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Tom Lane
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6 months ago | |
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| .. | ||
| .gitignore | 3 years ago | |
| Makefile | 3 years ago | |
| README | 3 years ago | |
| bitmapset.c | 3 years ago | |
| copyfuncs.c | 3 years ago | |
| equalfuncs.c | 3 years ago | |
| extensible.c | 3 years ago | |
| gen_node_support.pl | 2 years ago | |
| list.c | 2 years ago | |
| makefuncs.c | 6 months ago | |
| meson.build | 3 years ago | |
| multibitmapset.c | 3 years ago | |
| nodeFuncs.c | 2 years ago | |
| nodes.c | 3 years ago | |
| outfuncs.c | 2 years ago | |
| params.c | 3 years ago | |
| print.c | 3 years ago | |
| queryjumblefuncs.c | 2 years ago | |
| read.c | 2 years ago | |
| readfuncs.c | 2 years ago | |
| tidbitmap.c | 3 years ago | |
| value.c | 3 years ago | |
README
src/backend/nodes/README
Node Structures
===============
Introduction
------------
Postgres uses "node" types to organize parse trees, plan trees, and
executor state trees. All objects that can appear in such trees must
be declared as node types. In addition, a few object types that aren't
part of parse/plan/execute node trees receive NodeTags anyway for
identification purposes, usually because they are involved in APIs
where we want to pass multiple object types through the same pointer.
The node structures are plain old C structures with the first field
being of type NodeTag. "Inheritance" is achieved by convention:
the first field can alternatively be of another node type.
Node types typically have support for being copied by copyObject(),
compared by equal(), serialized by outNode(), and deserialized by
nodeRead(). For some classes of Nodes, not all of these support
functions are required; for example, executor state nodes don't
presently need any of them. So far as the system is concerned,
output and read functions are only needed for node types that can
appear in parse trees stored in the catalogs, and for plan tree
nodes because those are serialized to be passed to parallel workers.
However, we provide output functions for some other node types as well,
because they are very handy for debugging. Currently, such coverage
exists for raw parsetrees and most planner data structures. However,
output coverage of raw parsetrees is incomplete: in particular, utility
statements are almost entirely unsupported.
Relevant Files
--------------
Utility functions for manipulating node structures reside in this
directory. Some support functions are automatically generated by the
gen_node_support.pl script, other functions are maintained manually.
To control the automatic generation of support functions, node types
and node fields can be annotated with pg_node_attr() specifications;
see further documentation in src/include/nodes/nodes.h.
FILES IN THIS DIRECTORY (src/backend/nodes/)
General-purpose node manipulation functions:
copyfuncs.c - copy a node tree (*)
equalfuncs.c - compare two node trees (*)
outfuncs.c - convert a node tree to text representation (*)
readfuncs.c - convert text representation back to a node tree (*)
makefuncs.c - creator functions for some common node types
nodeFuncs.c - some other general-purpose manipulation functions
queryjumblefuncs.c - compute a node tree for query jumbling (*)
(*) - Most functions in these files are generated by
gen_node_support.pl and #include'd there.
Specialized manipulation functions:
bitmapset.c - Bitmapset support
list.c - generic list support
multibitmapset.c - List-of-Bitmapset support
params.c - Param support
tidbitmap.c - TIDBitmap support
value.c - support for value nodes
FILES IN src/include/nodes/
Node definitions primarily appear in:
nodes.h - define node tags (NodeTag) (*)
primnodes.h - primitive nodes
parsenodes.h - parse tree nodes
pathnodes.h - path tree nodes and planner internal structures
plannodes.h - plan tree nodes
execnodes.h - executor nodes
memnodes.h - memory nodes
pg_list.h - generic list
(*) - Also #include's files generated by gen_node_support.pl.
Steps to Add a Node
-------------------
Suppose you want to define a node Foo:
1. Add the structure definition to the appropriate include/nodes/???.h file.
If you intend to inherit from, say a Plan node, put Plan as the first field
of your struct definition. (The T_Foo tag is created automatically.)
2. Check that the generated support functions in copyfuncs.funcs.c,
equalfuncs.funcs.c, outfuncs.funcs.c, queryjumblefuncs.funcs.c and
readfuncs.funcs.c look correct. Add attributes as necessary to control the
outcome. (For some classes of node types, you don't need all the support
functions. Use node attributes similar to those of related node types.)
3. Add cases to the functions in nodeFuncs.c as needed. There are many
other places you'll probably also need to teach about your new node
type. Best bet is to grep for references to one or two similar existing
node types to find all the places to touch.
(Except for frequently-created nodes, don't bother writing a creator
function in makefuncs.c.)
4. Consider testing your new code with COPY_PARSE_PLAN_TREES,
WRITE_READ_PARSE_PLAN_TREES, and RAW_EXPRESSION_COVERAGE_TEST to ensure
support has been added everywhere that it's necessary; see
pg_config_manual.h about these.
Adding a new node type moves the numbers associated with existing
tags, so you'll need to recompile the whole tree after doing this.
(--enable-depend usually helps.) It doesn't force initdb though,
because the numbers never go to disk. But altering or removing a node
type should usually be accompanied by an initdb-forcing catalog
version change, since the interpretation of serialized node trees
stored in system catalogs is affected by that. (If the node type
never appears in stored parse trees, as for example Plan nodes do not,
then a catversion change is not needed to change it.)