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/**
* Copyright (C) 2018-present MongoDB, Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the Server Side Public License, version 1,
* as published by MongoDB, Inc.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* Server Side Public License for more details.
*
* You should have received a copy of the Server Side Public License
* along with this program. If not, see
* <http://www.mongodb.com/licensing/server-side-public-license>.
*
* As a special exception, the copyright holders give permission to link the
* code of portions of this program with the OpenSSL library under certain
* conditions as described in each individual source file and distribute
* linked combinations including the program with the OpenSSL library. You
* must comply with the Server Side Public License in all respects for
* all of the code used other than as permitted herein. If you modify file(s)
* with this exception, you may extend this exception to your version of the
* file(s), but you are not obligated to do so. If you do not wish to do so,
* delete this exception statement from your version. If you delete this
* exception statement from all source files in the program, then also delete
* it in the license file.
*/
#define MONGO_LOG_DEFAULT_COMPONENT ::mongo::logger::LogComponent::kQuery
#include "mongo/db/exec/projection.h"
#include "boost/optional.hpp"
#include "mongo/db/exec/plan_stage.h"
#include "mongo/db/exec/scoped_timer.h"
#include "mongo/db/exec/working_set_common.h"
#include "mongo/db/exec/working_set_computed_data.h"
#include "mongo/db/jsobj.h"
#include "mongo/db/matcher/expression.h"
#include "mongo/db/record_id.h"
#include "mongo/stdx/memory.h"
#include "mongo/util/log.h"
#include "mongo/util/mongoutils/str.h"
namespace mongo {
static const char* kIdField = "_id";
namespace {
BSONObj indexKey(const WorkingSetMember& member) {
return static_cast<const IndexKeyComputedData*>(member.getComputed(WSM_INDEX_KEY))->getKey();
}
BSONObj sortKey(const WorkingSetMember& member) {
return static_cast<const SortKeyComputedData*>(member.getComputed(WSM_SORT_KEY))->getSortKey();
}
double geoDistance(const WorkingSetMember& member) {
return static_cast<const GeoDistanceComputedData*>(
member.getComputed(WSM_COMPUTED_GEO_DISTANCE))
->getDist();
}
BSONObj geoPoint(const WorkingSetMember& member) {
return static_cast<const GeoNearPointComputedData*>(member.getComputed(WSM_GEO_NEAR_POINT))
->getPoint();
}
double textScore(const WorkingSetMember& member) {
if (member.hasComputed(WSM_COMPUTED_TEXT_SCORE))
return static_cast<const TextScoreComputedData*>(
member.getComputed(WSM_COMPUTED_TEXT_SCORE))
->getScore();
// It is permitted to request a text score when none has been computed. Zero is returned as an
// empty value in this case.
else
return 0.0;
}
void transitionMemberToOwnedObj(const BSONObj& bo, WorkingSetMember* member) {
member->keyData.clear();
member->recordId = RecordId();
member->obj = Snapshotted<BSONObj>(SnapshotId(), bo);
member->transitionToOwnedObj();
}
StatusWith<BSONObj> provideMetaFieldsAndPerformExec(const ProjectionExec& exec,
const WorkingSetMember& member) {
if (exec.needsGeoNearDistance() && !member.hasComputed(WSM_COMPUTED_GEO_DISTANCE))
return Status(ErrorCodes::InternalError, "near loc dist requested but no data available");
if (exec.needsGeoNearPoint() && !member.hasComputed(WSM_GEO_NEAR_POINT))
return Status(ErrorCodes::InternalError, "near loc proj requested but no data available");
return member.hasObj()
? exec.project(member.obj.value(),
exec.needsGeoNearDistance()
? boost::optional<const double>(geoDistance(member))
: boost::none,
exec.needsGeoNearPoint() ? geoPoint(member) : BSONObj(),
exec.needsSortKey() ? sortKey(member) : BSONObj(),
exec.needsTextScore() ? boost::optional<const double>(textScore(member))
: boost::none,
member.recordId.repr())
: exec.projectCovered(
member.keyData,
exec.needsGeoNearDistance() ? boost::optional<const double>(geoDistance(member))
: boost::none,
exec.needsGeoNearPoint() ? geoPoint(member) : BSONObj(),
exec.needsSortKey() ? sortKey(member) : BSONObj(),
exec.needsTextScore() ? boost::optional<const double>(textScore(member))
: boost::none,
member.recordId.repr());
}
} // namespace
ProjectionStage::ProjectionStage(OperationContext* opCtx,
const BSONObj& projObj,
WorkingSet* ws,
std::unique_ptr<PlanStage> child,
const char* stageType)
: PlanStage(opCtx, std::move(child), stageType), _projObj(projObj), _ws(*ws) {}
// static
void ProjectionStage::getSimpleInclusionFields(const BSONObj& projObj, FieldSet* includedFields) {
// The _id is included by default.
bool includeId = true;
// Figure out what fields are in the projection. TODO: we can get this from the
// ParsedProjection...modify that to have this type instead of a vector.
BSONObjIterator projObjIt(projObj);
while (projObjIt.more()) {
BSONElement elt = projObjIt.next();
// Must deal with the _id case separately as there is an implicit _id: 1 in the
// projection.
if (mongoutils::str::equals(elt.fieldName(), kIdField) && !elt.trueValue()) {
includeId = false;
continue;
}
(*includedFields)[elt.fieldNameStringData()] = true;
}
if (includeId) {
(*includedFields)[kIdField] = true;
}
}
bool ProjectionStage::isEOF() {
return child()->isEOF();
}
PlanStage::StageState ProjectionStage::doWork(WorkingSetID* out) {
WorkingSetID id = WorkingSet::INVALID_ID;
StageState status = child()->work(&id);
// Note that we don't do the normal if isEOF() return EOF thing here. Our child might be a
// tailable cursor and isEOF() would be true even if it had more data...
if (PlanStage::ADVANCED == status) {
WorkingSetMember* member = _ws.get(id);
// Punt to our specific projection impl.
Status projStatus = transform(member);
if (!projStatus.isOK()) {
warning() << "Couldn't execute projection, status = " << redact(projStatus);
*out = WorkingSetCommon::allocateStatusMember(&_ws, projStatus);
return PlanStage::FAILURE;
}
*out = id;
} else if (PlanStage::FAILURE == status) {
// The stage which produces a failure is responsible for allocating a working set member
// with error details.
invariant(WorkingSet::INVALID_ID != id);
*out = id;
} else if (PlanStage::NEED_YIELD == status) {
*out = id;
}
return status;
}
std::unique_ptr<PlanStageStats> ProjectionStage::getStats() {
_commonStats.isEOF = isEOF();
auto ret = std::make_unique<PlanStageStats>(_commonStats, stageType());
auto projStats = std::make_unique<ProjectionStats>(_specificStats);
projStats->projObj = _projObj;
ret->specific = std::move(projStats);
ret->children.emplace_back(child()->getStats());
return ret;
}
ProjectionStageDefault::ProjectionStageDefault(OperationContext* opCtx,
const BSONObj& projObj,
WorkingSet* ws,
std::unique_ptr<PlanStage> child,
const MatchExpression& fullExpression,
const CollatorInterface* collator)
: ProjectionStage(opCtx, projObj, ws, std::move(child), "PROJECTION_DEFAULT"),
_exec(opCtx, projObj, &fullExpression, collator) {}
Status ProjectionStageDefault::transform(WorkingSetMember* member) const {
// The default no-fast-path case.
if (_exec.needsSortKey() && !member->hasComputed(WSM_SORT_KEY))
return Status(ErrorCodes::InternalError,
"sortKey meta-projection requested but no data available");
if (_exec.returnKey()) {
auto keys = _exec.computeReturnKeyProjection(
member->hasComputed(WSM_INDEX_KEY) ? indexKey(*member) : BSONObj(),
_exec.needsSortKey() ? sortKey(*member) : BSONObj());
if (!keys.isOK())
return keys.getStatus();
transitionMemberToOwnedObj(keys.getValue(), member);
return Status::OK();
}
auto projected = provideMetaFieldsAndPerformExec(_exec, *member);
if (!projected.isOK())
return projected.getStatus();
transitionMemberToOwnedObj(projected.getValue(), member);
return Status::OK();
}
ProjectionStageCovered::ProjectionStageCovered(OperationContext* opCtx,
const BSONObj& projObj,
WorkingSet* ws,
std::unique_ptr<PlanStage> child,
const BSONObj& coveredKeyObj)
: ProjectionStage(opCtx, projObj, ws, std::move(child), "PROJECTION_COVERED"),
_coveredKeyObj(coveredKeyObj) {
invariant(projObjHasOwnedData());
// Figure out what fields are in the projection.
getSimpleInclusionFields(_projObj, &_includedFields);
// If we're pulling data out of one index we can pre-compute the indices of the fields
// in the key that we pull data from and avoid looking up the field name each time.
// Sanity-check.
invariant(_coveredKeyObj.isOwned());
BSONObjIterator kpIt(_coveredKeyObj);
while (kpIt.more()) {
BSONElement elt = kpIt.next();
auto fieldIt = _includedFields.find(elt.fieldNameStringData());
if (_includedFields.end() == fieldIt) {
// Push an unused value on the back to keep _includeKey and _keyFieldNames
// in sync.
_keyFieldNames.push_back(StringData());
_includeKey.push_back(false);
} else {
// If we are including this key field store its field name.
_keyFieldNames.push_back(fieldIt->first);
_includeKey.push_back(true);
}
}
}
Status ProjectionStageCovered::transform(WorkingSetMember* member) const {
BSONObjBuilder bob;
// We're pulling data out of the key.
invariant(1 == member->keyData.size());
size_t keyIndex = 0;
// Look at every key element...
BSONObjIterator keyIterator(member->keyData[0].keyData);
while (keyIterator.more()) {
BSONElement elt = keyIterator.next();
// If we're supposed to include it...
if (_includeKey[keyIndex]) {
// Do so.
bob.appendAs(elt, _keyFieldNames[keyIndex]);
}
++keyIndex;
}
transitionMemberToOwnedObj(bob.obj(), member);
return Status::OK();
}
ProjectionStageSimple::ProjectionStageSimple(OperationContext* opCtx,
const BSONObj& projObj,
WorkingSet* ws,
std::unique_ptr<PlanStage> child)
: ProjectionStage(opCtx, projObj, ws, std::move(child), "PROJECTION_SIMPLE") {
invariant(projObjHasOwnedData());
// Figure out what fields are in the projection.
getSimpleInclusionFields(_projObj, &_includedFields);
}
Status ProjectionStageSimple::transform(WorkingSetMember* member) const {
BSONObjBuilder bob;
// SIMPLE_DOC implies that we expect an object so it's kind of redundant.
// If we got here because of SIMPLE_DOC the planner shouldn't have messed up.
invariant(member->hasObj());
// Apply the SIMPLE_DOC projection.
// Look at every field in the source document and see if we're including it.
BSONObjIterator inputIt(member->obj.value());
while (inputIt.more()) {
BSONElement elt = inputIt.next();
auto fieldIt = _includedFields.find(elt.fieldNameStringData());
if (_includedFields.end() != fieldIt) {
// If so, add it to the builder.
bob.append(elt);
}
}
transitionMemberToOwnedObj(bob.obj(), member);
return Status::OK();
}
} // namespace mongo
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