"""plan execution of rql queries on multiple sources
the best way to understand what are we trying to acheive here is to read
the unit-tests in unittest_querier_planner.py
Split and execution specifications
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For a system source and a ldap user source (only EUser and its attributes
is supported, no group or such):
:EUser X:
1. fetch EUser X from both sources and return concatenation of results
:EUser X WHERE X in_group G, G name 'users':
* catch 1
1. fetch EUser X from both sources, store concatenation of results
into a temporary table
2. return the result of TMP X WHERE X in_group G, G name 'users' from
the system source
* catch 2
1. return the result of EUser X WHERE X in_group G, G name 'users'
from system source, that's enough (optimization of the sql querier
will avoid join on EUser, so we will directly get local eids)
:EUser X,L WHERE X in_group G, X login L, G name 'users':
1. fetch Any X,L WHERE X is EUser, X login L from both sources, store
concatenation of results into a temporary table
2. return the result of Any X, L WHERE X is TMP, X login LX in_group G,
G name 'users' from the system source
:Any X WHERE X owned_by Y:
* catch 1
1. fetch EUser X from both sources, store concatenation of results
into a temporary table
2. return the result of Any X WHERE X owned_by Y, Y is TMP from
the system source
* catch 2
1. return the result of Any X WHERE X owned_by Y
from system source, that's enough (optimization of the sql querier
will avoid join on EUser, so we will directly get local eids)
:organization: Logilab
:copyright: 2003-2008 LOGILAB S.A. (Paris, FRANCE), all rights reserved.
:contact: http://www.logilab.fr/ -- mailto:contact@logilab.fr
"""
__docformat__ = "restructuredtext en"
from copy import deepcopy
from itertools import imap, ifilterfalse
from logilab.common.compat import any
from logilab.common.decorators import cached
from rql.stmts import Union, Select
from rql.nodes import VariableRef, Comparison, Relation, Constant, Exists, Variable
from cubicweb import server
from cubicweb.common.utils import make_uid
from cubicweb.server.utils import cleanup_solutions
from cubicweb.server.ssplanner import SSPlanner, OneFetchStep, add_types_restriction
from cubicweb.server.mssteps import *
from cubicweb.server.sources import AbstractSource
Variable._ms_table_key = lambda x: x.name
Relation._ms_table_key = lambda x: x.r_type
# str() Constant.value to ensure generated table name won't be unicode
Constant._ms_table_key = lambda x: str(x.value)
AbstractSource.dont_cross_relations = ()
AbstractSource.cross_relations = ()
def allequals(solutions):
"""return true if all solutions are identical"""
sol = solutions.next()
for sol_ in solutions:
if sol_ != sol:
return False
return True
def need_aggr_step(select, sources, stepdefs=None):
"""return True if a temporary table is necessary to store some partial
results to execute the given query
"""
if len(sources) == 1:
# can do everything at once with a single source
return False
if select.orderby or select.groupby or select.has_aggregat:
# if more than one source, we need a temp table to deal with sort /
# groups / aggregat if :
# * the rqlst won't be splitted (in the other case the last query
# using partial temporary table can do sort/groups/aggregat without
# the need for a later AggrStep)
# * the rqlst is splitted in multiple steps and there are more than one
# final step
if stepdefs is None:
return True
has_one_final = False
fstepsolindices = set()
for stepdef in stepdefs:
if stepdef[-1]:
if has_one_final or frozenset(stepdef[2]) != fstepsolindices:
return True
has_one_final = True
else:
fstepsolindices.update(stepdef[2])
return False
def copy_node(newroot, node, subparts=()):
newnode = node.__class__(*node.initargs(newroot))
for part in subparts:
newnode.append(part)
return newnode
def same_scope(var):
"""return true if the variable is always used in the same scope"""
try:
return var.stinfo['samescope']
except KeyError:
for rel in var.stinfo['relations']:
if not rel.scope is var.scope:
var.stinfo['samescope'] = False
return False
var.stinfo['samescope'] = True
return True
def select_group_sort(select): # XXX something similar done in rql2sql
# add variables used in groups and sort terms to the selection
# if necessary
if select.groupby:
for vref in select.groupby:
if not vref in select.selection:
select.append_selected(vref.copy(select))
for sortterm in select.orderby:
for vref in sortterm.iget_nodes(VariableRef):
if not vref in select.get_selected_variables():
# we can't directly insert sortterm.term because it references
# a variable of the select before the copy.
# XXX if constant term are used to define sort, their value
# may necessite a decay
select.append_selected(vref.copy(select))
if select.groupby and not vref in select.groupby:
select.add_group_var(vref.copy(select))
class PartPlanInformation(object):
"""regroups necessary information to execute some part of a "global" rql
query ("global" means as received by the querier, which may result in
several internal queries, e.g. parts, due to security insertions)
it exposes as well some methods helping in executing this part on a
multi-sources repository, modifying its internal structure during the
process
:attr solutions: a list of mappings (varname -> vartype)
:attr sourcesvars:
a dictionnary telling for each source which variable/solution are
supported, of the form {source : {varname: [solution index, ]}}
"""
def __init__(self, plan, rqlst, rqlhelper=None):
self.needsplit = False
self.temptable = None
self.finaltable = None
self.plan = plan
self.rqlst = rqlst
self._session = plan.session
self._solutions = rqlst.solutions
self._solindices = range(len(self._solutions))
# source : {var: [solution index, ]}
self.sourcesvars = self._sourcesvars = {}
# source : {relation: set(child variable and constant)}
self._crossrelations = {}
# dictionnary of variables which are linked to each other using a non
# final relation which is supported by multiple sources
self._linkedvars = {}
self._crosslinkedvars = {}
# processing
self._compute_sourcesvars()
self._remove_invalid_sources()
self._compute_needsplit()
self.sourcesvars = {}
for k, v in self._sourcesvars.iteritems():
self.sourcesvars[k] = {}
for k2, v2 in v.iteritems():
self.sourcesvars[k][k2] = v2.copy()
self._inputmaps = {}
if rqlhelper is not None: # else test
self._insert_identity_variable = rqlhelper._annotator.rewrite_shared_optional
def copy_solutions(self, solindices):
return [self._solutions[solidx].copy() for solidx in solindices]
@property
@cached
def part_sources(self):
if self._sourcesvars:
return tuple(sorted(self._sourcesvars))
return (self._session.repo.system_source,)
@property
@cached
def _sys_source_set(self):
return frozenset((self._session.repo.system_source, solindex)
for solindex in self._solindices)
@cached
def _norel_support_set(self, relation):
"""return a set of (source, solindex) where source doesn't support the
relation
"""
return frozenset((source, solidx) for source in self._session.repo.sources
for solidx in self._solindices
if not ((source.support_relation(relation.r_type) and
not self.crossed_relation(source, relation))
or relation.r_type in source.dont_cross_relations))
def _compute_sourcesvars(self):
"""compute for each variable/solution in the rqlst which sources support
them
"""
repo = self._session.repo
eschema = repo.schema.eschema
sourcesvars = self._sourcesvars
# find for each source which variable/solution are supported
for varname, varobj in self.rqlst.defined_vars.items():
# if variable has an eid specified, we can get its source directly
# NOTE: use uidrels and not constnode to deal with "X eid IN(1,2,3,4)"
if varobj.stinfo['uidrels']:
vrels = varobj.stinfo['relations'] - varobj.stinfo['uidrels']
for rel in varobj.stinfo['uidrels']:
if rel.neged(strict=True) or rel.operator() != '=':
continue
for const in rel.children[1].get_nodes(Constant):
eid = const.eval(self.plan.args)
source = self._session.source_from_eid(eid)
if vrels and not any(source.support_relation(r.r_type)
for r in vrels):
self._set_source_for_var(repo.system_source, varobj)
else:
self._set_source_for_var(source, varobj)
continue
rels = varobj.stinfo['relations']
if not rels and not varobj.stinfo['typerels']:
# (rare) case where the variable has no type specified nor
# relation accessed ex. "Any MAX(X)"
self._set_source_for_var(repo.system_source, varobj)
continue
for i, sol in enumerate(self._solutions):
vartype = sol[varname]
# skip final variable
if eschema(vartype).is_final():
break
for source in repo.sources:
if source.support_entity(vartype):
# the source support the entity type, though we will
# actually have to fetch from it only if
# * the variable isn't invariant
# * at least one supported relation specified
if not varobj._q_invariant or \
any(imap(source.support_relation,
(r.r_type for r in rels if r.r_type != 'eid'))):
sourcesvars.setdefault(source, {}).setdefault(varobj, set()).add(i)
# if variable is not invariant and is used by a relation
# not supported by this source, we'll have to split the
# query
if not varobj._q_invariant and any(ifilterfalse(
source.support_relation, (r.r_type for r in rels))):
self.needsplit = True
def _handle_cross_relation(self, rel, relsources, vsources):
crossvars = None
for source in relsources:
if rel.r_type in source.cross_relations:
crossvars = set(x.variable for x in rel.get_nodes(VariableRef))
crossvars.update(frozenset(x for x in rel.get_nodes(Constant)))
assert len(crossvars) == 2
ssource = self._session.repo.system_source
needsplit = True
flag = 0
for v in crossvars:
if isinstance(v, Constant):
self._sourcesvars[ssource][v] = set(self._solindices)
if len(vsources[v]) == 1:
if iter(vsources[v]).next()[0].uri == 'system':
flag = 1
for ov in crossvars:
if ov is not v and ov._q_invariant:
ssset = frozenset((ssource,))
self._remove_sources(ov, vsources[ov] - ssset)
else:
for ov in crossvars:
if ov is not v and ov._q_invariant:
needsplit = False
break
else:
continue
if not rel.neged(strict=True):
break
else:
self._crossrelations.setdefault(source, {})[rel] = crossvars
if not flag:
self._sourcesvars.setdefault(source, {})[rel] = set(self._solindices)
self._sourcesvars.setdefault(ssource, {})[rel] = set(self._solindices)
if needsplit:
self.needsplit = True
return crossvars is None
def _remove_invalid_sources(self):
"""removes invalid sources from `sourcesvars` member according to
traversed relations and their properties (which sources support them,
can they cross sources, etc...)
"""
repo = self._session.repo
rschema = repo.schema.rschema
vsources = {}
for rel in self.rqlst.iget_nodes(Relation):
# process non final relations only
# note: don't try to get schema for 'is' relation (not available
# during bootstrap)
if not rel.is_types_restriction() and not rschema(rel.r_type).is_final():
# nothing to do if relation is not supported by multiple sources
# or if some source has it listed in its cross_relations
# attribute
#
# XXX code below don't deal if some source allow relation
# crossing but not another one
relsources = repo.rel_type_sources(rel.r_type)
crossvars = None
if len(relsources) < 2:
# filter out sources being there because they have this
# relation in their dont_cross_relations attribute
relsources = [source for source in relsources
if source.support_relation(rel.r_type)]
if relsources:
# this means the relation is using a variable inlined as
# a constant and another unsupported variable, in which
# case we put the relation in sourcesvars
self._sourcesvars.setdefault(relsources[0], {})[rel] = set(self._solindices)
continue
lhs, rhs = rel.get_variable_parts()
lhsv, rhsv = getattr(lhs, 'variable', lhs), getattr(rhs, 'variable', rhs)
# update dictionnary of sources supporting lhs and rhs vars
if not lhsv in vsources:
vsources[lhsv] = self._term_sources(lhs)
if not rhsv in vsources:
vsources[rhsv] = self._term_sources(rhs)
if self._handle_cross_relation(rel, relsources, vsources):
self._linkedvars.setdefault(lhsv, set()).add((rhsv, rel))
self._linkedvars.setdefault(rhsv, set()).add((lhsv, rel))
else:
self._crosslinkedvars.setdefault(lhsv, set()).add((rhsv, rel))
self._crosslinkedvars.setdefault(rhsv, set()).add((lhsv, rel))
for term in self._linkedvars:
self._remove_sources_until_stable(term, vsources)
if len(self._sourcesvars) > 1 and hasattr(self.plan.rqlst, 'main_relations'):
# the querier doesn't annotate write queries, need to do it here
self.plan.annotate_rqlst()
# insert/update/delete queries, we may get extra information from
# the main relation (eg relations to the left of the WHERE
if self.plan.rqlst.TYPE == 'insert':
inserted = dict((vref.variable, etype)
for etype, vref in self.plan.rqlst.main_variables)
else:
inserted = {}
for rel in self.plan.rqlst.main_relations:
if not rschema(rel.r_type).is_final():
# nothing to do if relation is not supported by multiple sources
if len(repo.rel_type_sources(rel.r_type)) < 2:
continue
lhs, rhs = rel.get_variable_parts()
try:
lhsv = self._extern_term(lhs, vsources, inserted)
rhsv = self._extern_term(rhs, vsources, inserted)
except KeyError, ex:
continue
norelsup = self._norel_support_set(rel)
self._remove_var_sources(lhsv, norelsup, rhsv, vsources)
self._remove_var_sources(rhsv, norelsup, lhsv, vsources)
# cleanup linked var
for var, linkedrelsinfo in self._linkedvars.iteritems():
self._linkedvars[var] = frozenset(x[0] for x in linkedrelsinfo)
# if there are other sources than the system source, consider simplified
# variables'source
if self._sourcesvars and self._sourcesvars.keys() != [self._session.repo.system_source]:
# add source for rewritten constants to sourcesvars
for vconsts in self.rqlst.stinfo['rewritten'].itervalues():
const = vconsts[0]
eid = const.eval(self.plan.args)
source = self._session.source_from_eid(eid)
if source is self._session.repo.system_source:
for const in vconsts:
self._set_source_for_var(source, const)
elif source in self._sourcesvars:
source_scopes = frozenset(v.scope for v in self._sourcesvars[source])
for const in vconsts:
if const.scope in source_scopes:
self._set_source_for_var(source, const)
def _extern_term(self, term, vsources, inserted):
var = term.variable
if var.stinfo['constnode']:
termv = var.stinfo['constnode']
vsources[termv] = self._term_sources(termv)
elif var in inserted:
termv = var
source = self._session.repo.locate_etype_source(inserted[var])
vsources[termv] = set((source, solindex) for solindex in self._solindices)
else:
termv = self.rqlst.defined_vars[var.name]
if not termv in vsources:
vsources[termv] = self._term_sources(termv)
return termv
def _remove_sources_until_stable(self, var, vsources):
sourcesvars = self._sourcesvars
for ovar, rel in self._linkedvars.get(var, ()):
if not var.scope is ovar.scope and rel.scope.neged(strict=True):
# can't get information from relation inside a NOT exists
# where variables don't belong to the same scope
continue
if not (var.scope is rel.scope and ovar.scope is rel.scope) and rel.ored():
continue
relsources = self._session.repo.rel_type_sources(rel.r_type)
if rel.neged(strict=True) and (
len(relsources) < 2
or not isinstance(ovar, Variable)
or ovar.valuable_references() != 1
or any(sourcesvars[source][var] != sourcesvars[source][ovar]
for source in relsources
if var in sourcesvars.get(source, ())
and ovar in sourcesvars.get(source, ()))):
# neged relation doesn't allow to infer variable sources unless we're
# on a multisource relation for a variable only used by this relation
# (eg "Any X WHERE NOT X multisource_rel Y" and over is Y), iif
continue
norelsup = self._norel_support_set(rel)
# compute invalid sources for variables and remove them
self._remove_var_sources(var, norelsup, ovar, vsources)
self._remove_var_sources(ovar, norelsup, var, vsources)
def _remove_var_sources(self, var, norelsup, ovar, vsources):
"""remove invalid sources for var according to ovar's sources and the
relation between those two variables.
"""
varsources = vsources[var]
invalid_sources = varsources - (vsources[ovar] | norelsup)
if invalid_sources:
self._remove_sources(var, invalid_sources)
varsources -= invalid_sources
self._remove_sources_until_stable(var, vsources)
def _compute_needsplit(self):
"""tell according to sourcesvars if the rqlst has to be splitted for
execution among multiple sources
the execution has to be split if
* a source support an entity (non invariant) but doesn't support a
relation on it
* a source support an entity which is accessed by an optional relation
* there is more than one source and either all sources'supported
variable/solutions are not equivalent or multiple variables have to
be fetched from some source
"""
# NOTE: < 2 since may be 0 on queries such as Any X WHERE X eid 2
if len(self._sourcesvars) < 2:
self.needsplit = False
elif not self.needsplit:
if not allequals(self._sourcesvars.itervalues()):
self.needsplit = True
else:
sample = self._sourcesvars.itervalues().next()
if len(sample) > 1 and any(v for v in sample
if not v in self._linkedvars
and not v in self._crosslinkedvars):
self.needsplit = True
def _set_source_for_var(self, source, var):
self._sourcesvars.setdefault(source, {})[var] = set(self._solindices)
def _term_sources(self, term):
"""returns possible sources for terms `term`"""
if isinstance(term, Constant):
source = self._session.source_from_eid(term.eval(self.plan.args))
return set((source, solindex) for solindex in self._solindices)
else:
var = getattr(term, 'variable', term)
sources = [source for source, varobjs in self.sourcesvars.iteritems()
if var in varobjs]
return set((source, solindex) for source in sources
for solindex in self.sourcesvars[source][var])
def _remove_sources(self, var, sources):
"""removes invalid sources (`sources`) from `sourcesvars`
:param sources: the list of sources to remove
:param var: the analyzed variable
"""
sourcesvars = self._sourcesvars
for source, solindex in sources:
try:
sourcesvars[source][var].remove(solindex)
except KeyError:
return # may occur with subquery column alias
if not sourcesvars[source][var]:
del sourcesvars[source][var]
if not sourcesvars[source]:
del sourcesvars[source]
def crossed_relation(self, source, relation):
return relation in self._crossrelations.get(source, ())
def part_steps(self):
"""precompute necessary part steps before generating actual rql for
each step. This is necessary to know if an aggregate step will be
necessary or not.
"""
steps = []
select = self.rqlst
rschema = self.plan.schema.rschema
for source in self.part_sources:
sourcevars = self._sourcesvars[source]
while sourcevars:
# take a variable randomly, and all variables supporting the
# same solutions
var, solindices = self._choose_var(sourcevars)
if source.uri == 'system':
# ensure all variables are available for the latest step
# (missing one will be available from temporary tables
# of previous steps)
scope = select
variables = scope.defined_vars.values() + scope.aliases.values()
sourcevars.clear()
else:
scope = var.scope
variables = self._expand_vars(var, source, sourcevars, scope, solindices)
if not sourcevars:
del self._sourcesvars[source]
# find which sources support the same variables/solutions
sources = self._expand_sources(source, variables, solindices)
# suppose this is a final step until the contrary is proven
final = scope is select
# set of variables which should be additionaly selected when
# possible
needsel = set()
# add attribute variables and mark variables which should be
# additionaly selected when possible
for var in select.defined_vars.itervalues():
if not var in variables:
stinfo = var.stinfo
for ovar, rtype in stinfo['attrvars']:
if ovar in variables:
needsel.add(var.name)
variables.append(var)
break
else:
needsel.add(var.name)
final = False
if final and source.uri != 'system':
# check rewritten constants
for vconsts in select.stinfo['rewritten'].itervalues():
const = vconsts[0]
eid = const.eval(self.plan.args)
_source = self._session.source_from_eid(eid)
if len(sources) > 1 or not _source in sources:
# if there is some rewriten constant used by a
# not neged relation while there are some source
# not supporting the associated entity, this step
# can't be final (unless the relation is explicitly
# in `variables`, eg cross relations)
for c in vconsts:
rel = c.relation()
if rel is None or not (rel in variables or rel.neged(strict=True)):
#if rel is not None and rel.r_type == 'identity' and not rel.neged(strict=True):
final = False
break
break
# check where all relations are supported by the sources
for rel in scope.iget_nodes(Relation):
if rel.is_types_restriction():
continue
# take care not overwriting the existing "source" identifier
for _source in sources:
if not _source.support_relation(rel.r_type):
for vref in rel.iget_nodes(VariableRef):
needsel.add(vref.name)
final = False
break
elif self.crossed_relation(_source, rel) and not rel in variables:
final = False
break
else:
if not scope is select:
self._exists_relation(rel, variables, needsel)
# if relation is supported by all sources and some of
# its lhs/rhs variable isn't in "variables", and the
# other end *is* in "variables", mark it have to be
# selected
if source.uri != 'system' and not rschema(rel.r_type).is_final():
lhs, rhs = rel.get_variable_parts()
try:
lhsvar = lhs.variable
except AttributeError:
lhsvar = lhs
try:
rhsvar = rhs.variable
except AttributeError:
rhsvar = rhs
if lhsvar in variables and not rhsvar in variables:
needsel.add(lhsvar.name)
elif rhsvar in variables and not lhsvar in variables:
needsel.add(rhsvar.name)
if final:
self._cleanup_sourcesvars(sources, solindices)
# XXX rename: variables may contain Relation and Constant nodes...
steps.append( (sources, variables, solindices, scope, needsel,
final) )
return steps
def _exists_relation(self, rel, variables, needsel):
rschema = self.plan.schema.rschema(rel.r_type)
lhs, rhs = rel.get_variable_parts()
try:
lhsvar, rhsvar = lhs.variable, rhs.variable
except AttributeError:
pass
else:
# supported relation with at least one end supported, check the
# other end is in as well. If not this usually means the
# variable is refed by an outer scope and should be substituted
# using an 'identity' relation (else we'll get a conflict of
# temporary tables)
if rhsvar in variables and not lhsvar in variables:
self._identity_substitute(rel, lhsvar, variables, needsel)
elif lhsvar in variables and not rhsvar in variables:
self._identity_substitute(rel, rhsvar, variables, needsel)
def _identity_substitute(self, relation, var, variables, needsel):
newvar = self._insert_identity_variable(relation.scope, var)
if newvar is not None:
# ensure relation is using '=' operator, else we rely on a
# sqlgenerator side effect (it won't insert an inequality operator
# in this case)
relation.children[1].operator = '='
variables.append(newvar)
needsel.add(newvar.name)
def _choose_var(self, sourcevars):
secondchoice = None
if len(self._sourcesvars) > 1:
# priority to variable from subscopes
for var in sourcevars:
if not var.scope is self.rqlst:
if isinstance(var, Variable):
return var, sourcevars.pop(var)
secondchoice = var
else:
# priority to variable outer scope
for var in sourcevars:
if var.scope is self.rqlst:
if isinstance(var, Variable):
return var, sourcevars.pop(var)
secondchoice = var
if secondchoice is not None:
return secondchoice, sourcevars.pop(secondchoice)
# priority to variable
for var in sourcevars:
if isinstance(var, Variable):
return var, sourcevars.pop(var)
# whatever
var = iter(sourcevars).next()
return var, sourcevars.pop(var)
def _expand_vars(self, var, source, sourcevars, scope, solindices):
variables = [var]
nbunlinked = 1
linkedvars = self._linkedvars
# variable has to belong to the same scope if there is more
# than the system source remaining
if len(self._sourcesvars) > 1 and not scope is self.rqlst:
candidates = (v for v in sourcevars.keys() if scope is v.scope)
else:
candidates = sourcevars #.iterkeys()
# we only want one unlinked variable in each generated query
candidates = [v for v in candidates
if isinstance(v, Constant) or
(solindices.issubset(sourcevars[v]) and v in linkedvars)]
accept_var = lambda x: (isinstance(x, Constant) or any(v for v in variables if v in linkedvars.get(x, ())))
source_cross_rels = self._crossrelations.get(source, ())
if isinstance(var, Relation) and var in source_cross_rels:
cross_vars = source_cross_rels.pop(var)
base_accept_var = accept_var
accept_var = lambda x: (base_accept_var(x) or x in cross_vars)
for refed in cross_vars:
if not refed in candidates:
candidates.append(refed)
else:
cross_vars = ()
# repeat until no variable can't be added, since addition of a new
# variable may permit to another one to be added
modified = True
while modified and candidates:
modified = False
for var in candidates[:]:
if accept_var(var):
variables.append(var)
try:
# constant nodes should be systematically deleted
if isinstance(var, Constant):
del sourcevars[var]
else:
# variable nodes should be deleted once all possible
# solutions indices have been consumed
sourcevars[var] -= solindices
if not sourcevars[var]:
del sourcevars[var]
except KeyError:
assert var in cross_vars
candidates.remove(var)
modified = True
return variables
def _expand_sources(self, selected_source, vars, solindices):
sources = [selected_source]
sourcesvars = self._sourcesvars
for source in sourcesvars:
if source is selected_source:
continue
for var in vars:
if not (var in sourcesvars[source] and
solindices.issubset(sourcesvars[source][var])):
break
else:
sources.append(source)
if source.uri != 'system':
for var in vars:
varsolindices = sourcesvars[source][var]
varsolindices -= solindices
if not varsolindices:
del sourcesvars[source][var]
return sources
def _cleanup_sourcesvars(self, sources, solindices):
"""on final parts, remove solutions so we know they are already processed"""
for source in sources:
try:
sourcevars = self._sourcesvars[source]
except KeyError:
continue
for var, varsolindices in sourcevars.items():
if isinstance(var, Relation) and self.crossed_relation(source, var):
continue
varsolindices -= solindices
if not varsolindices:
del sourcevars[var]
def merge_input_maps(self, allsolindices):
"""inputmaps is a dictionary with tuple of solution indices as key with an
associateed input map as value. This function compute for each solution
its necessary input map and return them grouped
ex:
inputmaps = {(0, 1, 2): {'A': 't1.login1', 'U': 't1.C0', 'U.login': 't1.login1'},
(1,): {'X': 't2.C0', 'T': 't2.C1'}}
return : [([1], {'A': 't1.login1', 'U': 't1.C0', 'U.login': 't1.login1',
'X': 't2.C0', 'T': 't2.C1'}),
([0,2], {'A': 't1.login1', 'U': 't1.C0', 'U.login': 't1.login1'})]
"""
if not self._inputmaps:
return [(allsolindices, None)]
mapbysol = {}
# compute a single map for each solution
for solindices, basemap in self._inputmaps.iteritems():
for solindex in solindices:
solmap = mapbysol.setdefault(solindex, {})
solmap.update(basemap)
try:
allsolindices.remove(solindex)
except KeyError:
continue # already removed
# group results by identical input map
result = []
for solindex, solmap in mapbysol.iteritems():
for solindices, commonmap in result:
if commonmap == solmap:
solindices.append(solindex)
break
else:
result.append( ([solindex], solmap) )
if allsolindices:
result.append( (list(allsolindices), None) )
return result
def build_final_part(self, select, solindices, inputmap, sources,
insertedvars):
plan = self.plan
rqlst = plan.finalize(select, [self._solutions[i] for i in solindices],
insertedvars)
if self.temptable is None and self.finaltable is None:
return OneFetchStep(plan, rqlst, sources, inputmap=inputmap)
table = self.temptable or self.finaltable
return FetchStep(plan, rqlst, sources, table, True, inputmap)
def build_non_final_part(self, select, solindices, sources, insertedvars,
table):
"""non final step, will have to store results in a temporary table"""
plan = self.plan
rqlst = plan.finalize(select, [self._solutions[i] for i in solindices],
insertedvars)
step = FetchStep(plan, rqlst, sources, table, False)
# update input map for following steps, according to processed solutions
inputmapkey = tuple(sorted(solindices))
inputmap = self._inputmaps.setdefault(inputmapkey, {})
inputmap.update(step.outputmap)
plan.add_step(step)
class MSPlanner(SSPlanner):
"""MultiSourcesPlanner: build execution plan for rql queries
decompose the RQL query according to sources'schema
"""
def build_select_plan(self, plan, rqlst):
"""build execution plan for a SELECT RQL query
the rqlst should not be tagged at this point
"""
if server.DEBUG:
print '-'*80
print 'PLANNING', rqlst
for select in rqlst.children:
if len(select.solutions) > 1:
hasmultiplesols = True
break
else:
hasmultiplesols = False
# preprocess deals with security insertion and returns a new syntax tree
# which have to be executed to fulfill the query: according
# to permissions for variable's type, different rql queries may have to
# be executed
plan.preprocess(rqlst)
ppis = [PartPlanInformation(plan, select, self.rqlhelper)
for select in rqlst.children]
steps = self._union_plan(plan, rqlst, ppis)
if server.DEBUG:
from pprint import pprint
for step in plan.steps:
pprint(step.test_repr())
pprint(steps[0].test_repr())
return steps
def _ppi_subqueries(self, ppi):
# part plan info for subqueries
plan = ppi.plan
inputmap = {}
for subquery in ppi.rqlst.with_[:]:
sppis = [PartPlanInformation(plan, select)
for select in subquery.query.children]
for sppi in sppis:
if sppi.needsplit or sppi.part_sources != ppi.part_sources:
temptable = 'T%s' % make_uid(id(subquery))
sstep = self._union_plan(plan, subquery.query, sppis, temptable)[0]
break
else:
sstep = None
if sstep is not None:
ppi.rqlst.with_.remove(subquery)
for i, colalias in enumerate(subquery.aliases):
inputmap[colalias.name] = '%s.C%s' % (temptable, i)
ppi.plan.add_step(sstep)
return inputmap
def _union_plan(self, plan, union, ppis, temptable=None):
tosplit, cango, allsources = [], {}, set()
for planinfo in ppis:
if planinfo.needsplit:
tosplit.append(planinfo)
else:
cango.setdefault(planinfo.part_sources, []).append(planinfo)
for source in planinfo.part_sources:
allsources.add(source)
# first add steps for query parts which doesn't need to splitted
steps = []
for sources, cppis in cango.iteritems():
byinputmap = {}
for ppi in cppis:
select = ppi.rqlst
if sources != (plan.session.repo.system_source,):
add_types_restriction(self.schema, select)
# part plan info for subqueries
inputmap = self._ppi_subqueries(ppi)
aggrstep = need_aggr_step(select, sources)
if aggrstep:
atemptable = 'T%s' % make_uid(id(select))
sunion = Union()
sunion.append(select)
selected = select.selection[:]
select_group_sort(select)
step = AggrStep(plan, selected, select, atemptable, temptable)
step.set_limit_offset(select.limit, select.offset)
select.limit = None
select.offset = 0
fstep = FetchStep(plan, sunion, sources, atemptable, True, inputmap)
step.children.append(fstep)
steps.append(step)
else:
byinputmap.setdefault(tuple(inputmap.iteritems()), []).append( (select) )
for inputmap, queries in byinputmap.iteritems():
inputmap = dict(inputmap)
sunion = Union()
for select in queries:
sunion.append(select)
if temptable:
steps.append(FetchStep(plan, sunion, sources, temptable, True, inputmap))
else:
steps.append(OneFetchStep(plan, sunion, sources, inputmap))
# then add steps for splitted query parts
for planinfo in tosplit:
steps.append(self.split_part(planinfo, temptable))
if len(steps) > 1:
if temptable:
step = UnionFetchStep(plan)
else:
step = UnionStep(plan)
step.children = steps
return (step,)
return steps
# internal methods for multisources decomposition #########################
def split_part(self, ppi, temptable):
ppi.finaltable = temptable
plan = ppi.plan
select = ppi.rqlst
subinputmap = self._ppi_subqueries(ppi)
stepdefs = ppi.part_steps()
if need_aggr_step(select, ppi.part_sources, stepdefs):
atemptable = 'T%s' % make_uid(id(select))
selection = select.selection[:]
select_group_sort(select)
else:
atemptable = None
selection = select.selection
ppi.temptable = atemptable
vfilter = VariablesFiltererVisitor(self.schema, ppi)
steps = []
for sources, variables, solindices, scope, needsel, final in stepdefs:
# extract an executable query using only the specified variables
if sources[0].uri == 'system':
# in this case we have to merge input maps before call to
# filter so already processed restriction are correctly
# removed
solsinputmaps = ppi.merge_input_maps(solindices)
for solindices, inputmap in solsinputmaps:
minrqlst, insertedvars = vfilter.filter(
sources, variables, scope, set(solindices), needsel, final)
if inputmap is None:
inputmap = subinputmap
else:
inputmap.update(subinputmap)
steps.append(ppi.build_final_part(minrqlst, solindices, inputmap,
sources, insertedvars))
else:
# this is a final part (i.e. retreiving results for the
# original query part) if all variable / sources have been
# treated or if this is the last shot for used solutions
minrqlst, insertedvars = vfilter.filter(
sources, variables, scope, solindices, needsel, final)
if final:
solsinputmaps = ppi.merge_input_maps(solindices)
for solindices, inputmap in solsinputmaps:
if inputmap is None:
inputmap = subinputmap
else:
inputmap.update(subinputmap)
steps.append(ppi.build_final_part(minrqlst, solindices, inputmap,
sources, insertedvars))
else:
table = '_T%s%s' % (''.join(sorted(v._ms_table_key() for v in variables)),
''.join(sorted(str(i) for i in solindices)))
ppi.build_non_final_part(minrqlst, solindices, sources,
insertedvars, table)
# finally: join parts, deal with aggregat/group/sorts if necessary
if atemptable is not None:
step = AggrStep(plan, selection, select, atemptable, temptable)
step.children = steps
elif len(steps) > 1:
if select.need_intersect:
if temptable:
step = IntersectFetchStep(plan)
else:
step = IntersectStep(plan)
else:
if temptable:
step = UnionFetchStep(plan)
else:
step = UnionStep(plan)
step.children = steps
else:
step = steps[0]
if select.limit is not None or select.offset:
step.set_limit_offset(select.limit, select.offset)
return step
class UnsupportedBranch(Exception):
pass
class VariablesFiltererVisitor(object):
def __init__(self, schema, ppi):
self.schema = schema
self.ppi = ppi
self.skip = {}
self.hasaggrstep = self.ppi.temptable
self.extneedsel = frozenset(vref.name for sortterm in ppi.rqlst.orderby
for vref in sortterm.iget_nodes(VariableRef))
def _rqlst_accept(self, rqlst, node, newroot, variables, setfunc=None):
try:
newrestr, node_ = node.accept(self, newroot, variables[:])
except UnsupportedBranch:
return rqlst
if setfunc is not None and newrestr is not None:
setfunc(newrestr)
if not node_ is node:
rqlst = node.parent
return rqlst
def filter(self, sources, variables, rqlst, solindices, needsel, final):
if server.DEBUG:
print 'filter', final and 'final' or '', sources, variables, rqlst, solindices, needsel
newroot = Select()
self.sources = sorted(sources)
self.variables = variables
self.solindices = solindices
self.final = final
# variables which appear in unsupported branches
needsel |= self.extneedsel
self.needsel = needsel
# variables which appear in supported branches
self.mayneedsel = set()
# new inserted variables
self.insertedvars = []
# other structures (XXX document)
self.mayneedvar, self.hasvar = {}, {}
self.use_only_defined = False
self.scopes = {rqlst: newroot}
if rqlst.where:
rqlst = self._rqlst_accept(rqlst, rqlst.where, newroot, variables,
newroot.set_where)
if isinstance(rqlst, Select):
self.use_only_defined = True
if rqlst.groupby:
groupby = []
for node in rqlst.groupby:
rqlst = self._rqlst_accept(rqlst, node, newroot, variables,
groupby.append)
if groupby:
newroot.set_groupby(groupby)
if rqlst.having:
having = []
for node in rqlst.having:
rqlst = self._rqlst_accept(rqlst, node, newroot, variables,
having.append)
if having:
newroot.set_having(having)
if final and rqlst.orderby and not self.hasaggrstep:
orderby = []
for node in rqlst.orderby:
rqlst = self._rqlst_accept(rqlst, node, newroot, variables,
orderby.append)
if orderby:
newroot.set_orderby(orderby)
self.process_selection(newroot, variables, rqlst)
elif not newroot.where:
# no restrictions have been copied, just select variables and add
# type restriction (done later by add_types_restriction)
for v in variables:
if not isinstance(v, Variable):
continue
newroot.append_selected(VariableRef(newroot.get_variable(v.name)))
solutions = self.ppi.copy_solutions(solindices)
cleanup_solutions(newroot, solutions)
newroot.set_possible_types(solutions)
if final:
if self.hasaggrstep:
self.add_necessary_selection(newroot, self.mayneedsel & self.extneedsel)
newroot.distinct = rqlst.distinct
else:
self.add_necessary_selection(newroot, self.mayneedsel & self.needsel)
# insert vars to fetch constant values when needed
for (varname, rschema), reldefs in self.mayneedvar.iteritems():
for rel, ored in reldefs:
if not (varname, rschema) in self.hasvar:
self.hasvar[(varname, rschema)] = None # just to avoid further insertion
cvar = newroot.make_variable()
for sol in newroot.solutions:
sol[cvar.name] = rschema.objects(sol[varname])[0]
# if the current restriction is not used in a OR branch,
# we can keep it, else we have to drop the constant
# restriction (or we may miss some results)
if not ored:
rel = rel.copy(newroot)
newroot.add_restriction(rel)
# add a relation to link the variable
newroot.remove_node(rel.children[1])
cmp = Comparison('=')
rel.append(cmp)
cmp.append(VariableRef(cvar))
self.insertedvars.append((varname, rschema, cvar.name))
newroot.append_selected(VariableRef(newroot.get_variable(cvar.name)))
# NOTE: even if the restriction is done by this query, we have
# to let it in the original rqlst so that it appears anyway in
# the "final" query, else we may change the meaning of the query
# if there are NOT somewhere :
# 'NOT X relation Y, Y name "toto"' means X WHERE X isn't related
# to Y whose name is toto while
# 'NOT X relation Y' means X WHERE X has no 'relation' (whatever Y)
elif ored:
newroot.remove_node(rel)
add_types_restriction(self.schema, rqlst, newroot, solutions)
if server.DEBUG:
print '--->', newroot
return newroot, self.insertedvars
def visit_and(self, node, newroot, variables):
subparts = []
for i in xrange(len(node.children)):
child = node.children[i]
try:
newchild, child_ = child.accept(self, newroot, variables)
if not child_ is child:
node = child_.parent
if newchild is None:
continue
subparts.append(newchild)
except UnsupportedBranch:
continue
if not subparts:
return None, node
if len(subparts) == 1:
return subparts[0], node
return copy_node(newroot, node, subparts), node
visit_or = visit_and
def _relation_supported(self, relation):
rtype = relation.r_type
for source in self.sources:
if not source.support_relation(rtype) \
or (rtype in source.cross_relations and not relation in self.variables):#self.ppi.crossed_relation(source, relation):
return False
if not self.final:
rschema = self.schema.rschema(relation.r_type)
if not rschema.is_final():
for term in relation.get_nodes((VariableRef, Constant)):
term = getattr(term, 'variable', term)
termsources = sorted(set(x[0] for x in self.ppi._term_sources(term)))
if termsources and termsources != self.sources:
return False
return True
def visit_relation(self, node, newroot, variables):
if not node.is_types_restriction():
if node in self.skip and self.solindices.issubset(self.skip[node]):
if not self.schema.rschema(node.r_type).is_final():
# can't really skip the relation if one variable is selected and only
# referenced by this relation
for vref in node.iget_nodes(VariableRef):
stinfo = vref.variable.stinfo
if stinfo['selected'] and len(stinfo['relations']) == 1:
break
else:
return None, node
else:
return None, node
if not self._relation_supported(node):
raise UnsupportedBranch()
# don't copy type restriction unless this is the only relation for the
# rhs variable, else they'll be reinserted later as needed (else we may
# copy a type restriction while the variable is not actually used)
elif not any(self._relation_supported(rel)
for rel in node.children[0].variable.stinfo['relations']):
rel, node = self.visit_default(node, newroot, variables)
return rel, node
else:
raise UnsupportedBranch()
rschema = self.schema.rschema(node.r_type)
res = self.visit_default(node, newroot, variables)[0]
ored = node.ored()
if rschema.is_final() or rschema.inlined:
vrefs = node.children[1].get_nodes(VariableRef)
if not vrefs:
if not ored:
self.skip.setdefault(node, set()).update(self.solindices)
else:
self.mayneedvar.setdefault((node.children[0].name, rschema), []).append( (res, ored) )
else:
assert len(vrefs) == 1
vref = vrefs[0]
# XXX check operator ?
self.hasvar[(node.children[0].name, rschema)] = vref
if self._may_skip_attr_rel(rschema, node, vref, ored, variables, res):
self.skip.setdefault(node, set()).update(self.solindices)
elif not ored:
self.skip.setdefault(node, set()).update(self.solindices)
return res, node
def _may_skip_attr_rel(self, rschema, rel, vref, ored, variables, res):
var = vref.variable
if ored:
return False
if var.name in self.extneedsel or var.stinfo['selected']:
return False
if not same_scope(var):
return False
if any(v for v,_ in var.stinfo['attrvars'] if not v.name in variables):
return False
return True
def visit_exists(self, node, newroot, variables):
newexists = node.__class__()
self.scopes = {node: newexists}
subparts, node = self._visit_children(node, newroot, variables)
if not subparts:
return None, node
newexists.set_where(subparts[0])
return newexists, node
def visit_not(self, node, newroot, variables):
subparts, node = self._visit_children(node, newroot, variables)
if not subparts:
return None, node
return copy_node(newroot, node, subparts), node
def visit_group(self, node, newroot, variables):
if not self.final:
return None, node
return self.visit_default(node, newroot, variables)
def visit_variableref(self, node, newroot, variables):
if self.use_only_defined:
if not node.variable.name in newroot.defined_vars:
raise UnsupportedBranch(node.name)
elif not node.variable in variables:
raise UnsupportedBranch(node.name)
self.mayneedsel.add(node.name)
# set scope so we can insert types restriction properly
newvar = newroot.get_variable(node.name)
newvar.stinfo['scope'] = self.scopes.get(node.variable.scope, newroot)
return VariableRef(newvar), node
def visit_constant(self, node, newroot, variables):
return copy_node(newroot, node), node
def visit_default(self, node, newroot, variables):
subparts, node = self._visit_children(node, newroot, variables)
return copy_node(newroot, node, subparts), node
visit_comparison = visit_mathexpression = visit_constant = visit_function = visit_default
visit_sort = visit_sortterm = visit_default
def _visit_children(self, node, newroot, variables):
subparts = []
for i in xrange(len(node.children)):
child = node.children[i]
newchild, child_ = child.accept(self, newroot, variables)
if not child is child_:
node = child_.parent
if newchild is not None:
subparts.append(newchild)
return subparts, node
def process_selection(self, newroot, variables, rqlst):
if self.final:
for term in rqlst.selection:
newroot.append_selected(term.copy(newroot))
for vref in term.get_nodes(VariableRef):
self.needsel.add(vref.name)
return
for term in rqlst.selection:
vrefs = term.get_nodes(VariableRef)
if vrefs:
supportedvars = []
for vref in vrefs:
var = vref.variable
if var in variables:
supportedvars.append(vref)
continue
else:
self.needsel.add(vref.name)
break
else:
for vref in vrefs:
newroot.append_selected(vref.copy(newroot))
supportedvars = []
for vref in supportedvars:
if not vref in newroot.get_selected_variables():
newroot.append_selected(VariableRef(newroot.get_variable(vref.name)))
def add_necessary_selection(self, newroot, variables):
selected = tuple(newroot.get_selected_variables())
for varname in variables:
var = newroot.defined_vars[varname]
for vref in var.references():
rel = vref.relation()
if rel is None and vref in selected:
# already selected
break
else:
selvref = VariableRef(var)
newroot.append_selected(selvref)
if newroot.groupby:
newroot.add_group_var(VariableRef(selvref.variable, noautoref=1))