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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.
*/
#include "mongo/db/matcher/expression_tree.h"
#include "mongo/bson/bsonmisc.h"
#include "mongo/bson/bsonobj.h"
#include "mongo/bson/bsonobjbuilder.h"
#include "mongo/db/matcher/expression_always_boolean.h"
#include "mongo/db/matcher/expression_path.h"
#include "mongo/db/matcher/expression_text_base.h"
namespace mongo {
ListOfMatchExpression::~ListOfMatchExpression() {
for (unsigned i = 0; i < _expressions.size(); i++) {
delete _expressions[i];
}
_expressions.clear();
}
void ListOfMatchExpression::add(MatchExpression* e) {
verify(e);
_expressions.push_back(e);
}
void ListOfMatchExpression::_debugList(StringBuilder& debug, int indentationLevel) const {
for (unsigned i = 0; i < _expressions.size(); i++)
_expressions[i]->debugString(debug, indentationLevel + 1);
}
void ListOfMatchExpression::_listToBSON(BSONArrayBuilder* out) const {
for (unsigned i = 0; i < _expressions.size(); i++) {
BSONObjBuilder childBob(out->subobjStart());
_expressions[i]->serialize(&childBob);
}
out->doneFast();
}
MatchExpression::ExpressionOptimizerFunc ListOfMatchExpression::getOptimizer() const {
return [](std::unique_ptr<MatchExpression> expression) -> std::unique_ptr<MatchExpression> {
auto& children = static_cast<ListOfMatchExpression&>(*expression)._expressions;
// Recursively apply optimizations to child expressions.
for (auto& childExpression : children) {
// Since 'childExpression' is a reference to a member of the ListOfMatchExpression's
// child array, this assignment replaces the original child with the optimized child.
// We must set this child's entry in '_expressions' to null after assigning ownership to
// 'childExpressionPtr'. Otherwise, if the call to optimize() throws we will attempt to
// free twice.
std::unique_ptr<MatchExpression> childExpressionPtr(childExpression);
childExpression = nullptr;
auto optimizedExpression = MatchExpression::optimize(std::move(childExpressionPtr));
childExpression = optimizedExpression.release();
}
// Associativity of AND and OR: an AND absorbs the children of any ANDs among its children
// (and likewise for any OR with OR children).
MatchType matchType = expression->matchType();
if (matchType == AND || matchType == OR) {
std::vector<MatchExpression*> absorbedExpressions;
for (MatchExpression*& childExpression : children) {
if (childExpression->matchType() == matchType) {
// Move this child out of the children array.
std::unique_ptr<ListOfMatchExpression> childExpressionPtr(
static_cast<ListOfMatchExpression*>(childExpression));
childExpression = nullptr; // Null out this child's entry in _expressions, so
// that it will be deleted by the erase call below.
// Move all of the grandchildren from the child expression to
// absorbedExpressions.
auto& grandChildren = childExpressionPtr->_expressions;
absorbedExpressions.insert(
absorbedExpressions.end(), grandChildren.begin(), grandChildren.end());
grandChildren.clear();
// Note that 'childExpressionPtr' will now be destroyed.
}
}
// We replaced each destroyed child expression with nullptr. Now we remove those
// nullptrs from the array.
children.erase(std::remove(children.begin(), children.end(), nullptr), children.end());
// Append the absorbed children to the end of the array.
children.insert(children.end(), absorbedExpressions.begin(), absorbedExpressions.end());
}
// Remove all children of AND that are $alwaysTrue and all children of OR that are
// $alwaysFalse.
if (matchType == AND || matchType == OR) {
for (MatchExpression*& childExpression : children) {
if ((childExpression->isTriviallyTrue() && matchType == MatchExpression::AND) ||
(childExpression->isTriviallyFalse() && matchType == MatchExpression::OR)) {
std::unique_ptr<MatchExpression> childPtr(childExpression);
childExpression = nullptr;
}
}
// We replaced each destroyed child expression with nullptr. Now we remove those
// nullptrs from the vector.
children.erase(std::remove(children.begin(), children.end(), nullptr), children.end());
}
// Check if the above optimizations eliminated all children. An OR with no children is
// always false.
// TODO SERVER-34759 It is correct to replace this empty AND with an $alwaysTrue, but we
// need to make enhancements to the planner to make it understand an $alwaysTrue and an
// empty AND as the same thing. The planner can create inferior plans for $alwaysTrue which
// it would not produce for an AND with no children.
if (children.empty() && matchType == MatchExpression::OR) {
return stdx::make_unique<AlwaysFalseMatchExpression>();
}
if (children.size() == 1) {
if ((matchType == AND || matchType == OR || matchType == INTERNAL_SCHEMA_XOR)) {
// Simplify AND/OR/XOR with exactly one operand to an expression consisting of just
// that operand.
MatchExpression* simplifiedExpression = children.front();
children.clear();
return std::unique_ptr<MatchExpression>(simplifiedExpression);
} else if (matchType == NOR) {
// Simplify NOR of exactly one operand to NOT of that operand.
auto simplifiedExpression = stdx::make_unique<NotMatchExpression>(children.front());
children.clear();
return std::move(simplifiedExpression);
}
}
if (matchType == MatchExpression::AND || matchType == MatchExpression::OR) {
for (auto& childExpression : children) {
// An AND containing an expression that always evaluates to false can be
// optimized to a single $alwaysFalse expression.
if (childExpression->isTriviallyFalse() && matchType == MatchExpression::AND) {
return stdx::make_unique<AlwaysFalseMatchExpression>();
}
// Likewise, an OR containing an expression that always evaluates to true can be
// optimized to a single $alwaysTrue expression.
if (childExpression->isTriviallyTrue() && matchType == MatchExpression::OR) {
return stdx::make_unique<AlwaysTrueMatchExpression>();
}
}
}
return expression;
};
}
bool ListOfMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType())
return false;
const ListOfMatchExpression* realOther = static_cast<const ListOfMatchExpression*>(other);
if (_expressions.size() != realOther->_expressions.size())
return false;
// TOOD: order doesn't matter
for (unsigned i = 0; i < _expressions.size(); i++)
if (!_expressions[i]->equivalent(realOther->_expressions[i]))
return false;
return true;
}
// -----
bool AndMatchExpression::matches(const MatchableDocument* doc, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (!getChild(i)->matches(doc, details)) {
if (details)
details->resetOutput();
return false;
}
}
return true;
}
bool AndMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (!getChild(i)->matchesSingleElement(e, details)) {
return false;
}
}
return true;
}
void AndMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << "$and\n";
_debugList(debug, indentationLevel);
}
void AndMatchExpression::serialize(BSONObjBuilder* out) const {
if (!numChildren()) {
// It is possible for an AndMatchExpression to have no children, resulting in the serialized
// expression {$and: []}, which is not a valid query object.
return;
}
BSONArrayBuilder arrBob(out->subarrayStart("$and"));
_listToBSON(&arrBob);
arrBob.doneFast();
}
bool AndMatchExpression::isTriviallyTrue() const {
return numChildren() == 0;
}
// -----
bool OrMatchExpression::matches(const MatchableDocument* doc, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (getChild(i)->matches(doc, NULL)) {
return true;
}
}
return false;
}
bool OrMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (getChild(i)->matchesSingleElement(e, details)) {
return true;
}
}
return false;
}
void OrMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << "$or\n";
_debugList(debug, indentationLevel);
}
void OrMatchExpression::serialize(BSONObjBuilder* out) const {
if (!numChildren()) {
// It is possible for an OrMatchExpression to have no children, resulting in the serialized
// expression {$or: []}, which is not a valid query object. An empty $or is logically
// equivalent to {$alwaysFalse: 1}.
out->append(AlwaysFalseMatchExpression::kName, 1);
return;
}
BSONArrayBuilder arrBob(out->subarrayStart("$or"));
_listToBSON(&arrBob);
}
bool OrMatchExpression::isTriviallyFalse() const {
return numChildren() == 0;
}
// ----
bool NorMatchExpression::matches(const MatchableDocument* doc, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (getChild(i)->matches(doc, NULL)) {
return false;
}
}
return true;
}
bool NorMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
for (size_t i = 0; i < numChildren(); i++) {
if (getChild(i)->matchesSingleElement(e, details)) {
return false;
}
}
return true;
}
void NorMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << "$nor\n";
_debugList(debug, indentationLevel);
}
void NorMatchExpression::serialize(BSONObjBuilder* out) const {
BSONArrayBuilder arrBob(out->subarrayStart("$nor"));
_listToBSON(&arrBob);
}
// -------
void NotMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << "$not\n";
_exp->debugString(debug, indentationLevel + 1);
}
boost::optional<StringData> NotMatchExpression::getPathIfNotWithSinglePathMatchExpressionTree(
MatchExpression* exp) {
if (auto pathMatch = dynamic_cast<PathMatchExpression*>(exp)) {
if (dynamic_cast<TextMatchExpressionBase*>(exp)) {
// While TextMatchExpressionBase derives from PathMatchExpression, text match
// expressions cannot be serialized in the same manner as other PathMatchExpression
// derivatives. This is because the path for a TextMatchExpression is embedded within
// the $text object, whereas for other PathMatchExpressions it is on the left-hand-side,
// for example {x: {$eq: 1}}.
return boost::none;
}
return pathMatch->path();
}
if (exp->matchType() == MatchExpression::MatchType::AND && exp->numChildren() > 0) {
boost::optional<StringData> path;
for (size_t i = 0; i < exp->numChildren(); ++i) {
auto pathMatchChild = dynamic_cast<PathMatchExpression*>(exp->getChild(i));
if (!pathMatchChild || dynamic_cast<TextMatchExpressionBase*>(exp->getChild(i))) {
return boost::none;
}
if (path && path != pathMatchChild->path()) {
return boost::none;
} else if (!path) {
path = pathMatchChild->path();
}
}
invariant(path);
return path;
}
return boost::none;
}
void NotMatchExpression::serializeNotExpressionToNor(MatchExpression* exp, BSONObjBuilder* out) {
BSONObjBuilder childBob;
exp->serialize(&childBob);
BSONObj tempObj = childBob.obj();
BSONArrayBuilder tBob(out->subarrayStart("$nor"));
tBob.append(tempObj);
tBob.doneFast();
}
void NotMatchExpression::serialize(BSONObjBuilder* out) const {
if (_exp->matchType() == MatchType::AND && _exp->numChildren() == 0) {
out->append("$alwaysFalse", 1);
return;
}
// When a $not contains an expression that is not a PathMatchExpression tree representing a
// single path, we transform to a $nor.
// There are trees constructed to represent JSONSchema that require a nor representation to
// be valid. Here is an example:
// JSONSchema:
// {properties: {foo: {type: "string", not: {maxLength: 4}}}}
// MatchExpression tree generated:
// {foo: {$not: {$or: [{$not: {$_internalSchemaType: [ 2 ]}},
// {$_internalSchemaMaxLength: 4}]}}}
boost::optional<StringData> path = getPathIfNotWithSinglePathMatchExpressionTree(_exp.get());
if (!path) {
return serializeNotExpressionToNor(_exp.get(), out);
}
BSONObjBuilder pathBob(out->subobjStart(*path));
if (_exp->matchType() == MatchType::AND) {
BSONObjBuilder notBob(pathBob.subobjStart("$not"));
for (size_t x = 0; x < _exp->numChildren(); ++x) {
auto* pathMatchExpression = dynamic_cast<PathMatchExpression*>(_exp->getChild(x));
invariant(pathMatchExpression);
notBob.appendElements(pathMatchExpression->getSerializedRightHandSide());
}
notBob.doneFast();
} else {
auto* pathMatchExpression = dynamic_cast<PathMatchExpression*>(_exp.get());
invariant(pathMatchExpression);
pathBob.append("$not", pathMatchExpression->getSerializedRightHandSide());
}
pathBob.doneFast();
}
bool NotMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType())
return false;
return _exp->equivalent(other->getChild(0));
}
MatchExpression::ExpressionOptimizerFunc NotMatchExpression::getOptimizer() const {
return [](std::unique_ptr<MatchExpression> expression) {
auto& notExpression = static_cast<NotMatchExpression&>(*expression);
notExpression._exp = MatchExpression::optimize(std::move(notExpression._exp));
return expression;
};
}
}
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