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Python

# firebird/base.py
# Copyright (C) 2005-2022 the SQLAlchemy authors and contributors
# <see AUTHORS file>
#
# This module is part of SQLAlchemy and is released under
# the MIT License: https://www.opensource.org/licenses/mit-license.php
r"""
.. dialect:: firebird
:name: Firebird
.. note::
The Firebird dialect within SQLAlchemy **is not currently supported**.
It is not tested within continuous integration and is likely to have
many issues and caveats not currently handled. Consider using the
`external dialect <https://github.com/pauldex/sqlalchemy-firebird>`_
instead.
.. deprecated:: 1.4 The internal Firebird dialect is deprecated and will be
removed in a future version. Use the external dialect.
Firebird Dialects
-----------------
Firebird offers two distinct dialects_ (not to be confused with a
SQLAlchemy ``Dialect``):
dialect 1
This is the old syntax and behaviour, inherited from Interbase pre-6.0.
dialect 3
This is the newer and supported syntax, introduced in Interbase 6.0.
The SQLAlchemy Firebird dialect detects these versions and
adjusts its representation of SQL accordingly. However,
support for dialect 1 is not well tested and probably has
incompatibilities.
Locking Behavior
----------------
Firebird locks tables aggressively. For this reason, a DROP TABLE may
hang until other transactions are released. SQLAlchemy does its best
to release transactions as quickly as possible. The most common cause
of hanging transactions is a non-fully consumed result set, i.e.::
result = engine.execute(text("select * from table"))
row = result.fetchone()
return
Where above, the ``CursorResult`` has not been fully consumed. The
connection will be returned to the pool and the transactional state
rolled back once the Python garbage collector reclaims the objects
which hold onto the connection, which often occurs asynchronously.
The above use case can be alleviated by calling ``first()`` on the
``CursorResult`` which will fetch the first row and immediately close
all remaining cursor/connection resources.
RETURNING support
-----------------
Firebird 2.0 supports returning a result set from inserts, and 2.1
extends that to deletes and updates. This is generically exposed by
the SQLAlchemy ``returning()`` method, such as::
# INSERT..RETURNING
result = table.insert().returning(table.c.col1, table.c.col2).\
values(name='foo')
print(result.fetchall())
# UPDATE..RETURNING
raises = empl.update().returning(empl.c.id, empl.c.salary).\
where(empl.c.sales>100).\
values(dict(salary=empl.c.salary * 1.1))
print(raises.fetchall())
.. _dialects: https://mc-computing.com/Databases/Firebird/SQL_Dialect.html
"""
import datetime
from sqlalchemy import exc
from sqlalchemy import sql
from sqlalchemy import types as sqltypes
from sqlalchemy import util
from sqlalchemy.engine import default
from sqlalchemy.engine import reflection
from sqlalchemy.sql import compiler
from sqlalchemy.sql import expression
from sqlalchemy.types import BIGINT
from sqlalchemy.types import BLOB
from sqlalchemy.types import DATE
from sqlalchemy.types import FLOAT
from sqlalchemy.types import INTEGER
from sqlalchemy.types import Integer
from sqlalchemy.types import NUMERIC
from sqlalchemy.types import SMALLINT
from sqlalchemy.types import TEXT
from sqlalchemy.types import TIME
from sqlalchemy.types import TIMESTAMP
RESERVED_WORDS = set(
[
"active",
"add",
"admin",
"after",
"all",
"alter",
"and",
"any",
"as",
"asc",
"ascending",
"at",
"auto",
"avg",
"before",
"begin",
"between",
"bigint",
"bit_length",
"blob",
"both",
"by",
"case",
"cast",
"char",
"character",
"character_length",
"char_length",
"check",
"close",
"collate",
"column",
"commit",
"committed",
"computed",
"conditional",
"connect",
"constraint",
"containing",
"count",
"create",
"cross",
"cstring",
"current",
"current_connection",
"current_date",
"current_role",
"current_time",
"current_timestamp",
"current_transaction",
"current_user",
"cursor",
"database",
"date",
"day",
"dec",
"decimal",
"declare",
"default",
"delete",
"desc",
"descending",
"disconnect",
"distinct",
"do",
"domain",
"double",
"drop",
"else",
"end",
"entry_point",
"escape",
"exception",
"execute",
"exists",
"exit",
"external",
"extract",
"fetch",
"file",
"filter",
"float",
"for",
"foreign",
"from",
"full",
"function",
"gdscode",
"generator",
"gen_id",
"global",
"grant",
"group",
"having",
"hour",
"if",
"in",
"inactive",
"index",
"inner",
"input_type",
"insensitive",
"insert",
"int",
"integer",
"into",
"is",
"isolation",
"join",
"key",
"leading",
"left",
"length",
"level",
"like",
"long",
"lower",
"manual",
"max",
"maximum_segment",
"merge",
"min",
"minute",
"module_name",
"month",
"names",
"national",
"natural",
"nchar",
"no",
"not",
"null",
"numeric",
"octet_length",
"of",
"on",
"only",
"open",
"option",
"or",
"order",
"outer",
"output_type",
"overflow",
"page",
"pages",
"page_size",
"parameter",
"password",
"plan",
"position",
"post_event",
"precision",
"primary",
"privileges",
"procedure",
"protected",
"rdb$db_key",
"read",
"real",
"record_version",
"recreate",
"recursive",
"references",
"release",
"reserv",
"reserving",
"retain",
"returning_values",
"returns",
"revoke",
"right",
"rollback",
"rows",
"row_count",
"savepoint",
"schema",
"second",
"segment",
"select",
"sensitive",
"set",
"shadow",
"shared",
"singular",
"size",
"smallint",
"snapshot",
"some",
"sort",
"sqlcode",
"stability",
"start",
"starting",
"starts",
"statistics",
"sub_type",
"sum",
"suspend",
"table",
"then",
"time",
"timestamp",
"to",
"trailing",
"transaction",
"trigger",
"trim",
"uncommitted",
"union",
"unique",
"update",
"upper",
"user",
"using",
"value",
"values",
"varchar",
"variable",
"varying",
"view",
"wait",
"when",
"where",
"while",
"with",
"work",
"write",
"year",
]
)
class _StringType(sqltypes.String):
"""Base for Firebird string types."""
def __init__(self, charset=None, **kw):
self.charset = charset
super(_StringType, self).__init__(**kw)
class VARCHAR(_StringType, sqltypes.VARCHAR):
"""Firebird VARCHAR type"""
__visit_name__ = "VARCHAR"
def __init__(self, length=None, **kwargs):
super(VARCHAR, self).__init__(length=length, **kwargs)
class CHAR(_StringType, sqltypes.CHAR):
"""Firebird CHAR type"""
__visit_name__ = "CHAR"
def __init__(self, length=None, **kwargs):
super(CHAR, self).__init__(length=length, **kwargs)
class _FBDateTime(sqltypes.DateTime):
def bind_processor(self, dialect):
def process(value):
if type(value) == datetime.date:
return datetime.datetime(value.year, value.month, value.day)
else:
return value
return process
colspecs = {sqltypes.DateTime: _FBDateTime}
ischema_names = {
"SHORT": SMALLINT,
"LONG": INTEGER,
"QUAD": FLOAT,
"FLOAT": FLOAT,
"DATE": DATE,
"TIME": TIME,
"TEXT": TEXT,
"INT64": BIGINT,
"DOUBLE": FLOAT,
"TIMESTAMP": TIMESTAMP,
"VARYING": VARCHAR,
"CSTRING": CHAR,
"BLOB": BLOB,
}
# TODO: date conversion types (should be implemented as _FBDateTime,
# _FBDate, etc. as bind/result functionality is required)
class FBTypeCompiler(compiler.GenericTypeCompiler):
def visit_boolean(self, type_, **kw):
return self.visit_SMALLINT(type_, **kw)
def visit_datetime(self, type_, **kw):
return self.visit_TIMESTAMP(type_, **kw)
def visit_TEXT(self, type_, **kw):
return "BLOB SUB_TYPE 1"
def visit_BLOB(self, type_, **kw):
return "BLOB SUB_TYPE 0"
def _extend_string(self, type_, basic):
charset = getattr(type_, "charset", None)
if charset is None:
return basic
else:
return "%s CHARACTER SET %s" % (basic, charset)
def visit_CHAR(self, type_, **kw):
basic = super(FBTypeCompiler, self).visit_CHAR(type_, **kw)
return self._extend_string(type_, basic)
def visit_VARCHAR(self, type_, **kw):
if not type_.length:
raise exc.CompileError(
"VARCHAR requires a length on dialect %s" % self.dialect.name
)
basic = super(FBTypeCompiler, self).visit_VARCHAR(type_, **kw)
return self._extend_string(type_, basic)
class FBCompiler(sql.compiler.SQLCompiler):
"""Firebird specific idiosyncrasies"""
ansi_bind_rules = True
# def visit_contains_op_binary(self, binary, operator, **kw):
# cant use CONTAINING b.c. it's case insensitive.
# def visit_not_contains_op_binary(self, binary, operator, **kw):
# cant use NOT CONTAINING b.c. it's case insensitive.
def visit_now_func(self, fn, **kw):
return "CURRENT_TIMESTAMP"
def visit_startswith_op_binary(self, binary, operator, **kw):
return "%s STARTING WITH %s" % (
binary.left._compiler_dispatch(self, **kw),
binary.right._compiler_dispatch(self, **kw),
)
def visit_not_startswith_op_binary(self, binary, operator, **kw):
return "%s NOT STARTING WITH %s" % (
binary.left._compiler_dispatch(self, **kw),
binary.right._compiler_dispatch(self, **kw),
)
def visit_mod_binary(self, binary, operator, **kw):
return "mod(%s, %s)" % (
self.process(binary.left, **kw),
self.process(binary.right, **kw),
)
def visit_alias(self, alias, asfrom=False, **kwargs):
if self.dialect._version_two:
return super(FBCompiler, self).visit_alias(
alias, asfrom=asfrom, **kwargs
)
else:
# Override to not use the AS keyword which FB 1.5 does not like
if asfrom:
alias_name = (
isinstance(alias.name, expression._truncated_label)
and self._truncated_identifier("alias", alias.name)
or alias.name
)
return (
self.process(alias.element, asfrom=asfrom, **kwargs)
+ " "
+ self.preparer.format_alias(alias, alias_name)
)
else:
return self.process(alias.element, **kwargs)
def visit_substring_func(self, func, **kw):
s = self.process(func.clauses.clauses[0])
start = self.process(func.clauses.clauses[1])
if len(func.clauses.clauses) > 2:
length = self.process(func.clauses.clauses[2])
return "SUBSTRING(%s FROM %s FOR %s)" % (s, start, length)
else:
return "SUBSTRING(%s FROM %s)" % (s, start)
def visit_length_func(self, function, **kw):
if self.dialect._version_two:
return "char_length" + self.function_argspec(function)
else:
return "strlen" + self.function_argspec(function)
visit_char_length_func = visit_length_func
def function_argspec(self, func, **kw):
# TODO: this probably will need to be
# narrowed to a fixed list, some no-arg functions
# may require parens - see similar example in the oracle
# dialect
if func.clauses is not None and len(func.clauses):
return self.process(func.clause_expr, **kw)
else:
return ""
def default_from(self):
return " FROM rdb$database"
def visit_sequence(self, seq, **kw):
return "gen_id(%s, 1)" % self.preparer.format_sequence(seq)
def get_select_precolumns(self, select, **kw):
"""Called when building a ``SELECT`` statement, position is just
before column list Firebird puts the limit and offset right
after the ``SELECT``...
"""
result = ""
if select._limit_clause is not None:
result += "FIRST %s " % self.process(select._limit_clause, **kw)
if select._offset_clause is not None:
result += "SKIP %s " % self.process(select._offset_clause, **kw)
result += super(FBCompiler, self).get_select_precolumns(select, **kw)
return result
def limit_clause(self, select, **kw):
"""Already taken care of in the `get_select_precolumns` method."""
return ""
def returning_clause(self, stmt, returning_cols):
columns = [
self._label_returning_column(stmt, c)
for c in expression._select_iterables(returning_cols)
]
return "RETURNING " + ", ".join(columns)
class FBDDLCompiler(sql.compiler.DDLCompiler):
"""Firebird syntactic idiosyncrasies"""
def visit_create_sequence(self, create):
"""Generate a ``CREATE GENERATOR`` statement for the sequence."""
# no syntax for these
# https://www.firebirdsql.org/manual/generatorguide-sqlsyntax.html
if create.element.start is not None:
raise NotImplementedError(
"Firebird SEQUENCE doesn't support START WITH"
)
if create.element.increment is not None:
raise NotImplementedError(
"Firebird SEQUENCE doesn't support INCREMENT BY"
)
if self.dialect._version_two:
return "CREATE SEQUENCE %s" % self.preparer.format_sequence(
create.element
)
else:
return "CREATE GENERATOR %s" % self.preparer.format_sequence(
create.element
)
def visit_drop_sequence(self, drop):
"""Generate a ``DROP GENERATOR`` statement for the sequence."""
if self.dialect._version_two:
return "DROP SEQUENCE %s" % self.preparer.format_sequence(
drop.element
)
else:
return "DROP GENERATOR %s" % self.preparer.format_sequence(
drop.element
)
def visit_computed_column(self, generated):
if generated.persisted is not None:
raise exc.CompileError(
"Firebird computed columns do not support a persistence "
"method setting; set the 'persisted' flag to None for "
"Firebird support."
)
return "GENERATED ALWAYS AS (%s)" % self.sql_compiler.process(
generated.sqltext, include_table=False, literal_binds=True
)
class FBIdentifierPreparer(sql.compiler.IdentifierPreparer):
"""Install Firebird specific reserved words."""
reserved_words = RESERVED_WORDS
illegal_initial_characters = compiler.ILLEGAL_INITIAL_CHARACTERS.union(
["_"]
)
def __init__(self, dialect):
super(FBIdentifierPreparer, self).__init__(dialect, omit_schema=True)
class FBExecutionContext(default.DefaultExecutionContext):
def fire_sequence(self, seq, type_):
"""Get the next value from the sequence using ``gen_id()``."""
return self._execute_scalar(
"SELECT gen_id(%s, 1) FROM rdb$database"
% self.identifier_preparer.format_sequence(seq),
type_,
)
class FBDialect(default.DefaultDialect):
"""Firebird dialect"""
name = "firebird"
supports_statement_cache = True
max_identifier_length = 31
supports_sequences = True
sequences_optional = False
supports_default_values = True
postfetch_lastrowid = False
supports_native_boolean = False
requires_name_normalize = True
supports_empty_insert = False
statement_compiler = FBCompiler
ddl_compiler = FBDDLCompiler
preparer = FBIdentifierPreparer
type_compiler = FBTypeCompiler
execution_ctx_cls = FBExecutionContext
colspecs = colspecs
ischema_names = ischema_names
construct_arguments = []
# defaults to dialect ver. 3,
# will be autodetected off upon
# first connect
_version_two = True
def __init__(self, *args, **kwargs):
util.warn_deprecated(
"The firebird dialect is deprecated and will be removed "
"in a future version. This dialect is superseded by the external "
"dialect https://github.com/pauldex/sqlalchemy-firebird.",
version="1.4",
)
super(FBDialect, self).__init__(*args, **kwargs)
def initialize(self, connection):
super(FBDialect, self).initialize(connection)
self._version_two = (
"firebird" in self.server_version_info
and self.server_version_info >= (2,)
) or (
"interbase" in self.server_version_info
and self.server_version_info >= (6,)
)
if not self._version_two:
# TODO: whatever other pre < 2.0 stuff goes here
self.ischema_names = ischema_names.copy()
self.ischema_names["TIMESTAMP"] = sqltypes.DATE
self.colspecs = {sqltypes.DateTime: sqltypes.DATE}
self.implicit_returning = self._version_two and self.__dict__.get(
"implicit_returning", True
)
def has_table(self, connection, table_name, schema=None):
"""Return ``True`` if the given table exists, ignoring
the `schema`."""
self._ensure_has_table_connection(connection)
tblqry = """
SELECT 1 AS has_table FROM rdb$database
WHERE EXISTS (SELECT rdb$relation_name
FROM rdb$relations
WHERE rdb$relation_name=?)
"""
c = connection.exec_driver_sql(
tblqry, [self.denormalize_name(table_name)]
)
return c.first() is not None
def has_sequence(self, connection, sequence_name, schema=None):
"""Return ``True`` if the given sequence (generator) exists."""
genqry = """
SELECT 1 AS has_sequence FROM rdb$database
WHERE EXISTS (SELECT rdb$generator_name
FROM rdb$generators
WHERE rdb$generator_name=?)
"""
c = connection.exec_driver_sql(
genqry, [self.denormalize_name(sequence_name)]
)
return c.first() is not None
@reflection.cache
def get_table_names(self, connection, schema=None, **kw):
# there are two queries commonly mentioned for this.
# this one, using view_blr, is at the Firebird FAQ among other places:
# https://www.firebirdfaq.org/faq174/
s = """
select rdb$relation_name
from rdb$relations
where rdb$view_blr is null
and (rdb$system_flag is null or rdb$system_flag = 0);
"""
# the other query is this one. It's not clear if there's really
# any difference between these two. This link:
# https://www.alberton.info/firebird_sql_meta_info.html#.Ur3vXfZGni8
# states them as interchangeable. Some discussion at [ticket:2898]
# SELECT DISTINCT rdb$relation_name
# FROM rdb$relation_fields
# WHERE rdb$system_flag=0 AND rdb$view_context IS NULL
return [
self.normalize_name(row[0])
for row in connection.exec_driver_sql(s)
]
@reflection.cache
def get_view_names(self, connection, schema=None, **kw):
# see https://www.firebirdfaq.org/faq174/
s = """
select rdb$relation_name
from rdb$relations
where rdb$view_blr is not null
and (rdb$system_flag is null or rdb$system_flag = 0);
"""
return [
self.normalize_name(row[0])
for row in connection.exec_driver_sql(s)
]
@reflection.cache
def get_view_definition(self, connection, view_name, schema=None, **kw):
qry = """
SELECT rdb$view_source AS view_source
FROM rdb$relations
WHERE rdb$relation_name=?
"""
rp = connection.exec_driver_sql(
qry, [self.denormalize_name(view_name)]
)
row = rp.first()
if row:
return row["view_source"]
else:
return None
@reflection.cache
def get_pk_constraint(self, connection, table_name, schema=None, **kw):
# Query to extract the PK/FK constrained fields of the given table
keyqry = """
SELECT se.rdb$field_name AS fname
FROM rdb$relation_constraints rc
JOIN rdb$index_segments se ON rc.rdb$index_name=se.rdb$index_name
WHERE rc.rdb$constraint_type=? AND rc.rdb$relation_name=?
"""
tablename = self.denormalize_name(table_name)
# get primary key fields
c = connection.exec_driver_sql(keyqry, ["PRIMARY KEY", tablename])
pkfields = [self.normalize_name(r["fname"]) for r in c.fetchall()]
return {"constrained_columns": pkfields, "name": None}
@reflection.cache
def get_column_sequence(
self, connection, table_name, column_name, schema=None, **kw
):
tablename = self.denormalize_name(table_name)
colname = self.denormalize_name(column_name)
# Heuristic-query to determine the generator associated to a PK field
genqry = """
SELECT trigdep.rdb$depended_on_name AS fgenerator
FROM rdb$dependencies tabdep
JOIN rdb$dependencies trigdep
ON tabdep.rdb$dependent_name=trigdep.rdb$dependent_name
AND trigdep.rdb$depended_on_type=14
AND trigdep.rdb$dependent_type=2
JOIN rdb$triggers trig ON
trig.rdb$trigger_name=tabdep.rdb$dependent_name
WHERE tabdep.rdb$depended_on_name=?
AND tabdep.rdb$depended_on_type=0
AND trig.rdb$trigger_type=1
AND tabdep.rdb$field_name=?
AND (SELECT count(*)
FROM rdb$dependencies trigdep2
WHERE trigdep2.rdb$dependent_name = trigdep.rdb$dependent_name) = 2
"""
genr = connection.exec_driver_sql(genqry, [tablename, colname]).first()
if genr is not None:
return dict(name=self.normalize_name(genr["fgenerator"]))
@reflection.cache
def get_columns(self, connection, table_name, schema=None, **kw):
# Query to extract the details of all the fields of the given table
tblqry = """
SELECT r.rdb$field_name AS fname,
r.rdb$null_flag AS null_flag,
t.rdb$type_name AS ftype,
f.rdb$field_sub_type AS stype,
f.rdb$field_length/
COALESCE(cs.rdb$bytes_per_character,1) AS flen,
f.rdb$field_precision AS fprec,
f.rdb$field_scale AS fscale,
COALESCE(r.rdb$default_source,
f.rdb$default_source) AS fdefault
FROM rdb$relation_fields r
JOIN rdb$fields f ON r.rdb$field_source=f.rdb$field_name
JOIN rdb$types t
ON t.rdb$type=f.rdb$field_type AND
t.rdb$field_name='RDB$FIELD_TYPE'
LEFT JOIN rdb$character_sets cs ON
f.rdb$character_set_id=cs.rdb$character_set_id
WHERE f.rdb$system_flag=0 AND r.rdb$relation_name=?
ORDER BY r.rdb$field_position
"""
# get the PK, used to determine the eventual associated sequence
pk_constraint = self.get_pk_constraint(connection, table_name)
pkey_cols = pk_constraint["constrained_columns"]
tablename = self.denormalize_name(table_name)
# get all of the fields for this table
c = connection.exec_driver_sql(tblqry, [tablename])
cols = []
while True:
row = c.fetchone()
if row is None:
break
name = self.normalize_name(row["fname"])
orig_colname = row["fname"]
# get the data type
colspec = row["ftype"].rstrip()
coltype = self.ischema_names.get(colspec)
if coltype is None:
util.warn(
"Did not recognize type '%s' of column '%s'"
% (colspec, name)
)
coltype = sqltypes.NULLTYPE
elif issubclass(coltype, Integer) and row["fprec"] != 0:
coltype = NUMERIC(
precision=row["fprec"], scale=row["fscale"] * -1
)
elif colspec in ("VARYING", "CSTRING"):
coltype = coltype(row["flen"])
elif colspec == "TEXT":
coltype = TEXT(row["flen"])
elif colspec == "BLOB":
if row["stype"] == 1:
coltype = TEXT()
else:
coltype = BLOB()
else:
coltype = coltype()
# does it have a default value?
defvalue = None
if row["fdefault"] is not None:
# the value comes down as "DEFAULT 'value'": there may be
# more than one whitespace around the "DEFAULT" keyword
# and it may also be lower case
# (see also https://tracker.firebirdsql.org/browse/CORE-356)
defexpr = row["fdefault"].lstrip()
assert defexpr[:8].rstrip().upper() == "DEFAULT", (
"Unrecognized default value: %s" % defexpr
)
defvalue = defexpr[8:].strip()
if defvalue == "NULL":
# Redundant
defvalue = None
col_d = {
"name": name,
"type": coltype,
"nullable": not bool(row["null_flag"]),
"default": defvalue,
"autoincrement": "auto",
}
if orig_colname.lower() == orig_colname:
col_d["quote"] = True
# if the PK is a single field, try to see if its linked to
# a sequence thru a trigger
if len(pkey_cols) == 1 and name == pkey_cols[0]:
seq_d = self.get_column_sequence(connection, tablename, name)
if seq_d is not None:
col_d["sequence"] = seq_d
cols.append(col_d)
return cols
@reflection.cache
def get_foreign_keys(self, connection, table_name, schema=None, **kw):
# Query to extract the details of each UK/FK of the given table
fkqry = """
SELECT rc.rdb$constraint_name AS cname,
cse.rdb$field_name AS fname,
ix2.rdb$relation_name AS targetrname,
se.rdb$field_name AS targetfname
FROM rdb$relation_constraints rc
JOIN rdb$indices ix1 ON ix1.rdb$index_name=rc.rdb$index_name
JOIN rdb$indices ix2 ON ix2.rdb$index_name=ix1.rdb$foreign_key
JOIN rdb$index_segments cse ON
cse.rdb$index_name=ix1.rdb$index_name
JOIN rdb$index_segments se
ON se.rdb$index_name=ix2.rdb$index_name
AND se.rdb$field_position=cse.rdb$field_position
WHERE rc.rdb$constraint_type=? AND rc.rdb$relation_name=?
ORDER BY se.rdb$index_name, se.rdb$field_position
"""
tablename = self.denormalize_name(table_name)
c = connection.exec_driver_sql(fkqry, ["FOREIGN KEY", tablename])
fks = util.defaultdict(
lambda: {
"name": None,
"constrained_columns": [],
"referred_schema": None,
"referred_table": None,
"referred_columns": [],
}
)
for row in c:
cname = self.normalize_name(row["cname"])
fk = fks[cname]
if not fk["name"]:
fk["name"] = cname
fk["referred_table"] = self.normalize_name(row["targetrname"])
fk["constrained_columns"].append(self.normalize_name(row["fname"]))
fk["referred_columns"].append(
self.normalize_name(row["targetfname"])
)
return list(fks.values())
@reflection.cache
def get_indexes(self, connection, table_name, schema=None, **kw):
qry = """
SELECT ix.rdb$index_name AS index_name,
ix.rdb$unique_flag AS unique_flag,
ic.rdb$field_name AS field_name
FROM rdb$indices ix
JOIN rdb$index_segments ic
ON ix.rdb$index_name=ic.rdb$index_name
LEFT OUTER JOIN rdb$relation_constraints
ON rdb$relation_constraints.rdb$index_name =
ic.rdb$index_name
WHERE ix.rdb$relation_name=? AND ix.rdb$foreign_key IS NULL
AND rdb$relation_constraints.rdb$constraint_type IS NULL
ORDER BY index_name, ic.rdb$field_position
"""
c = connection.exec_driver_sql(
qry, [self.denormalize_name(table_name)]
)
indexes = util.defaultdict(dict)
for row in c:
indexrec = indexes[row["index_name"]]
if "name" not in indexrec:
indexrec["name"] = self.normalize_name(row["index_name"])
indexrec["column_names"] = []
indexrec["unique"] = bool(row["unique_flag"])
indexrec["column_names"].append(
self.normalize_name(row["field_name"])
)
return list(indexes.values())