c22b9cb0cc7f34fcc0eff0cb44b5f3f69ccc62c8
1 /************************************************************************
2 ************************************************************************
4 Copyright (C) 2003-2004 GRAME, Centre National de Creation Musicale
5 ---------------------------------------------------------------------
6 This program is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 2 of the License, or
9 (at your option) any later version.
11 This program is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with this program; if not, write to the Free Software
18 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
19 ************************************************************************
20 ************************************************************************/
25 #include "recursivness.hh"
26 #include "property.hh"
36 * @file recursivness.cpp
37 * Annotate a signal expression with recursivness information. Recursiveness
38 * indicates the amount of recursive dependencies of a signal. A closed signal
39 * has a recursivness of 0 because is has no recursive dependencies. This means
40 * that the succesive samples of this signal can be computed in parallel.
41 * In a signal of type \x.(...F(x)...), F(x) has a recursivness of 1. In a
42 * signal of type \x.(... \y.(...F(x)...G(y)...)...) F(x) has a recursivness of 2
43 * while G(y) has a recursivness of 1.
46 //--------------------------------------------------------------------------
47 static int annotate(Tree env
, Tree sig
);
48 static int position (Tree env
, Tree t
, int p
=1);
50 Tree RECURSIVNESS
= tree(symbol("RecursivnessProp"));
51 //--------------------------------------------------------------------------
55 * Annotate a signal with recursivness. Should be used before
56 * calling getRecursivness
57 * @param sig signal to annotate
59 void recursivnessAnnotation(Tree sig
)
66 * Return the recursivness of a previously
67 * annotated signal. An error is generated
68 * if the signal has no recursivness property
70 * @return recursivness of the signal
72 int getRecursivness(Tree sig
)
75 if ( ! getProperty(sig
, RECURSIVNESS
, tr
)) {
76 cerr
<< "Error in getRecursivness of " << *sig
<< endl
;
82 //-------------------------------------- IMPLEMENTATION ------------------------------------
84 * Annotate a signal with recursivness
85 * @param env the current environment
86 * @param sig signal to annotate
87 * @return recursivness of the signal
89 static int annotate(Tree env
, Tree sig
)
93 if (getProperty(sig
, RECURSIVNESS
, tr
)) {
94 return tree2int(tr
); // already annotated
95 } else if (isRec(sig
, var
, body
)) {
96 int p
= position(env
, sig
);
98 return p
; // we are inside \x.(...)
100 int r
= annotate(cons(sig
, env
), body
) - 1;
102 setProperty(sig
, RECURSIVNESS
, tree(r
));
107 vector
<Tree
> v
; getSubSignals(sig
, v
);
108 for (unsigned int i
=0; i
<v
.size(); i
++) {
109 int r
= annotate(env
, v
[i
]);
112 setProperty(sig
, RECURSIVNESS
, tree(rmax
));
120 * return the position of a signal in the current recursive environment
121 * @param env the current recursive environment of the signal
122 * @param t signal we want to know the position
123 * @return the position in the recursive environment
125 static int position (Tree env
, Tree t
, int p
)
127 if (isNil(env
)) return 0; // was not in the environment
128 if (hd(env
) == t
) return p
;
129 else return position (tl(env
), t
, p
+1);
133 //-----------------------------------list recursive symbols-----------------------
138 * return the set of recursive symbols appearing in a signal.
139 * @param sig the signal to analyze
140 * @return the set of symbols
143 // the property used to memoize the results
144 property
<Tree
> SymListProp
;
146 Tree
symlistVisit(Tree sig
, set
<Tree
>& visited
)
149 if (SymListProp
.get(sig
, S
)) {
151 } else if ( visited
.count(sig
) > 0 ){
156 if (isRec(sig
, id
, body
)) {
157 Tree U
= singleton(sig
);
158 for (int i
=0; i
<len(body
); i
++) {
159 U
= setUnion(U
, symlistVisit(nth(body
,i
), visited
));
163 vector
<Tree
> subsigs
;
164 int n
= getSubSignals(sig
, subsigs
, true); // il faut visiter aussi les tables
166 for (int i
=0; i
<n
; i
++) {
167 U
= setUnion(U
, symlistVisit(subsigs
[i
], visited
));
174 Tree
symlist(Tree sig
)
177 if (!SymListProp
.get(sig
, S
)) {
179 S
= symlistVisit(sig
, visited
);
180 SymListProp
.set(sig
, S
);
182 //cerr << "SYMLIST " << *S << " OF " << ppsig(sig) << endl;