These idioms have a few things in common. The final step for both is an index-of operation, they both use sort of a mirrored concatenation strategy, and perhaps most importantly, the output of the left and right arguments is the same for both. That simplifies the search for an identity quite a bit, because we can compare the right argument of #1 with the right argument of of #5:

```
(⍴Y)⍴⍋⍋X⍳Y,X ⍝ right arg #1
(⍋X⍳Y,X)⍳⍳⍴Y ⍝ right arg #5
```

Another thing that can simplify the search is getting rid of or modifying anything that truncates the output, because the output of both arguments is the same without truncating. Idiom # 1 uses `(⍴Y)⍴`

to truncate it to the length of `Y`

, and the length of right argument in idiom #5 depends on the length of `Y`

in `⍳⍴Y`

. In the first case, the truncation can be removed, and in the second, it can be modified to the full length of `Y,X`

:

```
⍋⍋X⍳Y,X ⍝ #1
(⍋X⍳Y,X)⍳⍳⍴Y,X ⍝ #5
```

Given that both expressions contain `⍋X⍳Y,X`

, let's assign that to a variable `A ← ⍋X⍳Y,X`

and simplify. However, it's important to point out that the identity we have now only applies if A is a permutation vector, and I'll be talking more about that later. In the meantime, we have this identity:

```
⍋A ←→ A⍳⍳⍴Y,X
```

Since ´Y,X´ does nothing in this expression except for provide the vector length, and since that length is equal to ´A´, the identity can be simplified to its final form:

```
⍋A ←→ A⍳⍳⍴A, where A is a permutation vector
```

This makes a lot of sense. The grade-up operator, on the left side of the identity, returns the index values that each value of `A`

would have if it were assorted in ascending order. The index-of operator, on the right, returns the index in A where the ascending values of `⍳⍴A`

are located. For example:

```
5 2 1 4 3 ⍝ A←5 2 1 4 3
3 2 5 4 1 ⍝ ⍋A
5 2 1 4 3 ⍝ A←5 2 1 4 3
1 2 3 4 5 ⍝ ⍳⍴A
3 2 5 4 1 ⍝ A⍳⍳⍴A
```

Looking at the last two rows, the 1 has an index of 3 in A, 2 has 2, 3 has 5, 4 has 4 and the final 5 has an index of 1. That makes sense because that is pretty much by definition what the grade-up operator does.

**Permutation Vectors**

As already said, this identity is only valid if A is a permutation vector. In his essay *Notation as a Tool of Thought* , Kenneth Iverson defined a permutation vector: “A vector P whose elements are some permutation of its indices (that is, ^/1=+/P∘.=⍳⍴P) will be called a permutation vector.” Looking at some of the idioms themselves, you can see this idea represented in various ways:

```
Y[⍋Y]^.=X[⍋X] #6 permutations of each other
X^.=⍋⍋X #7 test if permutation vector
X[⍋X]^.=⍳⍴X #29 test if permutation vector
⍋X #48 Inverting a permutation
X⍳⍳⍴X #212 Inverting a permutation
^/1=+⌿X∘.=⍳⍴X #281 test if permutation vector
^/(⍳⍴X)∊X #454 test if permutation vector
A←⍳⍴X ⋄ A[X]←A ⋄ A #654 Inverting a permutation
```

In idiom #7, the right side of the expression is the ascending cardinal numbers idiom, which I discussed in another post, and in that post I talked about the fact that the grade up operator switches back and forth between two states, rank and index, such that we have the following two identities:

```
⍋X ←→ ⍋⍋⍋X ←→ ⍋⍋⍋⍋⍋X ...
⍋⍋X ←→ ⍋⍋⍋⍋X ←→ ⍋⍋⍋⍋⍋⍋X ...
```

That second identity could be extend as follows, if X is a permutation vector as idiom #7 establishes:

```
X ←→ ⍋⍋X ←→ ⍋⍋⍋⍋X ←→ ⍋⍋⍋⍋⍋⍋X …
```

We know that the grade-up operator returns all the numbers from 1 to the number of values in the argument. Apply the grade-up operator two more times and you get the exact same vector in the same order. Therefore idiom #7 is just saying that a permutation vector is one which contains all the numbers from 1 to some other value once and only once. (This assumes that 1 is set as the first index value.)

Another thing that is interesting about the list of idioms above is that idiom #48 and #212 are the left and right sides of the identity discussed in the answer:

```
⍋A ←→ A⍳⍳⍴Y,X
```