# ansisql.py # Copyright (C) 2005, 2006, 2007 Michael Bayer mike_mp@zzzcomputing.com # # This module is part of SQLAlchemy and is released under # the MIT License: http://www.opensource.org/licenses/mit-license.php """Defines ANSI SQL operations. Contains default implementations for the abstract objects in the sql module. """ from sqlalchemy import schema, sql, engine, util, sql_util, exceptions from sqlalchemy.engine import default import string, re, sets, weakref, random ANSI_FUNCS = sets.ImmutableSet(['CURRENT_DATE', 'CURRENT_TIME', 'CURRENT_TIMESTAMP', 'CURRENT_USER', 'LOCALTIME', 'LOCALTIMESTAMP', 'SESSION_USER', 'USER']) RESERVED_WORDS = util.Set(['all', 'analyse', 'analyze', 'and', 'any', 'array', 'as', 'asc', 'asymmetric', 'authorization', 'between', 'binary', 'both', 'case', 'cast', 'check', 'collate', 'column', 'constraint', 'create', 'cross', 'current_date', 'current_role', 'current_time', 'current_timestamp', 'current_user', 'default', 'deferrable', 'desc', 'distinct', 'do', 'else', 'end', 'except', 'false', 'for', 'foreign', 'freeze', 'from', 'full', 'grant', 'group', 'having', 'ilike', 'in', 'initially', 'inner', 'intersect', 'into', 'is', 'isnull', 'join', 'leading', 'left', 'like', 'limit', 'localtime', 'localtimestamp', 'natural', 'new', 'not', 'notnull', 'null', 'off', 'offset', 'old', 'on', 'only', 'or', 'order', 'outer', 'overlaps', 'placing', 'primary', 'references', 'right', 'select', 'session_user', 'similar', 'some', 'symmetric', 'table', 'then', 'to', 'trailing', 'true', 'union', 'unique', 'user', 'using', 'verbose', 'when', 'where']) LEGAL_CHARACTERS = util.Set(string.ascii_lowercase + string.ascii_uppercase + string.digits + '_$') ILLEGAL_INITIAL_CHARACTERS = util.Set(string.digits + '$') class ANSIDialect(default.DefaultDialect): def __init__(self, cache_identifiers=True, **kwargs): super(ANSIDialect,self).__init__(**kwargs) self.identifier_preparer = self.preparer() self.cache_identifiers = cache_identifiers def create_connect_args(self): return ([],{}) def schemagenerator(self, *args, **kwargs): return ANSISchemaGenerator(self, *args, **kwargs) def schemadropper(self, *args, **kwargs): return ANSISchemaDropper(self, *args, **kwargs) def compiler(self, statement, parameters, **kwargs): return ANSICompiler(self, statement, parameters, **kwargs) def preparer(self): """Return an IdentifierPreparer. This object is used to format table and column names including proper quoting and case conventions. """ return ANSIIdentifierPreparer(self) class ANSICompiler(sql.Compiled): """Default implementation of Compiled. Compiles ClauseElements into ANSI-compliant SQL strings. """ __traverse_options__ = {'column_collections':False} def __init__(self, dialect, statement, parameters=None, **kwargs): """Construct a new ``ANSICompiler`` object. dialect Dialect to be used statement ClauseElement to be compiled parameters optional dictionary indicating a set of bind parameters specified with this Compiled object. These parameters are the *default* key/value pairs when the Compiled is executed, and also may affect the actual compilation, as in the case of an INSERT where the actual columns inserted will correspond to the keys present in the parameters. """ sql.Compiled.__init__(self, dialect, statement, parameters, **kwargs) # if we are insert/update. set to true when we visit an INSERT or UPDATE self.isinsert = self.isupdate = False # a dictionary of bind parameter keys to _BindParamClause instances. self.binds = {} # a dictionary of _BindParamClause instances to "compiled" names that are # actually present in the generated SQL self.bind_names = {} # a dictionary which stores the string representation for every ClauseElement # processed by this compiler. self.strings = {} # a dictionary which stores the string representation for ClauseElements # processed by this compiler, which are to be used in the FROM clause # of a select. items are often placed in "froms" as well as "strings" # and sometimes with different representations. self.froms = {} # slightly hacky. maps FROM clauses to WHERE clauses, and used in select # generation to modify the WHERE clause of the select. currently a hack # used by the oracle module. self.wheres = {} # when the compiler visits a SELECT statement, the clause object is appended # to this stack. various visit operations will check this stack to determine # additional choices (TODO: it seems to be all typemap stuff. shouldnt this only # apply to the topmost-level SELECT statement ?) self.select_stack = [] # a dictionary of result-set column names (strings) to TypeEngine instances, # which will be passed to a ResultProxy and used for resultset-level value conversion self.typemap = {} # a dictionary of select columns labels mapped to their "generated" label self.column_labels = {} # a dictionary of ClauseElement subclasses to counters, which are used to # generate truncated identifier names or "anonymous" identifiers such as # for aliases self.generated_ids = {} # True if this compiled represents an INSERT self.isinsert = False # True if this compiled represents an UPDATE self.isupdate = False # default formatting style for bind parameters self.bindtemplate = ":%s" # paramstyle from the dialect (comes from DBAPI) self.paramstyle = dialect.paramstyle # true if the paramstyle is positional self.positional = dialect.positional # a list of the compiled's bind parameter names, used to help # formulate a positional argument list self.positiontup = [] # an ANSIIdentifierPreparer that formats the quoting of identifiers self.preparer = dialect.identifier_preparer # for UPDATE and INSERT statements, a set of columns whos values are being set # from a SQL expression (i.e., not one of the bind parameter values). if present, # default-value logic in the Dialect knows not to fire off column defaults # and also knows postfetching will be needed to get the values represented by these # parameters. self.inline_params = None def after_compile(self): # this re will search for params like :param # it has a negative lookbehind for an extra ':' so that it doesnt match # postgres '::text' tokens match = re.compile(r'(? 0 def visit_calculatedclause(self, clause): self.strings[clause] = self.get_str(clause.clause_expr) def visit_cast(self, cast): if len(self.select_stack): # not sure if we want to set the typemap here... self.typemap.setdefault("CAST", cast.type) self.strings[cast] = "CAST(%s AS %s)" % (self.strings[cast.clause],self.strings[cast.typeclause]) def visit_function(self, func): if len(self.select_stack): self.typemap.setdefault(func.name, func.type) if not self.apply_function_parens(func): self.strings[func] = ".".join(func.packagenames + [func.name]) self.froms[func] = self.strings[func] else: self.strings[func] = ".".join(func.packagenames + [func.name]) + (not func.group and " " or "") + self.get_str(func.clause_expr) self.froms[func] = self.strings[func] def visit_compound_select(self, cs): text = string.join([self.get_str(c) for c in cs.selects], " " + cs.keyword + " ") group_by = self.get_str(cs.group_by_clause) if group_by: text += " GROUP BY " + group_by text += self.order_by_clause(cs) text += self.visit_select_postclauses(cs) self.strings[cs] = text self.froms[cs] = "(" + text + ")" def visit_unary(self, unary): s = self.get_str(unary.element) if unary.operator: s = unary.operator + " " + s if unary.modifier: s = s + " " + unary.modifier self.strings[unary] = s def visit_binary(self, binary): result = self.get_str(binary.left) if binary.operator is not None: result += " " + self.binary_operator_string(binary) result += " " + self.get_str(binary.right) self.strings[binary] = result def binary_operator_string(self, binary): return binary.operator def visit_bindparam(self, bindparam): # apply truncation to the ultimate generated name if bindparam.shortname != bindparam.key: self.binds.setdefault(bindparam.shortname, bindparam) if bindparam.unique: count = 1 key = bindparam.key # redefine the generated name of the bind param in the case # that we have multiple conflicting bind parameters. while self.binds.setdefault(key, bindparam) is not bindparam: tag = "_%d" % count key = bindparam.key + tag count += 1 bindparam.key = key self.strings[bindparam] = self.bindparam_string(self._truncate_bindparam(bindparam)) else: existing = self.binds.get(bindparam.key) if existing is not None and existing.unique: raise exceptions.CompileError("Bind parameter '%s' conflicts with unique bind parameter of the same name" % bindparam.key) self.strings[bindparam] = self.bindparam_string(self._truncate_bindparam(bindparam)) self.binds[bindparam.key] = bindparam def _truncate_bindparam(self, bindparam): if bindparam in self.bind_names: return self.bind_names[bindparam] bind_name = bindparam.key if len(bind_name) > self.dialect.max_identifier_length(): bind_name = self._truncated_identifier("bindparam", bind_name) # add to bind_names for translation self.bind_names[bindparam] = bind_name return bind_name def _truncated_identifier(self, ident_class, name): if (ident_class, name) in self.generated_ids: return self.generated_ids[(ident_class, name)] if len(name) > self.dialect.max_identifier_length(): counter = self.generated_ids.get(ident_class, 1) truncname = name[0:self.dialect.max_identifier_length() - 6] + "_" + hex(counter)[2:] self.generated_ids[ident_class] = counter + 1 else: truncname = name self.generated_ids[(ident_class, name)] = truncname return truncname def bindparam_string(self, name): return self.bindtemplate % name def visit_alias(self, alias): self.froms[alias] = self.get_from_text(alias.original) + " AS " + self.preparer.format_alias(alias) self.strings[alias] = self.get_str(alias.original) def visit_select(self, select): # the actual list of columns to print in the SELECT column list. inner_columns = util.OrderedDict() self.select_stack.append(select) for c in select._raw_columns: if hasattr(c, '_selectable'): s = c._selectable() else: self.traverse(c) inner_columns[self.get_str(c)] = c continue for co in s.columns: if select.use_labels: labelname = co._label if labelname is not None: l = co.label(labelname) self.traverse(l) inner_columns[labelname] = l else: self.traverse(co) inner_columns[self.get_str(co)] = co # TODO: figure this out, a ColumnClause with a select as a parent # is different from any other kind of parent elif select.is_selected_from and isinstance(co, sql._ColumnClause) and not co.is_literal and co.table is not None and not isinstance(co.table, sql.Select): # SQLite doesnt like selecting from a subquery where the column # names look like table.colname, so add a label synonomous with # the column name l = co.label(co.name) self.traverse(l) inner_columns[self.get_str(l.obj)] = l else: self.traverse(co) inner_columns[self.get_str(co)] = co self.select_stack.pop(-1) collist = string.join([self.get_str(v) for v in inner_columns.values()], ', ') text = "SELECT " text += self.visit_select_precolumns(select) text += collist whereclause = select.whereclause froms = [] for f in select.froms: if self.parameters is not None: # TODO: whack this feature in 0.4 # look at our own parameters, see if they # are all present in the form of BindParamClauses. if # not, then append to the above whereclause column conditions # matching those keys for c in f.columns: if sql.is_column(c) and self.parameters.has_key(c.key) and not self.binds.has_key(c.key): value = self.parameters[c.key] else: continue clause = c==value if whereclause is not None: whereclause = self.traverse(sql.and_(clause, whereclause), stop_on=util.Set([whereclause])) else: whereclause = clause self.traverse(whereclause) # special thingy used by oracle to redefine a join w = self.get_whereclause(f) if w is not None: # TODO: move this more into the oracle module if whereclause is not None: whereclause = self.traverse(sql.and_(w, whereclause), stop_on=util.Set([whereclause, w])) else: whereclause = w t = self.get_from_text(f) if t is not None: froms.append(t) if len(froms): text += " \nFROM " text += string.join(froms, ', ') else: text += self.default_from() if whereclause is not None: t = self.get_str(whereclause) if t: text += " \nWHERE " + t group_by = self.get_str(select.group_by_clause) if group_by: text += " GROUP BY " + group_by if select.having is not None: t = self.get_str(select.having) if t: text += " \nHAVING " + t text += self.order_by_clause(select) text += self.visit_select_postclauses(select) text += self.for_update_clause(select) self.strings[select] = text self.froms[select] = "(" + text + ")" def visit_select_precolumns(self, select): """Called when building a ``SELECT`` statement, position is just before column list.""" return select.distinct and "DISTINCT " or "" def visit_select_postclauses(self, select): """Called when building a ``SELECT`` statement, position is after all other ``SELECT`` clauses. Most DB syntaxes put ``LIMIT``/``OFFSET`` here. """ return (select.limit or select.offset) and self.limit_clause(select) or "" def order_by_clause(self, select): order_by = self.get_str(select.order_by_clause) if order_by: return " ORDER BY " + order_by else: return "" def for_update_clause(self, select): if select.for_update: return " FOR UPDATE" else: return "" def limit_clause(self, select): text = "" if select.limit is not None: text += " \n LIMIT " + str(select.limit) if select.offset is not None: if select.limit is None: text += " \n LIMIT -1" text += " OFFSET " + str(select.offset) return text def visit_table(self, table): self.froms[table] = self.preparer.format_table(table) self.strings[table] = "" def visit_join(self, join): righttext = self.get_from_text(join.right) if join.right._group_parenthesized(): righttext = "(" + righttext + ")" if join.isouter: self.froms[join] = (self.get_from_text(join.left) + " LEFT OUTER JOIN " + righttext + " ON " + self.get_str(join.onclause)) else: self.froms[join] = (self.get_from_text(join.left) + " JOIN " + righttext + " ON " + self.get_str(join.onclause)) self.strings[join] = self.froms[join] def visit_insert_column_default(self, column, default, parameters): """Called when visiting an ``Insert`` statement. For each column in the table that contains a ``ColumnDefault`` object, add a blank *placeholder* parameter so the ``Insert`` gets compiled with this column's name in its column and ``VALUES`` clauses. """ parameters.setdefault(column.key, None) def visit_update_column_default(self, column, default, parameters): """Called when visiting an ``Update`` statement. For each column in the table that contains a ``ColumnDefault`` object as an onupdate, add a blank *placeholder* parameter so the ``Update`` gets compiled with this column's name as one of its ``SET`` clauses. """ parameters.setdefault(column.key, None) def visit_insert_sequence(self, column, sequence, parameters): """Called when visiting an ``Insert`` statement. This may be overridden compilers that support sequences to place a blank *placeholder* parameter for each column in the table that contains a Sequence object, so the Insert gets compiled with this column's name in its column and ``VALUES`` clauses. """ pass def visit_insert_column(self, column, parameters): """Called when visiting an ``Insert`` statement. This may be overridden by compilers who disallow NULL columns being set in an ``Insert`` where there is a default value on the column (i.e. postgres), to remove the column for which there is a NULL insert from the parameter list. """ pass def visit_insert(self, insert_stmt): # scan the table's columns for defaults that have to be pre-set for an INSERT # add these columns to the parameter list via visit_insert_XXX methods default_params = {} class DefaultVisitor(schema.SchemaVisitor): def visit_column(s, c): self.visit_insert_column(c, default_params) def visit_column_default(s, cd): self.visit_insert_column_default(c, cd, default_params) def visit_sequence(s, seq): self.visit_insert_sequence(c, seq, default_params) vis = DefaultVisitor() for c in insert_stmt.table.c: if (isinstance(c, schema.SchemaItem) and (self.parameters is None or self.parameters.get(c.key, None) is None)): vis.traverse(c) self.isinsert = True colparams = self._get_colparams(insert_stmt, default_params) self.inline_params = util.Set() def create_param(col, p): if isinstance(p, sql._BindParamClause): self.binds[p.key] = p if p.shortname is not None: self.binds[p.shortname] = p return self.bindparam_string(self._truncate_bindparam(p)) else: self.inline_params.add(col) self.traverse(p) if isinstance(p, sql.ClauseElement) and not isinstance(p, sql.ColumnElement): return "(" + self.get_str(p) + ")" else: return self.get_str(p) text = ("INSERT INTO " + self.preparer.format_table(insert_stmt.table) + " (" + string.join([self.preparer.format_column(c[0]) for c in colparams], ', ') + ")" + " VALUES (" + string.join([create_param(*c) for c in colparams], ', ') + ")") self.strings[insert_stmt] = text def visit_update(self, update_stmt): # scan the table's columns for onupdates that have to be pre-set for an UPDATE # add these columns to the parameter list via visit_update_XXX methods default_params = {} class OnUpdateVisitor(schema.SchemaVisitor): def visit_column_onupdate(s, cd): self.visit_update_column_default(c, cd, default_params) vis = OnUpdateVisitor() for c in update_stmt.table.c: if (isinstance(c, schema.SchemaItem) and (self.parameters is None or self.parameters.get(c.key, None) is None)): vis.traverse(c) self.isupdate = True colparams = self._get_colparams(update_stmt, default_params) self.inline_params = util.Set() def create_param(col, p): if isinstance(p, sql._BindParamClause): self.binds[p.key] = p self.binds[p.shortname] = p return self.bindparam_string(self._truncate_bindparam(p)) else: self.traverse(p) self.inline_params.add(col) if isinstance(p, sql.ClauseElement) and not isinstance(p, sql.ColumnElement): return "(" + self.get_str(p) + ")" else: return self.get_str(p) text = "UPDATE " + self.preparer.format_table(update_stmt.table) + " SET " + string.join(["%s=%s" % (self.preparer.format_column(c[0]), create_param(*c)) for c in colparams], ', ') if update_stmt.whereclause: text += " WHERE " + self.get_str(update_stmt.whereclause) self.strings[update_stmt] = text def _get_colparams(self, stmt, default_params): """Organize ``UPDATE``/``INSERT`` ``SET``/``VALUES`` parameters into a list of tuples. Each tuple will contain the ``Column`` and a ``ClauseElement`` representing the value to be set (usually a ``_BindParamClause``, but could also be other SQL expressions.) The list of tuples will determine the columns that are actually rendered into the ``SET``/``VALUES`` clause of the rendered ``UPDATE``/``INSERT`` statement. It will also determine how to generate the list/dictionary of bind parameters at execution time (i.e. ``get_params()``). This list takes into account the `values` keyword specified to the statement, the parameters sent to this Compiled instance, and the default bind parameter values corresponding to the dialect's behavior for otherwise unspecified primary key columns. """ # no parameters in the statement, no parameters in the # compiled params - return binds for all columns if self.parameters is None and stmt.parameters is None: return [(c, sql.bindparam(c.key, type=c.type)) for c in stmt.table.columns] def to_col(key): if not isinstance(key, sql._ColumnClause): return stmt.table.columns.get(unicode(key), key) else: return key # if we have statement parameters - set defaults in the # compiled params if self.parameters is None: parameters = {} else: parameters = dict([(to_col(k), v) for k, v in self.parameters.iteritems()]) if stmt.parameters is not None: for k, v in stmt.parameters.iteritems(): parameters.setdefault(to_col(k), v) for k, v in default_params.iteritems(): parameters.setdefault(to_col(k), v) # create a list of column assignment clauses as tuples values = [] for c in stmt.table.columns: if parameters.has_key(c): value = parameters[c] if sql._is_literal(value): value = sql.bindparam(c.key, value, type=c.type, unique=True) values.append((c, value)) return values def visit_delete(self, delete_stmt): text = "DELETE FROM " + self.preparer.format_table(delete_stmt.table) if delete_stmt.whereclause: text += " WHERE " + self.get_str(delete_stmt.whereclause) self.strings[delete_stmt] = text def __str__(self): return self.get_str(self.statement) class ANSISchemaBase(engine.SchemaIterator): def find_alterables(self, tables): alterables = [] class FindAlterables(schema.SchemaVisitor): def visit_foreign_key_constraint(self, constraint): if constraint.use_alter and constraint.table in tables: alterables.append(constraint) findalterables = FindAlterables() for table in tables: for c in table.constraints: findalterables.traverse(c) return alterables class ANSISchemaGenerator(ANSISchemaBase): def __init__(self, dialect, connection, checkfirst=False, tables=None, **kwargs): super(ANSISchemaGenerator, self).__init__(connection, **kwargs) self.checkfirst = checkfirst self.tables = tables and util.Set(tables) or None self.preparer = dialect.preparer() self.dialect = dialect def get_column_specification(self, column, first_pk=False): raise NotImplementedError() def visit_metadata(self, metadata): collection = [t for t in metadata.table_iterator(reverse=False, tables=self.tables) if (not self.checkfirst or not self.dialect.has_table(self.connection, t.name, schema=t.schema))] for table in collection: table.accept_visitor(self) if self.dialect.supports_alter(): for alterable in self.find_alterables(collection): self.add_foreignkey(alterable) def visit_table(self, table): for column in table.columns: if column.default is not None: column.default.accept_visitor(self) #if column.onupdate is not None: # column.onupdate.accept_visitor(visitor) self.append("\nCREATE TABLE " + self.preparer.format_table(table) + " (") separator = "\n" # if only one primary key, specify it along with the column first_pk = False for column in table.columns: self.append(separator) separator = ", \n" self.append("\t" + self.get_column_specification(column, first_pk=column.primary_key and not first_pk)) if column.primary_key: first_pk = True for constraint in column.constraints: constraint.accept_visitor(self) # On some DB order is significant: visit PK first, then the # other constraints (engine.ReflectionTest.testbasic failed on FB2) if len(table.primary_key): table.primary_key.accept_visitor(self) for constraint in [c for c in table.constraints if c is not table.primary_key]: constraint.accept_visitor(self) self.append("\n)%s\n\n" % self.post_create_table(table)) self.execute() if hasattr(table, 'indexes'): for index in table.indexes: index.accept_visitor(self) def post_create_table(self, table): return '' def get_column_default_string(self, column): if isinstance(column.default, schema.PassiveDefault): if isinstance(column.default.arg, str): return repr(column.default.arg) else: return str(self._compile(column.default.arg, None)) else: return None def _compile(self, tocompile, parameters): """compile the given string/parameters using this SchemaGenerator's dialect.""" compiler = self.dialect.compiler(tocompile, parameters) compiler.compile() return compiler def visit_check_constraint(self, constraint): self.append(", \n\t") if constraint.name is not None: self.append("CONSTRAINT %s " % constraint.name) self.append(" CHECK (%s)" % constraint.sqltext) def visit_column_check_constraint(self, constraint): self.append(" ") self.append(" CHECK (%s)" % constraint.sqltext) def visit_primary_key_constraint(self, constraint): if len(constraint) == 0: return self.append(", \n\t") if constraint.name is not None: self.append("CONSTRAINT %s " % constraint.name) self.append("PRIMARY KEY ") self.append("(%s)" % (string.join([self.preparer.format_column(c) for c in constraint],', '))) def visit_foreign_key_constraint(self, constraint): if constraint.use_alter and self.dialect.supports_alter(): return self.append(", \n\t ") self.define_foreign_key(constraint) def add_foreignkey(self, constraint): self.append("ALTER TABLE %s ADD " % self.preparer.format_table(constraint.table)) self.define_foreign_key(constraint) self.execute() def define_foreign_key(self, constraint): if constraint.name is not None: self.append("CONSTRAINT %s " % constraint.name) self.append("FOREIGN KEY(%s) REFERENCES %s (%s)" % ( string.join([self.preparer.format_column(f.parent) for f in constraint.elements], ', '), self.preparer.format_table(list(constraint.elements)[0].column.table), string.join([self.preparer.format_column(f.column) for f in constraint.elements], ', ') )) if constraint.ondelete is not None: self.append(" ON DELETE %s" % constraint.ondelete) if constraint.onupdate is not None: self.append(" ON UPDATE %s" % constraint.onupdate) def visit_unique_constraint(self, constraint): self.append(", \n\t") if constraint.name is not None: self.append("CONSTRAINT %s " % constraint.name) self.append(" UNIQUE ") self.append("(%s)" % (string.join([self.preparer.format_column(c) for c in constraint],', '))) def visit_column(self, column): pass def visit_index(self, index): self.append('CREATE ') if index.unique: self.append('UNIQUE ') self.append('INDEX %s ON %s (%s)' \ % (index.name, self.preparer.format_table(index.table), string.join([self.preparer.format_column(c) for c in index.columns], ', '))) self.execute() class ANSISchemaDropper(ANSISchemaBase): def __init__(self, dialect, connection, checkfirst=False, tables=None, **kwargs): super(ANSISchemaDropper, self).__init__(connection, **kwargs) self.checkfirst = checkfirst self.tables = tables self.preparer = dialect.preparer() self.dialect = dialect def visit_metadata(self, metadata): collection = [t for t in metadata.table_iterator(reverse=True, tables=self.tables) if (not self.checkfirst or self.dialect.has_table(self.connection, t.name, schema=t.schema))] if self.dialect.supports_alter(): for alterable in self.find_alterables(collection): self.drop_foreignkey(alterable) for table in collection: table.accept_visitor(self) def visit_index(self, index): self.append("\nDROP INDEX " + index.name) self.execute() def drop_foreignkey(self, constraint): self.append("ALTER TABLE %s DROP CONSTRAINT %s" % (self.preparer.format_table(constraint.table), constraint.name)) self.execute() def visit_table(self, table): for column in table.columns: if column.default is not None: column.default.accept_visitor(self) self.append("\nDROP TABLE " + self.preparer.format_table(table)) self.execute() class ANSIDefaultRunner(engine.DefaultRunner): pass class ANSIIdentifierPreparer(object): """Handle quoting and case-folding of identifiers based on options.""" def __init__(self, dialect, initial_quote='"', final_quote=None, omit_schema=False): """Construct a new ``ANSIIdentifierPreparer`` object. initial_quote Character that begins a delimited identifier. final_quote Character that ends a delimited identifier. Defaults to `initial_quote`. omit_schema Prevent prepending schema name. Useful for databases that do not support schemae. """ self.dialect = dialect self.initial_quote = initial_quote self.final_quote = final_quote or self.initial_quote self.omit_schema = omit_schema self.__strings = {} def _escape_identifier(self, value): """Escape an identifier. Subclasses should override this to provide database-dependent escaping behavior. """ return value.replace('"', '""') def _quote_identifier(self, value): """Quote an identifier. Subclasses should override this to provide database-dependent quoting behavior. """ return self.initial_quote + self._escape_identifier(value) + self.final_quote def _fold_identifier_case(self, value): """Fold the case of an identifier. Subclasses should override this to provide database-dependent case folding behavior. """ return value # ANSI SQL calls for the case of all unquoted identifiers to be folded to UPPER. # some tests would need to be rewritten if this is done. #return value.upper() def _reserved_words(self): return RESERVED_WORDS def _legal_characters(self): return LEGAL_CHARACTERS def _illegal_initial_characters(self): return ILLEGAL_INITIAL_CHARACTERS def _requires_quotes(self, value, case_sensitive): """Return True if the given identifier requires quoting.""" return \ value in self._reserved_words() \ or (value[0] in self._illegal_initial_characters()) \ or bool(len([x for x in unicode(value) if x not in self._legal_characters()])) \ or (case_sensitive and value.lower() != value) def __generic_obj_format(self, obj, ident): if getattr(obj, 'quote', False): return self._quote_identifier(ident) if self.dialect.cache_identifiers: case_sens = getattr(obj, 'case_sensitive', None) try: return self.__strings[(ident, case_sens)] except KeyError: if self._requires_quotes(ident, getattr(obj, 'case_sensitive', ident == ident.lower())): self.__strings[(ident, case_sens)] = self._quote_identifier(ident) else: self.__strings[(ident, case_sens)] = ident return self.__strings[(ident, case_sens)] else: if self._requires_quotes(ident, getattr(obj, 'case_sensitive', ident == ident.lower())): return self._quote_identifier(ident) else: return ident def should_quote(self, object): return object.quote or self._requires_quotes(object.name, object.case_sensitive) def is_natural_case(self, object): return object.quote or self._requires_quotes(object.name, object.case_sensitive) def format_sequence(self, sequence): return self.__generic_obj_format(sequence, sequence.name) def format_label(self, label, name=None): return self.__generic_obj_format(label, name or label.name) def format_alias(self, alias): return self.__generic_obj_format(alias, alias.name) def format_table(self, table, use_schema=True, name=None): """Prepare a quoted table and schema name.""" if name is None: name = table.name result = self.__generic_obj_format(table, name) if use_schema and getattr(table, "schema", None): result = self.__generic_obj_format(table, table.schema) + "." + result return result def format_column(self, column, use_table=False, name=None): """Prepare a quoted column name.""" if name is None: name = column.name if not getattr(column, 'is_literal', False): if use_table: return self.format_table(column.table, use_schema=False) + "." + self.__generic_obj_format(column, name) else: return self.__generic_obj_format(column, name) else: # literal textual elements get stuck into ColumnClause alot, which shouldnt get quoted if use_table: return self.format_table(column.table, use_schema=False) + "." + name else: return name def format_column_with_table(self, column, column_name=None): """Prepare a quoted column name with table name.""" return self.format_column(column, use_table=True, name=column_name) dialect = ANSIDialect