## MergeAt()
Now, let's discuss `mergeAt` procedure, which is used to merge two runs.
Let $base_i$ and $len_i$ are base address and length of $run_i$, respectively.
We perform two operations before merging two runs:
1. Find index of the first element of $run_2$ into $run_1$. If the index turns out to be the last, then no merging is required.
Otherwise just increment the base address for $run_1$, because the elements before this index are already in place.
2. Similarly, find index of the last element of $run_1$ in $run_2$. If the index turns out to be the first, then no merging is required.
Otherwise set $len_2$ to this index, because the elements after this index are already in place.
After performing this operation you notice that all elements of $run_2$ are less than last element of $run_1$ and first element fo $run_1$ is greater than first element of $run_2$, i.e. $run_1[base_1] > run_2[base_2]$. These implies two things:
Conclusion 1. The last element of $run_1$ is the largest element.
Conclusion 2. The first element of $run_2$ is the smallest element.
We will see how useful these conclusions are! Just keep it in mind.
Now, Let say we are merging two sorted arrays of size _$len_1$_ and _$len_2$_. In traditional merge procedure, we create a new array of size $len_1$+$len_2$. But in Tim sort's merge procedure, we just create a new temporary array of size $min(len1,len2)$ and we copy the smaller array into this temporary array.
The main intention behind it is to decrease **merge space overhead**, because it reduces the number of required element movements.
Notice that we can do merging in both directions: **left-to-right**, as in the traditional mergesort, or **right-to-left**.
Now, suppose the $len_1$ is less than $len_2$, then we will create a temporary copy of $run_1$. To merge them, we are not going to allocate any more memory, but we will merge them directly into the main array, in **left-to-right** direction. In the other case($len_2$ < $len_1$), we will merge them in **right-to-left** direction.
**The reason for different directions is that by doing this we are able to do merging in the main list itself.** You will be able to see this when we will see `merge_LtoR` and `merge_RtoL`.
```cpp
// Merges two runs
// parameter i must be stacksize - 2 or stacksize - 3
void mergeAt(vector<int>& data, int i)
{
int base1 = stack_of_runs[i].base_address;
int len1 = stack_of_runs[i].len;
int base2 = stack_of_runs[i + 1].base_address;
int len2 = stack_of_runs[i + 1].len;
stack_of_runs[i].len = len1 + len2;
// Copy the third last run to 2nd last
if (i == stackSize - 3)
stack_of_runs[i + 1] = stack_of_runs[i + 2];
stackSize--;
// Find position of first element of run2 into run1
// prior elements of run1 are already in place
// so just ignore it
int pos1 = gallopRight(data, data[base2], base1, len1, 0);
base1 += pos1;
len1 -= pos1;
if (len1 == 0)
return;
// Find where the last element of run1 goes into run2
// subsequent elements of run2 are already in place
// so just ignore it
len2 = gallopLeft(data, data[base1 + len1 - 1], base2, len2, len2 - 1);
if (len2 == 0)
return;
if (len1 <= len2)
merge_LtoR(data, base1, len1, base2, len2);
else
merge_RtoL(data, base1, len1, base2, len2);
}
```
Time complexity will be discussed in the next article.