Yes, it's correct. Proof can be constructed along the following lines.
Always when j-loop (the inner) completes (so j=n, i will be increased as next op), then a[i] is the max, and the part before a[i] is in ascending order (proofs below). So when the outer cycle is about to complete with i=n-1 then a[i] is max, and the items up to the index i are ordered (and since none of the preceding items is greater than max) so the whole array is ordered.
To prove that a[i] is always max after the j-loop is simple: i is not changing while the j-loop and if j encounters an item larger than a[i] then that is brought to a[i] and since j has scanned the whole array it's not possible that it includes an element larger than a[i].
To prove that the items up to i are ordered is full induction. We will use the above statement about a[i] being max.
For i=0 trivial (no preceding elements). a is max and "it is ordered".
i=1 (just for fun): 1 item got to a (don't care about its value, it cannot be greater than max), and a is max. So a[0..1] sorted.
Now if the theses are satisfied after a j-loop ending at i=k then the following happens:
i <- k+1
Let's say the current item a[i]=q.
j scans a to k. Since k is the max it will be swapped to i. The items beyond i are not bothered yet. So essentially max moves up by one, so one item, particulaily q was added to the first part of the array. Let's see how:
The sorted part to max is scanned by j until it finds an item at index m that is larger than a[i]. (It will find a[i-1] in the worst case.) The items up to m are sorted. Now a[i] will be inserted here, an all items in the range [m..i-1] will be moved up by one. Since m is a right place to insert a[i] so a[0..i] will be ordered after the move. Now the only thing to prove is that the j-loop in [m..i] really performs a move:
At the beginning the sequence a[i],a[m..i-1] is ordered, thus every comparison in this interval will trigger a swap: a[i] is always the smallest in the a[j..i] part. The swap (i with j) will make the j-th to be at the right place (minimal item to the front) and j steps on to the remaining part of the interval.
So j reaches i=k+1 (no swap here) and a[k+1] is max so no more swaps in this j-loop, so at the end a[0..k+1] is sorted.
So finally if the theses hold for i=k then they hold for i=k+1 after a j-loop. We'we established that they hold for i=0 after 1 j-loop, and from i-loop shows that there will be altogether n j-loops so the theses hold for i=n-1 which is just what we've promised to prove in the firs paragraph.