Option 1:

```
key=lambda d:(d['rank']==0, d['rank'])
```

Option 2:

```
key=lambda d:d['rank'] if d['rank']!=0 else float('inf')
```

Demo:

"I'd like to sort it by the rank values, ordering as follows: 1-2-3-4-0-0-0." --original poster

```
>>> sorted([0,0,0,1,2,3,4], key=lambda x:(x==0, x))
[1, 2, 3, 4, 0, 0]
>>> sorted([0,0,0,1,2,3,4], key=lambda x:x if x!=0 else float('inf'))
[1, 2, 3, 4, 0, 0]
```

Additional comments:

"Please could you explain to me (a Python novice) what it's doing? I can see that it's a lambda, which I know is an anonymous function: what's the bit in brackets?" – OP comment

**Indexing/slice notation**:

`itemgetter('rank')`

is the same thing as `lambda x: x['rank']`

is the same thing as the function:

```
def getRank(myDict):
return myDict['rank']
```

The `[...]`

is called the indexing/slice notation, see Good Primer for Python Slice Notation - Also note that `someArray[n]`

is common notation in many programming languages for indexing, but may not support slices of the form `[start:end]`

or `[start:end:step]`

.

`key=`

vs `cmp=`

vs rich comparison:

As for what is going on, there are two common ways to specify how a sorting algorithm works: one is with a `key`

function, and the other is with a `cmp`

function (now deprecated in python, but a lot more versatile). While a `cmp`

function allows you to arbitrarily specify how two elements should compare (input: `a`

,`b`

; output: `a<b`

or `a>b`

or `a==b`

). Though legitimate, it gives us no major benefit (we'd have to duplicate code in an awkward manner), and a key function is more natural for your case. (See "object rich comparison" for how to implicitly define `cmp=`

in an elegant but possibly-excessive way.)

**Implementing your key function**:

Unfortunately 0 is an element of the integers and thus has a natural ordering: 0 is normally < 1,2,3... Thus if we want to impose an extra rule, we need to sort the list at a "higher level". We do this by making the key a tuple: tuples are sorted first by their 1st element, then by their 2nd element. True will always be ordered after False, so all the Trues will be ordered after the Falses; they will then sort as normal: `(True,1)<(True,2)<(True,3)<...`

, `(False,1)<(False,2)<...`

, `(False,*)<(True,*)`

. The alternative (option 2), merely assigns rank-0 dictionaries a value of infinity, since that is guaranteed to be above any possible rank.

**More general alternative** - object rich comparison:

The even more general solution would be to create a class representing records, then implement `__lt__`

, `__gt__`

, `__eq__`

, `__ne__`

, `__gt__`

, `__ge__`

, and all the other rich comparison operators, or alternatively just implement one of those and `__eq__`

and use the `@functools.total_ordering`

decorator. This will cause objects of that class to use the custom logic whenever you use comparison operators (e.g. `x=Record(name='Joe', rank=12)`

`y=Record(...)`

`x<y`

); since the `sorted(...)`

function uses `<`

and other comparison operators by default in a comparison sort, this will make the behavior automatic when sorting, and in other instances where you use `<`

and other comparison operators. This may or may not be excessive depending on your use case.

**Cleaner alternative** - don't overload 0 with semantics:

I should however point out that it's a bit artificial to put 0s behind 1,2,3,4,etc. Whether this is justified depends on whether rank=0 really means rank=0; if rank=0 are really "lower" than rank=1 (which in turn are really "lower" than rank=2...). If this is truly the case, then your method is perfectly fine. If this is not the case, then you might consider omitting the `'rank':...`

entry as opposed to setting `'rank':0`

. Then you could sort by Lev Levitsky's answer using `'rank' in d`

, or by:

Option 1 with different scheme:

```
key=lambda d: (not 'rank' in d, d['rank'])
```

Option 2 with different scheme:

```
key=lambda d: d.get('rank', float('inf'))
```

*sidenote: Relying on the existence of infinity in python is almost borderline a hack, making any of the mentioned solutions (tuples, object comparison), Lev's filter-then-concatenate solution, and even maybe the slightly-more-complicated *`cmp`

solution (typed up by wilson), more generalizable to other languages.