Add documentation to gecode.mzn

MiniZinc uses this file to generate the reference documentation
Gecode · Jan 29, 2024 · b977abc · b977abc
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diff --git a/changelog.in b/changelog.in
@@ -69,6 +69,13 @@ Date: 2020-??-??
 [DESCRIPTION]
 Let's see.
 
+[ENTRY]
+Module: flatzinc
+What:   change
+Rank:   minor
+[DESCRIPTION]
+Add MiniZinc documentation comments to the Gecode-specific library file.
+
 [ENTRY]
 Module: flatzinc
 What:   bug

diff --git a/gecode/flatzinc/mznlib/gecode.mzn b/gecode/flatzinc/mznlib/gecode.mzn
@@ -30,44 +30,87 @@
 %
 %
 
-% This file contains predicate definitions for additional constraints available
-% in the Gecode FlatZinc interpreter.
+/***
+ @groupdef gecode Additional declarations for Gecode 
+
+ These annotations and predicates are available for the Gecode
+ solver. In order to use them in a model, include the file "gecode.mzn".
+*/
 
-% Additional search annotations
+/***
+ @groupdef gecode.annotations Additional Gecode search annotations
+*/
+
+/** @group gecode.annotations Select variable with smallest accumulated failure count */
 annotation afc_min;
+/** @group gecode.annotations Select variable with smallest accumulated failure count divided by domain size */
 annotation afc_size_min;
+/** @group gecode.annotations Select variable with largest accumulated failure count */
 annotation afc_max;
+/** @group gecode.annotations Select variable with largest accumulated failure count divided by domain size */
 annotation afc_size_max;
+/** @group gecode.annotations Select variable with smallest action count */
 annotation action_min;
+/** @group gecode.annotations Select variable with smallest action count divided by domain size */
 annotation action_size_min;
+/** @group gecode.annotations Select variable with largest action count */
 annotation action_max;
+/** @group gecode.annotations Select variable with largest action count divided by domain size */
 annotation action_size_max;
+/** @group gecode.annotations Select random variable */
 annotation random;
+
 annotation int_assign(array[int] of var int: x, ann:a);
 
+/** @group gecode.annotations Specify default search strategy for integer variables to use variable selection
+  strategy \a varsel, and value choice strategy \a valsel. */
 annotation int_default_search(ann: varsel, ann: valsel);
+/** @group gecode.annotations Specify default search strategy for Boolean variables to use variable selection
+  strategy \a varsel, and value choice strategy \a valsel. */
 annotation bool_default_search(ann: varsel, ann: valsel);
+/** @group gecode.annotations Specify default search strategy for set variables to use variable selection
+  strategy \a varsel, and value choice strategy \a valsel. */
 annotation set_default_search(ann: varsel, ann: valsel);
+/** @group gecode.annotations Specify default search strategy for float variables to use variable selection
+  strategy \a varsel, and value choice strategy \a valsel. */
 annotation float_default_search(ann: varsel, ann: valsel);
 
-% Simple LNS: upon restart, for each variable the probability of it being
-% fixed to the previous solution is 'percentage' (out of 100).
+/** @group gecode.annotations
+  Simple large neighbourhood search strategy: upon restart, for each variable in \a x,
+  the probability of it being fixed to the previous solution is \a percentage (out of 100).
+*/
 annotation relax_and_reconstruct(array[int] of var int: x, int: percentage);
 
-% Simple LNS: upon restart, for each variable the probability of it being
-% fixed to the previous solution is 'percentage' (out of 100). Start from
-% an initial solution y.
+/** @group gecode.annotations
+  Simple large neighbourhood search strategy: upon restart, for each variable in \a x,
+  the probability of it being fixed to the previous solution is \a percentage (out of 100).
+  Start from an initial solution \a y.
+*/
 annotation relax_and_reconstruct(array[int] of var int: x, int: percentage, array[int] of int: y);
 
-% i in z <-> forall (j in x) (i in y[j])
+/***
+ @groupdef gecode.constraints Additional Gecode constraints
+*/
+
+/** @group gecode.constraints
+  Constrain \a z to be the intersection of all sets
+  in \a y that are selected by \a x: \(i \in \a z \leftrightarrow \forall j \in \a x: (i \in \a y[j]) \)
+*/
 predicate gecode_array_set_element_intersect(var set of int: x,
     array[int] of var set of int: y, var set of int: z);
 
-% (i in z <-> exists (j in x) (i in y[j])) /\ (i in x /\ j in x /\ i!=j -> disjoint(y[i],y[j]))
+/** @group gecode.constraints
+  Constrain \a z to be the disjoint union of all sets
+  in \a y that are selected by \a x: \(i \in \a z \leftrightarrow \exists j \in \a x: (i \in \a y[j]) \)
+  and \( i \in \a x \land j \in \a x \land i\neq j \rightarrow \a y[i] \cap \a y[j]=\emptyset \)
+*/
 predicate gecode_array_set_element_partition(var set of int: x,
     array[int] of var set of int: y, var set of int: z);
 
-% z subset u /\ ( i in z <-> forall (j in x) (i in y[j]) )
+/** @group gecode.constraints
+  Constrain \a z to be a subset of \a u, and \a z to be the intersection of all sets
+  in \a y that are selected by \a x: \(i \in \a z \leftrightarrow \forall j \in \a x: (i \in \a y[j]) \)
+*/
 predicate gecode_array_set_element_intersect_in(var set of int: x,
     array[int] of var set of int: y,
     var set of int: z, set of int: u);
@@ -82,9 +125,16 @@ predicate gecode_among_seq_int(array[int] of var int: x, set of int: S,
 predicate gecode_among_seq_bool(array[int] of var bool: x, bool: b,
     int: l, int: m, int: n);
 
-% Overloading for among_seq
+/** @group gecode.constraints
+ Every subsequence of \a x of length \a l has at least \a m and at most \a n occurrences
+ of the values in \a S
+*/
 predicate among_seq(array[int] of var int: x, set of int: S,
     int: l, int: m, int: n) = gecode_among_seq_int(x,S,l,m,n);
+/** @group gecode.constraints
+ Every subsequence of \a x of length \a l has at least \a m and at most \a n occurrences
+ of the value \a b
+*/
 predicate among_seq(array[int] of var bool: x, bool: b,
     int: l, int: m, int: n) = gecode_among_seq_bool(x,b,l,m,n);
 
@@ -94,10 +144,21 @@ predicate gecode_circuit_cost_array(array[int] of int: c,
 predicate gecode_circuit_cost(array[int] of int: c, array[int] of var int: x,
     var int: z);
 
+/** @group gecode.constraints
+  Constrains the elements of \a x to define a circuit where \a x[\p i] = \p j means
+  that \p j is the successor of \p i. Additionally, constrain \a z to
+  be the cost of the circuit. Each edge cost is defined by array \a c. The variables
+  \a y[i] are constrained to be the edge cost of the node \a x[i].
+*/
 predicate circuit_cost_array(array[int] of int: c,
     array[int] of var int: x, array[int] of var int: y, var int: z) =
   gecode_circuit_cost_array(c,[x[i]-min(index_set(x)) | i in index_set(x)],
                             y,z);
+/** @group gecode.constraints
+  Constrains the elements of \a x to define a circuit where \a x[\p i] = \p j means
+  that \p j is the successor of \p i. Additionally, constrain \a z to
+  be the cost of the circuit. Each edge cost is defined by array \a c.
+*/
 predicate circuit_cost(array[int] of int: c, array[int] of var int: x,
     var int: z) =
   gecode_circuit_cost(c, [x[i]-min(index_set(x)) | i in index_set(x)], z);