect as inserting a NULL into an INTEGER PRIMARY KEY
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column of a regular table. The system automatically assigns
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an unused integer key value to the new record. Usually, this
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is one greater than the largest primary key value currently
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present in the table.
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* Attempting to insert a duplicate primary key value fails with
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an SQLITE_CONSTRAINT error.
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* Attempting to insert or modify a record such that the value
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stored in the (N*2)th column is greater than that stored in
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the (N*2+1)th column fails with an SQLITE_CONSTRAINT error.
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* When a record is inserted, values are always converted to
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the required type (64-bit integer or 32-bit real) as if they
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were part of an SQL CAST expression. Non-numeric strings are
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converted to zero.
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1.3 Queries.
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R-tree tables may be queried using all of the same SQL syntax supported
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by regular tables. However, some query patterns are more efficient
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than others.
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R-trees support fast lookup by primary key value (O(logN), like
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regular tables).
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Any combination of equality and range (<, <=, >, >=) constraints
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on spatial data columns may be used to optimize other queries. This
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is the key advantage to using r-tree tables instead of creating
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indices on regular tables.
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1.4 Introspection and Analysis.
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TODO: Describe rtreenode() and rtreedepth() functions.
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2. COMPILATION AND USAGE
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The easiest way to compile and use the RTREE extension is to build
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and use it as a dynamically loadable SQLite extension. To do this
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using gcc on *nix:
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gcc -shared rtree.c -o libSqliteRtree.so
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You may need to add "-I" flags so that gcc can find sqlite3ext.h
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and sqlite3.h. The resulting shared lib, libSqliteRtree.so, may be
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loaded into sqlite in the same way as any other dynamicly loadable
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extension.
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3. REFERENCES
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[1] Atonin Guttman, "R-trees - A Dynamic Index Structure For Spatial
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Searching", University of California Berkeley, 1984.
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[2] Norbert Beckmann, Hans-Peter Kriegel, Ralf Schneider, Bernhard Seeger,
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"The R*-tree: An Efficient and Robust Access Method for Points and
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Rectangles", Universitaet Bremen, 1990.
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