Following Arthur's suggestion in http://stackoverflow.com/a/17304209/403875 I changed my Fixpoint relation to a mutual Inductive relation which "builds up" the different comparisons between games rather than "drilling down".

But now I'm receiving a new entirely error message

Error: Parameters should be syntactically the same for each inductive type.

I think the error message is saying that I need the same exact parameters for all of these mutual inductive definitions. I realize there are simple hacks to get around this (unused dummy variables, long functional types with everything inside the forall) but I don't see why I should have to. Can somebody explain the logic behind this restriction on mutual inductive types? Is there a more elegant way to write this? Does this restriction also imply that the inductive calls to each other must all use the same parameters (in which case I don't know of any hacks save hideous amounts of code duplication)?

(The definitions of all the types and terms such as compare_quest, game, g1side etc. are unchanged from what they were in my first question: How to indicate decreasing in size of two coq inductive types)

```
Inductive gameCompare (c : compare_quest) : game -> game -> Prop :=
| igc : forall g1 g2 : game,
innerGCompare (nextCompare c) (compareCombiner c) (g1side c) (g2side c) g1 g2 ->
gameCompare c g1 g2
with innerGCompare (next_c : compare_quest) (cbn : combiner) (g1s g2s : side)
: game -> game -> Prop :=
| compBoth : forall g1 g2 : game,
cbn (listGameCompare next_c cbn (g1s g1) g2)
(gameListCompare next_c cbn g1 (g2s g2)) ->
innerGCompare next_c cbn g1s g2s g1 g2
with listGameCompare (c : compare_quest) (cbn : combiner) : gamelist -> game -> Prop :=
| emptylgCompare : cbn_init cbn -> forall g2 : game, listGameCompare c cbn emptylist g2
| otlgCompare : forall (g1_cdr : gamelist) (g1_car g2 : game),
(cbn (listGameCompare c cbn g1_cdr g2) (gameCompare c g1_car g2)) ->
listGameCompare c cbn (listCons g1_car g1_cdr) g2
with gameListCompare (c : compare_quest) (cbn : combiner) : game -> gamelist -> Prop :=
| emptyglCompare : cbn_init cbn -> forall g1 : game, gameListCompare c cbn g1 emptylist
| otglCompare : forall (g1 g2_car : game) (g2_cdr : gamelist),
(cbn (gameListCompare c cbn g1 g2_cdr) (gameCompare c g1 g2_car)) ->
gameListCompare c cbn g1 (listCons g2_car g2_cdr).
```

In CGT, generally two players (named "Left" and "Right") take turns playing a game where the player to make the last move wins. Each game (meaning each position in a game) can be read as a set of Left's options and a set of Right's options written as {G_L | G_R} . When comparing two games, they can compare in any of four different ways: <, >, =, or ||. A game A < B if B is strictly better than A for Left regardless of who goes first. A > B if A is better than B for Left. A = B if the two games are equivalent (in the sense that the sum of games A + -B is a zero-game so that the player who goes first loses) and A || B if which game is better for Left depends who goes first.

One way to check the comparison between two games is as follows:

A <= B if all of A's Left children are <| B and A <| all of B's right children. A <| B if A has a right child which is <= B or if A <= any of B's left children. Similarly for >= and >|. So then by seeing which pair of these relations apply to two games A and B, it's possible to determine whether A < B (A<=B and A<|B), A=B (A<=B and A>=B), A > B (A>=B and A>|B), or A || B (A<|B and A>|B).

Here's the wiki article on CGT: http://en.wikipedia.org/wiki/Combinatorial_game_theory