Sort-merge join

Let $R$ and $S$ be relations where . $R$ fits in $P\_\{r\}$ pages memory and $S$ fits in $P\_\{s\}$ pages memory. In the worst case, a sort-merge join will run in $O(P\_\{r\}+P\_\{s\})$ I/O operations. In the case that $R$ and $S$ are not ordered the worst case time cost will contain additional terms of sorting time: $O(P\_\{r\}+P\_\{s\}+P\_\{r\}\backslash log(P\_\{r\})+\; P\_\{s\}\backslash log(P\_\{s\}))$, which equals $O(P\_\{r\}\backslash log(P\_\{r\})+\; P\_\{s\}\backslash log(P\_\{s\}))$ (as linearithmic terms outweigh the linear terms, see Big O notation – Orders of common functions).

For simplicity, the algorithm is described in the case of an inner join of two relations left and right. Generalization to other join types is straightforward. The output of the algorithm will contain only rows contained in the left and right relation and duplicates form a Cartesian product.

function Sort-Merge Join(left: Relation, right: Relation, comparator: Comparator) {

result = new Relation()

// Ensure that at least one element is present

if (!left.hasNext() || !right.hasNext()) {

return result

}

// Sort left and right relation with comparator

left.sort(comparator)

right.sort(comparator)

// Start Merge Join algorithm

leftRow = left.next()

rightRow = right.next()

outerForeverLoop:

while (true) {

while (comparator.compare(leftRow, rightRow) != 0) {

if (comparator.compare(leftRow, rightRow) < 0) {

// Left row is less than right row

if (left.hasNext()) {

// Advance to next left row

leftRow = left.next()

} else {

break outerForeverLoop

}

} else {

// Left row is greater than right row

if (right.hasNext()) {

// Advance to next right row

rightRow = right.next()

} else {

break outerForeverLoop

}

}

}

// Mark position of left row and keep copy of current left row

left.mark()

markedLeftRow = leftRow

while (true) {

while (comparator.compare(leftRow, rightRow) == 0) {

// Left row and right row are equal

// Add rows to result

result = add(leftRow, rightRow)

// Advance to next left row

leftRow = left.next()

// Check if left row exists

if (!leftRow) {

// Continue with inner forever loop

break

}

}

if (right.hasNext()) {

// Advance to next right row

rightRow = right.next()

} else {

break outerForeverLoop

}

if (comparator.compare(markedLeftRow, rightRow) == 0) {

// Restore left to stored mark

left.restoreMark()

leftRow = markedLeftRow

} else {

// Check if left row exists

if (!leftRow) {

break outerForeverLoop

} else {

// Continue with outer forever loop

break

}

}

}

}

return result

}

Since the comparison logic is not the central aspect of this algorithm, it is hidden behind a generic comparator and can also consist of several comparison criteria (e.g. multiple columns). The compare function should return if a row is less(-1), equal(0) or bigger(1) than another row:

function compare(leftRow: RelationRow, rightRow: RelationRow): number {

// Return -1 if leftRow is less than rightRow

// Return 0 if leftRow is equal to rightRow

// Return 1 if leftRow is greater than rightRow

}

Note that a relation in terms of this pseudocode supports some basic operations:

interface Relation {

// Returns true if relation has a next row (otherwise false)

hasNext(): boolean

// Returns the next row of the relation (if any)

next(): RelationRow

// Sorts the relation with the given comparator

sort(comparator: Comparator): void

// Marks the current row index

mark(): void

// Restores the current row index to the marked row index

restoreMark(): void

}

Note that this implementation assumes the join attributes are unique, i.e., there is no need to output multiple tuples for a given value of the key.

public class MergeJoin

{

// Assume that left and right are already sorted

public static Relation Merge(Relation left, Relation right)

{

Relation output = new Relation();

while (!left.IsPastEnd && !right.IsPastEnd)

{

if (left.Key == right.Key)

{

output.Add(left.Key);

left.Advance();

right.Advance();

}

else if (left.Key < right.Key)

left.Advance();

else // if (left.Key > right.Key)

right.Advance();

}

return output;

}

}

public class Relation

{

private const int ENDPOS = -1;

private List list;

private int position = 0;

public Relation()

{

this.list = new List();

}

public Relation(List list)

{

this.list = list;

}

public int Position => position;

public int Key => list[position];

public bool IsPastEnd => position == ENDPOS;

public bool Advance()

{

if (position == list.Count - 1 || position == ENDPOS)

{

position = ENDPOS;

return false;

}

position++;

return true;

}

public void Add(int key)

{

list.Add(key);

}

public void Print()

{

foreach (int key in list)

Console.WriteLine(key);

}

}

• Hash join
• Nested loop join

{{Reflist}}

[http://www.necessaryandsufficient.net/2010/02/join-algorithms-illustrated/ C# Implementations of Various Join Algorithms]

{{DEFAULTSORT:Sort-Merge Join}}

Category:Join algorithms

Category:Articles with example pseudocode

Category:Articles with example C Sharp code