The parser stage consists of two parts:
The parser defined in
gram.y
and scan.l
is
built using the Unix tools bison
and flex.
The transformation process does modifications and augmentations to the data structures returned by the parser.
The parser has to check the query string (which arrives as plain text) for valid syntax. If the syntax is correct a parse tree is built up and handed back; otherwise an error is returned. The parser and lexer are implemented using the well-known Unix tools bison and flex.
The lexer is defined in the file
scan.l
and is responsible
for recognizing identifiers,
the SQL key words etc. For
every key word or identifier that is found, a token
is generated and handed to the parser.
The parser is defined in the file gram.y
and
consists of a set of grammar rules and
actions that are executed whenever a rule
is fired. The code of the actions (which is actually C code) is
used to build up the parse tree.
The file scan.l
is transformed to the C
source file scan.c
using the program
flex and gram.y
is
transformed to gram.c
using
bison. After these transformations
have taken place a normal C compiler can be used to create the
parser. Never make any changes to the generated C files as they
will be overwritten the next time flex
or bison is called.
The mentioned transformations and compilations are normally done automatically using the makefiles shipped with the PostgreSQL source distribution.
A detailed description of bison or
the grammar rules given in gram.y
would be
beyond the scope of this manual. There are many books and
documents dealing with flex and
bison. You should be familiar with
bison before you start to study the
grammar given in gram.y
otherwise you won't
understand what happens there.
The parser stage creates a parse tree using only fixed rules about the syntactic structure of SQL. It does not make any lookups in the system catalogs, so there is no possibility to understand the detailed semantics of the requested operations. After the parser completes, the transformation process takes the tree handed back by the parser as input and does the semantic interpretation needed to understand which tables, functions, and operators are referenced by the query. The data structure that is built to represent this information is called the query tree.
The reason for separating raw parsing from semantic analysis is that
system catalog lookups can only be done within a transaction, and we
do not wish to start a transaction immediately upon receiving a query
string. The raw parsing stage is sufficient to identify the transaction
control commands (BEGIN
, ROLLBACK
, etc.), and
these can then be correctly executed without any further analysis.
Once we know that we are dealing with an actual query (such as
SELECT
or UPDATE
), it is okay to
start a transaction if we're not already in one. Only then can the
transformation process be invoked.
The query tree created by the transformation process is structurally
similar to the raw parse tree in most places, but it has many differences
in detail. For example, a FuncCall
node in the
parse tree represents something that looks syntactically like a function
call. This might be transformed to either a FuncExpr
or Aggref
node depending on whether the referenced
name turns out to be an ordinary function or an aggregate function.
Also, information about the actual data types of columns and expression
results is added to the query tree.