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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/query/index_bounds.h"
#include <algorithm>
#include <tuple>
#include <utility>
#include "mongo/base/simple_string_data_comparator.h"
#include "mongo/bson/simple_bsonobj_comparator.h"
namespace mongo {
using std::string;
using std::vector;
namespace {
// Return a value in the set {-1, 0, 1} to represent the sign of parameter i.
int sgn(int i) {
if (i == 0)
return 0;
return i > 0 ? 1 : -1;
}
/**
* Returns BEHIND if the key is behind the interval.
* Returns WITHIN if the key is within the interval.
* Returns AHEAD if the key is ahead the interval.
*
* All directions are oriented along 'direction'.
*/
IndexBoundsChecker::Location intervalCmp(const Interval& interval,
const BSONElement& key,
const int expectedDirection) {
int cmp = sgn(key.woCompare(interval.start, false));
bool startOK = (cmp == expectedDirection) || (cmp == 0 && interval.startInclusive);
if (!startOK) {
return IndexBoundsChecker::BEHIND;
}
cmp = sgn(key.woCompare(interval.end, false));
bool endOK = (cmp == -expectedDirection) || (cmp == 0 && interval.endInclusive);
if (!endOK) {
return IndexBoundsChecker::AHEAD;
}
return IndexBoundsChecker::WITHIN;
}
} // namespace
// For debugging.
size_t IndexBounds::size() const {
return fields.size();
}
string IndexBounds::getFieldName(size_t i) const {
return i < size() ? fields[i].name : "";
}
size_t IndexBounds::getNumIntervals(size_t i) const {
return i < size() ? fields[i].intervals.size() : 0;
}
Interval IndexBounds::getInterval(size_t i, size_t j) const {
if (i < size() && j < fields[i].intervals.size()) {
return fields[i].intervals[j];
} else {
return Interval();
}
}
bool IndexBounds::operator==(const IndexBounds& other) const {
if (this->isSimpleRange != other.isSimpleRange) {
return false;
}
if (this->isSimpleRange) {
return SimpleBSONObjComparator::kInstance.evaluate(this->startKey == other.startKey) &&
SimpleBSONObjComparator::kInstance.evaluate(this->endKey == other.endKey) &&
(this->boundInclusion == other.boundInclusion);
}
if (this->fields.size() != other.fields.size()) {
return false;
}
for (size_t i = 0; i < this->fields.size(); ++i) {
if (this->fields[i] != other.fields[i]) {
return false;
}
}
return true;
}
bool IndexBounds::operator!=(const IndexBounds& other) const {
return !(*this == other);
}
string OrderedIntervalList::toString() const {
str::stream ss;
ss << "['" << name << "']: ";
for (size_t j = 0; j < intervals.size(); ++j) {
ss << intervals[j].toString();
if (j < intervals.size() - 1) {
ss << ", ";
}
}
return ss;
}
bool IndexBounds::isStartIncludedInBound(BoundInclusion boundInclusion) {
return boundInclusion == BoundInclusion::kIncludeBothStartAndEndKeys ||
boundInclusion == BoundInclusion::kIncludeStartKeyOnly;
}
bool IndexBounds::isEndIncludedInBound(BoundInclusion boundInclusion) {
return boundInclusion == BoundInclusion::kIncludeBothStartAndEndKeys ||
boundInclusion == BoundInclusion::kIncludeEndKeyOnly;
}
BoundInclusion IndexBounds::makeBoundInclusionFromBoundBools(bool startKeyInclusive,
bool endKeyInclusive) {
if (startKeyInclusive) {
if (endKeyInclusive) {
return BoundInclusion::kIncludeBothStartAndEndKeys;
} else {
return BoundInclusion::kIncludeStartKeyOnly;
}
} else {
if (endKeyInclusive) {
return BoundInclusion::kIncludeEndKeyOnly;
} else {
return BoundInclusion::kExcludeBothStartAndEndKeys;
}
}
}
BoundInclusion IndexBounds::reverseBoundInclusion(BoundInclusion b) {
switch (b) {
case BoundInclusion::kIncludeStartKeyOnly:
return BoundInclusion::kIncludeEndKeyOnly;
case BoundInclusion::kIncludeEndKeyOnly:
return BoundInclusion::kIncludeStartKeyOnly;
case BoundInclusion::kIncludeBothStartAndEndKeys:
case BoundInclusion::kExcludeBothStartAndEndKeys:
// These are both symmetric.
return b;
default:
MONGO_UNREACHABLE;
}
}
bool OrderedIntervalList::operator==(const OrderedIntervalList& other) const {
if (this->name != other.name) {
return false;
}
if (this->intervals.size() != other.intervals.size()) {
return false;
}
for (size_t i = 0; i < this->intervals.size(); ++i) {
if (this->intervals[i] != other.intervals[i]) {
return false;
}
}
return true;
}
bool OrderedIntervalList::operator!=(const OrderedIntervalList& other) const {
return !(*this == other);
}
void OrderedIntervalList::reverse() {
for (size_t i = 0; i < (intervals.size() + 1) / 2; i++) {
const size_t otherIdx = intervals.size() - i - 1;
intervals[i].reverse();
if (i != otherIdx) {
intervals[otherIdx].reverse();
std::swap(intervals[i], intervals[otherIdx]);
}
}
}
OrderedIntervalList OrderedIntervalList::reverseClone() const {
OrderedIntervalList clone(name);
for (auto it = intervals.rbegin(); it != intervals.rend(); ++it) {
clone.intervals.push_back(it->reverseClone());
}
return clone;
}
Interval::Direction OrderedIntervalList::computeDirection() const {
if (intervals.empty())
return Interval::Direction::kDirectionNone;
// Because the interval list is ordered, we only need to compare the two endpoints of the
// overall list. If the endpoints are ascending or descending, then each interval already
// respects that order. And if the endpoints are equal, then all the intervals must be squeezed
// into a single point.
bool compareFieldNames = false;
int res = intervals.front().start.woCompare(intervals.back().end, compareFieldNames);
if (res == 0)
return Interval::Direction::kDirectionNone;
return res < 0 ? Interval::Direction::kDirectionAscending
: Interval::Direction::kDirectionDescending;
}
bool OrderedIntervalList::isMinToMax() const {
return intervals.size() == 1 && intervals[0].isMinToMax();
}
// static
void OrderedIntervalList::complement() {
BSONObjBuilder minBob;
minBob.appendMinKey("");
BSONObj minObj = minBob.obj();
// We complement by scanning the entire range of BSON values from MinKey to MaxKey. The value
// from which we must begin the next complemented interval is kept in 'curBoundary'.
BSONElement curBoundary = minObj.firstElement();
// If 'curInclusive' is true, then 'curBoundary' is included in one of the original intervals,
// and hence should not be included in the complement (and vice-versa if 'curInclusive' is
// false).
bool curInclusive = false;
// We will build up a list of intervals that represents the inversion of those in the OIL.
vector<Interval> newIntervals;
for (const auto& curInt : intervals) {
// There is one special case worth optimizing for: we will generate two point queries for an
// equality-to-null predicate like {a: {$eq: null}}. The points are undefined and null, so
// when complementing (for {a: {$ne: null}} or similar), we know that there is nothing in
// between these two points, and can avoid adding that range.
const bool isProvablyEmptyRange =
(curBoundary.type() == BSONType::Undefined && curInclusive &&
curInt.start.type() == BSONType::jstNULL && curInt.startInclusive);
if ((0 != curInt.start.woCompare(curBoundary) ||
(!curInclusive && !curInt.startInclusive)) &&
!isProvablyEmptyRange) {
// Make a new interval from 'curBoundary' to the start of 'curInterval'.
BSONObjBuilder intBob;
intBob.append(curBoundary);
intBob.append(curInt.start);
Interval newInt(intBob.obj(), !curInclusive, !curInt.startInclusive);
newIntervals.push_back(newInt);
}
// Reset the boundary for the next iteration.
curBoundary = curInt.end;
curInclusive = curInt.endInclusive;
}
// We may have to add a final interval which ends in MaxKey.
BSONObjBuilder maxBob;
maxBob.appendMaxKey("");
BSONObj maxObj = maxBob.obj();
BSONElement maxKey = maxObj.firstElement();
if (0 != maxKey.woCompare(curBoundary) || !curInclusive) {
BSONObjBuilder intBob;
intBob.append(curBoundary);
intBob.append(maxKey);
Interval newInt(intBob.obj(), !curInclusive, true);
newIntervals.push_back(newInt);
}
// Replace the old list of intervals with the new one.
intervals.clear();
intervals.insert(intervals.end(), newIntervals.begin(), newIntervals.end());
}
string IndexBounds::toString() const {
str::stream ss;
if (isSimpleRange) {
if (IndexBounds::isStartIncludedInBound(boundInclusion)) {
ss << "[";
} else {
ss << "(";
}
ss << startKey.toString() << ", ";
if (endKey.isEmpty()) {
ss << "]";
} else {
ss << endKey.toString();
if (IndexBounds::isEndIncludedInBound(boundInclusion)) {
ss << "]";
} else {
ss << ")";
}
}
return ss;
}
for (size_t i = 0; i < fields.size(); ++i) {
if (i > 0) {
ss << ", ";
}
ss << "field #" << i << fields[i].toString();
}
return ss;
}
BSONObj IndexBounds::toBSON() const {
BSONObjBuilder bob;
vector<OrderedIntervalList>::const_iterator itField;
for (itField = fields.begin(); itField != fields.end(); ++itField) {
BSONArrayBuilder fieldBuilder(bob.subarrayStart(itField->name));
vector<Interval>::const_iterator itInterval;
for (itInterval = itField->intervals.begin(); itInterval != itField->intervals.end();
++itInterval) {
std::string intervalStr = itInterval->toString();
// Insulate against hitting BSON size limit.
if ((bob.len() + (int)intervalStr.size()) > BSONObjMaxUserSize) {
fieldBuilder.append("warning: bounds truncated due to BSON size limit");
fieldBuilder.doneFast();
return bob.obj();
}
fieldBuilder.append(intervalStr);
}
fieldBuilder.doneFast();
}
return bob.obj();
}
IndexBounds IndexBounds::forwardize() const {
IndexBounds newBounds;
newBounds.isSimpleRange = isSimpleRange;
if (isSimpleRange) {
const int cmpRes = startKey.woCompare(endKey);
if (cmpRes <= 0) {
newBounds.startKey = startKey;
newBounds.endKey = endKey;
newBounds.boundInclusion = boundInclusion;
} else {
// Swap start and end key.
newBounds.endKey = startKey;
newBounds.startKey = endKey;
newBounds.boundInclusion = IndexBounds::reverseBoundInclusion(boundInclusion);
}
return newBounds;
}
newBounds.fields.reserve(fields.size());
std::transform(fields.begin(),
fields.end(),
std::back_inserter(newBounds.fields),
[](const OrderedIntervalList& oil) {
if (oil.computeDirection() == Interval::Direction::kDirectionDescending) {
return oil.reverseClone();
}
return oil;
});
return newBounds;
}
IndexBounds IndexBounds::reverse() const {
IndexBounds reversed(*this);
if (reversed.isSimpleRange) {
std::swap(reversed.startKey, reversed.endKey);
// If only one bound is included, swap which one is included.
reversed.boundInclusion = reverseBoundInclusion(reversed.boundInclusion);
} else {
for (auto& orderedIntervalList : reversed.fields) {
orderedIntervalList.reverse();
}
}
return reversed;
}
//
// Validity checking for bounds
//
bool OrderedIntervalList::isValidFor(int expectedOrientation) const {
// Make sure each interval's start is oriented correctly with respect to its end.
for (size_t j = 0; j < intervals.size(); ++j) {
// false means don't consider field name.
int cmp = sgn(intervals[j].end.woCompare(intervals[j].start, false));
if (cmp == 0 && intervals[j].startInclusive && intervals[j].endInclusive) {
continue;
}
if (cmp != expectedOrientation) {
return false;
}
}
// Make sure each interval is oriented correctly with respect to its neighbors.
for (size_t j = 1; j < intervals.size(); ++j) {
int cmp = sgn(intervals[j].start.woCompare(intervals[j - 1].end, false));
// TODO: We could care if the end of one interval is the start of another. The bounds
// are still valid but they're a bit sloppy; they could have been combined to form one
// interval if either of them is inclusive.
if (0 == cmp) {
continue;
}
if (cmp != expectedOrientation) {
return false;
}
}
return true;
}
bool IndexBounds::isValidFor(const BSONObj& keyPattern, int direction) {
if (isSimpleRange) {
return direction == sgn(endKey.woCompare(startKey, keyPattern, false));
}
BSONObjIterator it(keyPattern);
for (size_t i = 0; i < fields.size(); ++i) {
// We expect a bound for each field in the index.
if (!it.more()) {
return false;
}
BSONElement elt = it.next();
const OrderedIntervalList& field = fields[i];
// Make sure the names match up.
if (field.name != elt.fieldName()) {
return false;
}
// Special indices are all inserted increasing. elt.number() will return 0 if it's
// not a number. Special indices are strings, not numbers.
int expectedOrientation = direction * ((elt.number() >= 0) ? 1 : -1);
if (!field.isValidFor(expectedOrientation)) {
return false;
}
}
return !it.more();
}
//
// Iteration over index bounds
//
IndexBoundsChecker::IndexBoundsChecker(const IndexBounds* bounds,
const BSONObj& keyPattern,
int scanDirection)
: _bounds(bounds), _curInterval(bounds->fields.size(), 0) {
BSONObjIterator it(keyPattern);
while (it.more()) {
int indexDirection = it.next().number() >= 0 ? 1 : -1;
_expectedDirection.push_back(indexDirection * scanDirection);
}
}
bool IndexBoundsChecker::getStartSeekPoint(IndexSeekPoint* out) {
out->prefixLen = 0;
out->prefixExclusive = false;
out->keySuffix.resize(_bounds->fields.size());
out->suffixInclusive.resize(_bounds->fields.size());
for (size_t i = 0; i < _bounds->fields.size(); ++i) {
if (0 == _bounds->fields[i].intervals.size()) {
return false;
}
out->keySuffix[i] = &_bounds->fields[i].intervals[0].start;
out->suffixInclusive[i] = _bounds->fields[i].intervals[0].startInclusive;
}
return true;
}
bool IndexBoundsChecker::findLeftmostProblem(const vector<BSONElement>& keyValues,
size_t* where,
Location* what) {
// For each field in the index key, see if it's in the interval it should be.
for (size_t i = 0; i < _curInterval.size(); ++i) {
const OrderedIntervalList& field = _bounds->fields[i];
const Interval& currentInterval = field.intervals[_curInterval[i]];
Location cmp = intervalCmp(currentInterval, keyValues[i], _expectedDirection[i]);
// If it's not in the interval we think it is...
if (0 != cmp) {
*where = i;
*what = cmp;
return true;
}
}
return false;
}
bool IndexBoundsChecker::spaceLeftToAdvance(size_t fieldsToCheck,
const vector<BSONElement>& keyValues) {
// Check end conditions. Since we need to move the keys before
// firstNonContainedField forward, let's make sure that those fields are not at the
// end of their bounds.
for (size_t i = 0; i < fieldsToCheck; ++i) {
// Field 'i' isn't at its last interval. There's possibly a key we could move forward
// to, either in the current interval or the next one.
if (_curInterval[i] != _bounds->fields[i].intervals.size() - 1) {
return true;
}
// Field 'i' is at its last interval.
const Interval& ival = _bounds->fields[i].intervals[_curInterval[i]];
// We're OK if it's an open interval. There are an infinite number of keys between any
// key and the end point...
if (!ival.endInclusive) {
return true;
}
// If it's a closed interval, we're fine so long as we haven't hit the end point of
// the interval.
if (-_expectedDirection[i] == sgn(keyValues[i].woCompare(ival.end, false))) {
return true;
}
}
return false;
}
bool IndexBoundsChecker::isValidKey(const BSONObj& key) {
BSONObjIterator it(key);
size_t curOil = 0;
while (it.more()) {
BSONElement elt = it.next();
size_t whichInterval;
Location loc = findIntervalForField(
elt, _bounds->fields[curOil], _expectedDirection[curOil], &whichInterval);
if (WITHIN != loc) {
return false;
}
++curOil;
}
return true;
}
IndexBoundsChecker::KeyState IndexBoundsChecker::checkKey(const BSONObj& key, IndexSeekPoint* out) {
verify(_curInterval.size() > 0);
out->keySuffix.resize(_curInterval.size());
out->suffixInclusive.resize(_curInterval.size());
// It's useful later to go from a field number to the value for that field. Store these.
// TODO: on optimization pass, populate the vector as-needed and keep the vector around as a
// member variable
vector<BSONElement> keyValues;
BSONObjIterator keyIt(key);
while (keyIt.more()) {
keyValues.push_back(keyIt.next());
}
verify(keyValues.size() == _curInterval.size());
size_t firstNonContainedField;
Location orientation;
if (!findLeftmostProblem(keyValues, &firstNonContainedField, &orientation)) {
// All fields in the index are within the current interval. Caller can use the key.
return VALID;
}
// Field number 'firstNonContainedField' of the index key is before its current interval.
if (BEHIND == orientation) {
// It's behind our current interval, but our current interval could be wrong. Start all
// intervals from firstNonContainedField to the right over...
for (size_t i = firstNonContainedField; i < _curInterval.size(); ++i) {
_curInterval[i] = 0;
}
// ...and try again. This call modifies 'orientation', so we may check its value again
// in the clause below if field number 'firstNonContainedField' isn't in its first
// interval.
if (!findLeftmostProblem(keyValues, &firstNonContainedField, &orientation)) {
return VALID;
}
}
// Field number 'firstNonContainedField' of the index key is before all current intervals.
if (BEHIND == orientation) {
// Tell the caller to move forward to the start of the current interval.
out->keyPrefix = key.getOwned();
out->prefixLen = firstNonContainedField;
out->prefixExclusive = false;
for (size_t j = firstNonContainedField; j < _curInterval.size(); ++j) {
const OrderedIntervalList& oil = _bounds->fields[j];
out->keySuffix[j] = &oil.intervals[_curInterval[j]].start;
out->suffixInclusive[j] = oil.intervals[_curInterval[j]].startInclusive;
}
return MUST_ADVANCE;
}
verify(AHEAD == orientation);
// Field number 'firstNonContainedField' of the index key is after interval we think it's
// in. Fields 0 through 'firstNonContained-1' are within their current intervals and we can
// ignore them.
while (firstNonContainedField < _curInterval.size()) {
// Find the interval that contains our field.
size_t newIntervalForField;
Location where = findIntervalForField(keyValues[firstNonContainedField],
_bounds->fields[firstNonContainedField],
_expectedDirection[firstNonContainedField],
&newIntervalForField);
if (WITHIN == where) {
// Found a new interval for field firstNonContainedField. Move our internal choice
// of interval to that.
_curInterval[firstNonContainedField] = newIntervalForField;
// Let's find valid intervals for fields to the right.
++firstNonContainedField;
} else if (BEHIND == where) {
// firstNonContained field is between the intervals (newIntervalForField-1) and
// newIntervalForField. We have to tell the caller to move forward until he at
// least hits our new current interval.
_curInterval[firstNonContainedField] = newIntervalForField;
// All other fields to the right start at their first interval.
for (size_t i = firstNonContainedField + 1; i < _curInterval.size(); ++i) {
_curInterval[i] = 0;
}
out->keyPrefix = key.getOwned();
out->prefixLen = firstNonContainedField;
out->prefixExclusive = false;
for (size_t i = firstNonContainedField; i < _curInterval.size(); ++i) {
const OrderedIntervalList& oil = _bounds->fields[i];
out->keySuffix[i] = &oil.intervals[_curInterval[i]].start;
out->suffixInclusive[i] = oil.intervals[_curInterval[i]].startInclusive;
}
return MUST_ADVANCE;
} else {
verify(AHEAD == where);
// Field number 'firstNonContainedField' cannot possibly be placed into an interval,
// as it is already past its last possible interval. The caller must move forward
// to a key with a greater value for the previous field.
// If all fields to the left have hit the end of their intervals, we can't ask them
// to move forward and we should stop iterating.
if (!spaceLeftToAdvance(firstNonContainedField, keyValues)) {
return DONE;
}
out->keyPrefix = key.getOwned();
out->prefixLen = firstNonContainedField;
out->prefixExclusive = true;
for (size_t i = firstNonContainedField; i < _curInterval.size(); ++i) {
_curInterval[i] = 0;
}
// If movePastKeyElts is true, we don't examine any fields after the keyEltsToUse
// fields of the key. As such we don't populate the out/incOut.
return MUST_ADVANCE;
}
}
verify(firstNonContainedField == _curInterval.size());
return VALID;
}
namespace {
/**
* Returns true if key (first member of pair) is AHEAD of interval
* along 'direction' (second member of pair).
*/
bool isKeyAheadOfInterval(const Interval& interval,
const std::pair<BSONElement, int>& keyAndDirection) {
const BSONElement& elt = keyAndDirection.first;
int expectedDirection = keyAndDirection.second;
IndexBoundsChecker::Location where = intervalCmp(interval, elt, expectedDirection);
return IndexBoundsChecker::AHEAD == where;
}
} // namespace
// static
IndexBoundsChecker::Location IndexBoundsChecker::findIntervalForField(
const BSONElement& elt,
const OrderedIntervalList& oil,
const int expectedDirection,
size_t* newIntervalIndex) {
// Binary search for interval.
// Intervals are ordered in the same direction as our keys.
// Key behind all intervals: [BEHIND, ..., BEHIND]
// Key ahead of all intervals: [AHEAD, ..., AHEAD]
// Key within one interval: [AHEAD, ..., WITHIN, BEHIND, ...]
// Key not in any inteval: [AHEAD, ..., AHEAD, BEHIND, ...]
// Find left-most BEHIND/WITHIN interval.
vector<Interval>::const_iterator i = std::lower_bound(oil.intervals.begin(),
oil.intervals.end(),
std::make_pair(elt, expectedDirection),
isKeyAheadOfInterval);
// Key ahead of all intervals.
if (i == oil.intervals.end()) {
return AHEAD;
}
// Found either interval containing key or left-most BEHIND interval.
*newIntervalIndex = std::distance(oil.intervals.begin(), i);
// Additional check to determine if interval contains key.
Location where = intervalCmp(*i, elt, expectedDirection);
invariant(BEHIND == where || WITHIN == where);
return where;
}
} // namespace mongo
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