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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/platform/basic.h"
#include "mongo/db/matcher/expression_leaf.h"
#include <cmath>
#include <memory>
#include <pcrecpp.h>
#include "mongo/bson/bsonelement_comparator.h"
#include "mongo/bson/bsonmisc.h"
#include "mongo/bson/bsonobj.h"
#include "mongo/config.h"
#include "mongo/db/field_ref.h"
#include "mongo/db/jsobj.h"
#include "mongo/db/matcher/expression_parser.h"
#include "mongo/db/matcher/path.h"
#include "mongo/db/query/collation/collator_interface.h"
#include "mongo/util/regex_util.h"
#include "mongo/util/str.h"
namespace mongo {
ComparisonMatchExpressionBase::ComparisonMatchExpressionBase(
MatchType type,
StringData path,
const BSONElement& rhs,
ElementPath::LeafArrayBehavior leafArrBehavior,
ElementPath::NonLeafArrayBehavior nonLeafArrBehavior)
: LeafMatchExpression(type, path, leafArrBehavior, nonLeafArrBehavior), _rhs(rhs) {
invariant(_rhs);
}
bool ComparisonMatchExpressionBase::equivalent(const MatchExpression* other) const {
if (other->matchType() != matchType())
return false;
auto realOther = static_cast<const ComparisonMatchExpressionBase*>(other);
if (!CollatorInterface::collatorsMatch(_collator, realOther->_collator)) {
return false;
}
const StringData::ComparatorInterface* stringComparator = nullptr;
BSONElementComparator eltCmp(BSONElementComparator::FieldNamesMode::kIgnore, stringComparator);
return path() == realOther->path() && eltCmp.evaluate(_rhs == realOther->_rhs);
}
void ComparisonMatchExpressionBase::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " " << name();
debug << " " << _rhs.toString(false);
MatchExpression::TagData* td = getTag();
if (td) {
debug << " ";
td->debugString(&debug);
}
debug << "\n";
}
BSONObj ComparisonMatchExpressionBase::getSerializedRightHandSide() const {
return BSON(name() << _rhs);
}
ComparisonMatchExpression::ComparisonMatchExpression(MatchType type,
StringData path,
const BSONElement& rhs)
: ComparisonMatchExpressionBase(type,
path,
rhs,
ElementPath::LeafArrayBehavior::kTraverse,
ElementPath::NonLeafArrayBehavior::kTraverse) {
uassert(
ErrorCodes::BadValue, "cannot compare to undefined", _rhs.type() != BSONType::Undefined);
switch (matchType()) {
case LT:
case LTE:
case EQ:
case GT:
case GTE:
break;
default:
uasserted(ErrorCodes::BadValue, "bad match type for ComparisonMatchExpression");
}
}
bool ComparisonMatchExpression::matchesSingleElement(const BSONElement& e,
MatchDetails* details) const {
if (e.canonicalType() != _rhs.canonicalType()) {
// We can't call 'compareElements' on elements of different canonical types. Usually
// elements with different canonical types should never match any comparison, but there are
// a few exceptions, handled here.
// jstNULL and undefined are treated the same
if (e.canonicalType() + _rhs.canonicalType() == 5) {
return matchType() == EQ || matchType() == LTE || matchType() == GTE;
}
if (_rhs.type() == MaxKey || _rhs.type() == MinKey) {
switch (matchType()) {
// LT and LTE need no distinction here because the two elements that we are
// comparing do not even have the same canonical type and are thus not equal
// (i.e.the case where we compare MinKey against MinKey would not reach this switch
// statement at all). The same reasoning follows for the lack of distinction
// between GTE and GT.
case LT:
case LTE:
return _rhs.type() == MaxKey;
case EQ:
return false;
case GT:
case GTE:
return _rhs.type() == MinKey;
default:
// This is a comparison match expression, so it must be either
// a $lt, $lte, $gt, $gte, or equality expression.
MONGO_UNREACHABLE;
}
}
return false;
}
// Special case handling for NaN. NaN is equal to NaN but
// otherwise always compares to false.
if (std::isnan(e.numberDouble()) || std::isnan(_rhs.numberDouble())) {
bool bothNaN = std::isnan(e.numberDouble()) && std::isnan(_rhs.numberDouble());
switch (matchType()) {
case LT:
return false;
case LTE:
return bothNaN;
case EQ:
return bothNaN;
case GT:
return false;
case GTE:
return bothNaN;
default:
// This is a comparison match expression, so it must be either
// a $lt, $lte, $gt, $gte, or equality expression.
fassertFailed(17448);
}
}
int x = BSONElement::compareElements(
e, _rhs, BSONElement::ComparisonRules::kConsiderFieldName, _collator);
switch (matchType()) {
case LT:
return x < 0;
case LTE:
return x <= 0;
case EQ:
return x == 0;
case GT:
return x > 0;
case GTE:
return x >= 0;
default:
// This is a comparison match expression, so it must be either
// a $lt, $lte, $gt, $gte, or equality expression.
fassertFailed(16828);
}
}
constexpr StringData EqualityMatchExpression::kName;
constexpr StringData LTMatchExpression::kName;
constexpr StringData LTEMatchExpression::kName;
constexpr StringData GTMatchExpression::kName;
constexpr StringData GTEMatchExpression::kName;
const std::set<char> RegexMatchExpression::kValidRegexFlags = {'i', 'm', 's', 'x'};
RegexMatchExpression::RegexMatchExpression(StringData path, const BSONElement& e)
: LeafMatchExpression(REGEX, path),
_regex(e.regex()),
_flags(e.regexFlags()),
_re(new pcrecpp::RE(_regex.c_str(), regex_util::flagsToPcreOptions(_flags, true))) {
uassert(ErrorCodes::BadValue, "regex not a regex", e.type() == RegEx);
_init();
}
RegexMatchExpression::RegexMatchExpression(StringData path, StringData regex, StringData options)
: LeafMatchExpression(REGEX, path),
_regex(regex.toString()),
_flags(options.toString()),
_re(new pcrecpp::RE(_regex.c_str(), regex_util::flagsToPcreOptions(_flags, true))) {
_init();
}
void RegexMatchExpression::_init() {
uassert(ErrorCodes::BadValue,
"Regular expression cannot contain an embedded null byte",
_regex.find('\0') == std::string::npos);
uassert(ErrorCodes::BadValue,
"Regular expression options string cannot contain an embedded null byte",
_flags.find('\0') == std::string::npos);
uassert(51091,
str::stream() << "Regular expression is invalid: " << _re->error(),
_re->error().empty());
}
RegexMatchExpression::~RegexMatchExpression() {}
bool RegexMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType())
return false;
const RegexMatchExpression* realOther = static_cast<const RegexMatchExpression*>(other);
return path() == realOther->path() && _regex == realOther->_regex &&
_flags == realOther->_flags;
}
bool RegexMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
switch (e.type()) {
case String:
case Symbol: {
// String values stored in documents can contain embedded NUL bytes. We construct a
// pcrecpp::StringPiece instance using the full length of the string to avoid truncating
// 'data' early.
pcrecpp::StringPiece data(e.valuestr(), e.valuestrsize() - 1);
return _re->PartialMatch(data);
}
case RegEx:
return _regex == e.regex() && _flags == e.regexFlags();
default:
return false;
}
}
void RegexMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " regex /" << _regex << "/" << _flags;
MatchExpression::TagData* td = getTag();
if (nullptr != td) {
debug << " ";
td->debugString(&debug);
}
debug << "\n";
}
BSONObj RegexMatchExpression::getSerializedRightHandSide() const {
BSONObjBuilder regexBuilder;
regexBuilder.append("$regex", _regex);
if (!_flags.empty()) {
regexBuilder.append("$options", _flags);
}
return regexBuilder.obj();
}
void RegexMatchExpression::serializeToBSONTypeRegex(BSONObjBuilder* out) const {
out->appendRegex(path(), _regex, _flags);
}
void RegexMatchExpression::shortDebugString(StringBuilder& debug) const {
debug << "/" << _regex << "/" << _flags;
}
// ---------
ModMatchExpression::ModMatchExpression(StringData path, int divisor, int remainder)
: LeafMatchExpression(MOD, path), _divisor(divisor), _remainder(remainder) {
uassert(ErrorCodes::BadValue, "divisor cannot be 0", divisor != 0);
}
bool ModMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
if (!e.isNumber())
return false;
return e.numberLong() % _divisor == _remainder;
}
void ModMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " mod " << _divisor << " % x == " << _remainder;
MatchExpression::TagData* td = getTag();
if (nullptr != td) {
debug << " ";
td->debugString(&debug);
}
debug << "\n";
}
BSONObj ModMatchExpression::getSerializedRightHandSide() const {
return BSON("$mod" << BSON_ARRAY(_divisor << _remainder));
}
bool ModMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType())
return false;
const ModMatchExpression* realOther = static_cast<const ModMatchExpression*>(other);
return path() == realOther->path() && _divisor == realOther->_divisor &&
_remainder == realOther->_remainder;
}
// ------------------
ExistsMatchExpression::ExistsMatchExpression(StringData path) : LeafMatchExpression(EXISTS, path) {}
bool ExistsMatchExpression::matchesSingleElement(const BSONElement& e,
MatchDetails* details) const {
return !e.eoo();
}
void ExistsMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " exists";
MatchExpression::TagData* td = getTag();
if (nullptr != td) {
debug << " ";
td->debugString(&debug);
}
debug << "\n";
}
BSONObj ExistsMatchExpression::getSerializedRightHandSide() const {
return BSON("$exists" << true);
}
bool ExistsMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType())
return false;
const ExistsMatchExpression* realOther = static_cast<const ExistsMatchExpression*>(other);
return path() == realOther->path();
}
// ----
InMatchExpression::InMatchExpression(StringData path)
: LeafMatchExpression(MATCH_IN, path),
_eltCmp(BSONElementComparator::FieldNamesMode::kIgnore, _collator) {}
std::unique_ptr<MatchExpression> InMatchExpression::shallowClone() const {
auto next = std::make_unique<InMatchExpression>(path());
next->setCollator(_collator);
if (getTag()) {
next->setTag(getTag()->clone());
}
next->_hasNull = _hasNull;
next->_hasEmptyArray = _hasEmptyArray;
next->_equalitySet = _equalitySet;
next->_originalEqualityVector = _originalEqualityVector;
for (auto&& regex : _regexes) {
std::unique_ptr<RegexMatchExpression> clonedRegex(
static_cast<RegexMatchExpression*>(regex->shallowClone().release()));
next->_regexes.push_back(std::move(clonedRegex));
}
return std::move(next);
}
bool InMatchExpression::contains(const BSONElement& e) const {
return std::binary_search(_equalitySet.begin(), _equalitySet.end(), e, _eltCmp.makeLessThan());
}
bool InMatchExpression::matchesSingleElement(const BSONElement& e, MatchDetails* details) const {
if (_hasNull && e.eoo()) {
return true;
}
if (contains(e)) {
return true;
}
for (auto&& regex : _regexes) {
if (regex->matchesSingleElement(e, details)) {
return true;
}
}
return false;
}
void InMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " $in ";
debug << "[ ";
for (auto&& equality : _equalitySet) {
debug << equality.toString(false) << " ";
}
for (auto&& regex : _regexes) {
regex->shortDebugString(debug);
debug << " ";
}
debug << "]";
MatchExpression::TagData* td = getTag();
if (nullptr != td) {
debug << " ";
td->debugString(&debug);
}
debug << "\n";
}
BSONObj InMatchExpression::getSerializedRightHandSide() const {
BSONObjBuilder inBob;
BSONArrayBuilder arrBob(inBob.subarrayStart("$in"));
for (auto&& _equality : _equalitySet) {
arrBob.append(_equality);
}
for (auto&& _regex : _regexes) {
BSONObjBuilder regexBob;
_regex->serializeToBSONTypeRegex(®exBob);
arrBob.append(regexBob.obj().firstElement());
}
arrBob.doneFast();
return inBob.obj();
}
bool InMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType()) {
return false;
}
const InMatchExpression* realOther = static_cast<const InMatchExpression*>(other);
if (path() != realOther->path()) {
return false;
}
if (_hasNull != realOther->_hasNull) {
return false;
}
if (_regexes.size() != realOther->_regexes.size()) {
return false;
}
for (size_t i = 0; i < _regexes.size(); ++i) {
if (!_regexes[i]->equivalent(realOther->_regexes[i].get())) {
return false;
}
}
if (!CollatorInterface::collatorsMatch(_collator, realOther->_collator)) {
return false;
}
// We use an element-wise comparison to check equivalence of '_equalitySet'. Unfortunately, we
// can't use BSONElementSet::operator==(), as it does not use the comparator object the set is
// initialized with (and as such, it is not collation-aware).
if (_equalitySet.size() != realOther->_equalitySet.size()) {
return false;
}
auto thisEqIt = _equalitySet.begin();
auto otherEqIt = realOther->_equalitySet.begin();
for (; thisEqIt != _equalitySet.end(); ++thisEqIt, ++otherEqIt) {
const bool considerFieldName = false;
if (thisEqIt->woCompare(*otherEqIt, considerFieldName, _collator)) {
return false;
}
}
invariant(otherEqIt == realOther->_equalitySet.end());
return true;
}
void InMatchExpression::_doSetCollator(const CollatorInterface* collator) {
_collator = collator;
_eltCmp = BSONElementComparator(BSONElementComparator::FieldNamesMode::kIgnore, _collator);
if (!std::is_sorted(_originalEqualityVector.begin(),
_originalEqualityVector.end(),
_eltCmp.makeLessThan())) {
std::sort(
_originalEqualityVector.begin(), _originalEqualityVector.end(), _eltCmp.makeLessThan());
}
// We need to re-compute '_equalitySet', since our set comparator has changed.
_equalitySet.clear();
_equalitySet.reserve(_originalEqualityVector.size());
std::unique_copy(_originalEqualityVector.begin(),
_originalEqualityVector.end(),
std::back_inserter(_equalitySet),
_eltCmp.makeEqualTo());
}
Status InMatchExpression::setEqualities(std::vector<BSONElement> equalities) {
for (auto&& equality : equalities) {
if (equality.type() == BSONType::RegEx) {
return Status(ErrorCodes::BadValue, "InMatchExpression equality cannot be a regex");
}
if (equality.type() == BSONType::Undefined) {
return Status(ErrorCodes::BadValue, "InMatchExpression equality cannot be undefined");
}
if (equality.type() == BSONType::jstNULL) {
_hasNull = true;
} else if (equality.type() == BSONType::Array && equality.Obj().isEmpty()) {
_hasEmptyArray = true;
}
}
_originalEqualityVector = std::move(equalities);
if (!std::is_sorted(_originalEqualityVector.begin(),
_originalEqualityVector.end(),
_eltCmp.makeLessThan())) {
std::sort(
_originalEqualityVector.begin(), _originalEqualityVector.end(), _eltCmp.makeLessThan());
}
_equalitySet.clear();
_equalitySet.reserve(_originalEqualityVector.size());
std::unique_copy(_originalEqualityVector.begin(),
_originalEqualityVector.end(),
std::back_inserter(_equalitySet),
_eltCmp.makeEqualTo());
return Status::OK();
}
Status InMatchExpression::addRegex(std::unique_ptr<RegexMatchExpression> expr) {
_regexes.push_back(std::move(expr));
return Status::OK();
}
MatchExpression::ExpressionOptimizerFunc InMatchExpression::getOptimizer() const {
return [](std::unique_ptr<MatchExpression> expression) -> std::unique_ptr<MatchExpression> {
// NOTE: We do not recursively call optimize() on the RegexMatchExpression children in the
// _regexes list. We assume that optimize() on a RegexMatchExpression is a no-op.
auto& regexList = static_cast<InMatchExpression&>(*expression)._regexes;
auto& equalitySet = static_cast<InMatchExpression&>(*expression)._equalitySet;
auto collator = static_cast<InMatchExpression&>(*expression).getCollator();
if (regexList.size() == 1 && equalitySet.empty()) {
// Simplify IN of exactly one regex to be a regex match.
auto& childRe = regexList.front();
invariant(!childRe->getTag());
auto simplifiedExpression = std::make_unique<RegexMatchExpression>(
expression->path(), childRe->getString(), childRe->getFlags());
if (expression->getTag()) {
simplifiedExpression->setTag(expression->getTag()->clone());
}
return std::move(simplifiedExpression);
} else if (equalitySet.size() == 1 && regexList.empty()) {
// Simplify IN of exactly one equality to be an EqualityMatchExpression.
auto simplifiedExpression = std::make_unique<EqualityMatchExpression>(
expression->path(), *(equalitySet.begin()));
simplifiedExpression->setCollator(collator);
if (expression->getTag()) {
simplifiedExpression->setTag(expression->getTag()->clone());
}
return std::move(simplifiedExpression);
}
return expression;
};
}
// -----------
BitTestMatchExpression::BitTestMatchExpression(MatchType type,
StringData path,
std::vector<uint32_t> bitPositions)
: LeafMatchExpression(type, path), _bitPositions(std::move(bitPositions)) {
// Process bit positions into bitmask.
for (auto bitPosition : _bitPositions) {
// Checking bits > 63 is just checking the sign bit, since we sign-extend numbers. For
// example, the 100th bit of -1 is considered set if and only if the 63rd bit position is
// set.
bitPosition = std::min(bitPosition, 63U);
_bitMask |= 1ULL << bitPosition;
}
}
BitTestMatchExpression::BitTestMatchExpression(MatchType type, StringData path, uint64_t bitMask)
: LeafMatchExpression(type, path), _bitMask(bitMask) {
// Process bitmask into bit positions.
for (int bit = 0; bit < 64; bit++) {
if (_bitMask & (1ULL << bit)) {
_bitPositions.push_back(bit);
}
}
}
BitTestMatchExpression::BitTestMatchExpression(MatchType type,
StringData path,
const char* bitMaskBinary,
uint32_t bitMaskLen)
: LeafMatchExpression(type, path) {
for (uint32_t byte = 0; byte < bitMaskLen; byte++) {
char byteAt = bitMaskBinary[byte];
if (!byteAt) {
continue;
}
// Build _bitMask with the first 8 bytes of the bitMaskBinary.
if (byte < 8) {
_bitMask |= static_cast<uint64_t>(byteAt) << byte * 8;
} else {
// Checking bits > 63 is just checking the sign bit, since we sign-extend numbers. For
// example, the 100th bit of -1 is considered set if and only if the 63rd bit position
// is set.
_bitMask |= 1ULL << 63;
}
for (int bit = 0; bit < 8; bit++) {
if (byteAt & (1 << bit)) {
_bitPositions.push_back(8 * byte + bit);
}
}
}
}
bool BitTestMatchExpression::needFurtherBitTests(bool isBitSet) const {
const MatchType mt = matchType();
return (isBitSet && (mt == BITS_ALL_SET || mt == BITS_ANY_CLEAR)) ||
(!isBitSet && (mt == BITS_ALL_CLEAR || mt == BITS_ANY_SET));
}
bool BitTestMatchExpression::performBitTest(long long eValue) const {
const MatchType mt = matchType();
switch (mt) {
case BITS_ALL_SET:
return (eValue & _bitMask) == _bitMask;
case BITS_ALL_CLEAR:
return (~eValue & _bitMask) == _bitMask;
case BITS_ANY_SET:
return eValue & _bitMask;
case BITS_ANY_CLEAR:
return ~eValue & _bitMask;
default:
MONGO_UNREACHABLE;
}
}
bool BitTestMatchExpression::performBitTest(const char* eBinary, uint32_t eBinaryLen) const {
const MatchType mt = matchType();
// Test each bit position.
for (auto bitPosition : _bitPositions) {
bool isBitSet;
if (bitPosition >= eBinaryLen * 8) {
// If position to test is longer than the data to test against, zero-extend.
isBitSet = false;
} else {
// Map to byte position and bit position within that byte. Note that byte positions
// start at position 0 in the char array, and bit positions start at the least
// significant bit.
int bytePosition = bitPosition / 8;
int bit = bitPosition % 8;
char byte = eBinary[bytePosition];
isBitSet = byte & (1 << bit);
}
if (!needFurtherBitTests(isBitSet)) {
// If we can skip the rest fo the tests, that means we succeeded with _ANY_ or failed
// with _ALL_.
return mt == BITS_ANY_SET || mt == BITS_ANY_CLEAR;
}
}
// If we finished all the tests, that means we succeeded with _ALL_ or failed with _ANY_.
return mt == BITS_ALL_SET || mt == BITS_ALL_CLEAR;
}
bool BitTestMatchExpression::matchesSingleElement(const BSONElement& e,
MatchDetails* details) const {
// Validate 'e' is a number or a BinData.
if (!e.isNumber() && e.type() != BSONType::BinData) {
return false;
}
if (e.type() == BSONType::BinData) {
int eBinaryLen; // Length of eBinary (in bytes).
const char* eBinary = e.binData(eBinaryLen);
return performBitTest(eBinary, eBinaryLen);
}
invariant(e.isNumber());
if (e.type() == BSONType::NumberDouble) {
double eDouble = e.numberDouble();
// NaN doubles are rejected.
if (std::isnan(eDouble)) {
return false;
}
// Integral doubles that are too large or small to be represented as a 64-bit signed
// integer are treated as 0. We use 'kLongLongMaxAsDouble' because if we just did
// eDouble > 2^63-1, it would be compared against 2^63. eDouble=2^63 would not get caught
// that way.
if (eDouble >= BSONElement::kLongLongMaxPlusOneAsDouble ||
eDouble < std::numeric_limits<long long>::min()) {
return false;
}
// This checks if e is an integral double.
if (eDouble != static_cast<double>(static_cast<long long>(eDouble))) {
return false;
}
}
long long eValue = e.numberLong();
return performBitTest(eValue);
}
void BitTestMatchExpression::debugString(StringBuilder& debug, int indentationLevel) const {
_debugAddSpace(debug, indentationLevel);
debug << path() << " ";
switch (matchType()) {
case BITS_ALL_SET:
debug << "$bitsAllSet:";
break;
case BITS_ALL_CLEAR:
debug << "$bitsAllClear:";
break;
case BITS_ANY_SET:
debug << "$bitsAnySet:";
break;
case BITS_ANY_CLEAR:
debug << "$bitsAnyClear:";
break;
default:
MONGO_UNREACHABLE;
}
debug << " [";
for (size_t i = 0; i < _bitPositions.size(); i++) {
debug << _bitPositions[i];
if (i != _bitPositions.size() - 1) {
debug << ", ";
}
}
debug << "]";
MatchExpression::TagData* td = getTag();
if (td) {
debug << " ";
td->debugString(&debug);
}
}
BSONObj BitTestMatchExpression::getSerializedRightHandSide() const {
std::string opString = "";
switch (matchType()) {
case BITS_ALL_SET:
opString = "$bitsAllSet";
break;
case BITS_ALL_CLEAR:
opString = "$bitsAllClear";
break;
case BITS_ANY_SET:
opString = "$bitsAnySet";
break;
case BITS_ANY_CLEAR:
opString = "$bitsAnyClear";
break;
default:
MONGO_UNREACHABLE;
}
BSONArrayBuilder arrBob;
for (auto bitPosition : _bitPositions) {
arrBob.append(bitPosition);
}
arrBob.doneFast();
return BSON(opString << arrBob.arr());
}
bool BitTestMatchExpression::equivalent(const MatchExpression* other) const {
if (matchType() != other->matchType()) {
return false;
}
const BitTestMatchExpression* realOther = static_cast<const BitTestMatchExpression*>(other);
std::vector<uint32_t> myBitPositions = getBitPositions();
std::vector<uint32_t> otherBitPositions = realOther->getBitPositions();
std::sort(myBitPositions.begin(), myBitPositions.end());
std::sort(otherBitPositions.begin(), otherBitPositions.end());
return path() == realOther->path() && myBitPositions == otherBitPositions;
}
}
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