implementation module newfold // $Id$ import extract import trace import spine import rule import dnc import graph import basic import StdEnv import general /* newfold.lit - New folding function ================================== Description ----------- This module defines one function, `fullfold'. It derives a function defintion from a trace, by first searching and folding autorecursion, and searching the remainder of the trace for introduced recursion. ------------------------------------------------------------ Includes -------- > %include "dnc.lit" > %include "../src/basic.lit" > %include "../src/pfun.lit" > %include "../src/graph.lit" > %include "../src/rule.lit" > %include "../src/spine.lit" > %include "trace.lit" > %include "extract.lit" ------------------------------------------------------------ Interface --------- Exported identifiers: > %export > fullfold || Full folding function > tracer || Debugging > || extract || Fold a trace and extract new functions > || etracer || Debugging ------------------------------------------------------------ Deprecated type --------------- > tracer * ** *** > == ( (rgraph * **->(*,[**])) -> > * -> > trace * ** *** -> > (bool,([bool],[rule * **],[rgraph * **])) > ) -> > (rgraph * **->(*,[**])) -> > * -> > trace * ** *** -> > (bool,([bool],[rule * **],[rgraph * **])) */ :: FuncDef sym var :== ( [var] // Arguments of function , FuncBody sym var // Right hand side of function ) :: FuncBody sym var = MatchPattern (Rgraph sym var) // Pattern to match (FuncBody sym var) // Right hand side for matching graph (case branch) (FuncBody sym var) // Right hand side for failed match (case default) | BuildGraph (Rgraph sym var) // Right hand side to reduce to /* Implementation -------------- `Fullfold foldarea fnsymbol trace' folds the trace. It returns a resulting list of rewrite rules and rooted graphs for which new functions have to be introduced. First, an attempt is made to fold to the right hand side of the initial rewrite rule (autorecursion), or residues of the right hand side for which no instantiation was necessary. If any tip of the trace can be folded, this is done. The remaining subtraces of the trace (which is possibly the whole trace) are folded in their own right. Introduced recursion is applied if it occurs within any subtrace. */ fullfold :: (Etracer sym var pvar) ((Rgraph sym var)->(sym,[var])) sym (Trace sym var pvar) -> ([Bool],FuncDef sym var,[Rgraph sym var]) | == sym & == var & == pvar & toString sym & toString var & toString pvar & <<< var & <<< pvar fullfold trc foldarea fnsymbol trace | recursive = addlhs recurseresult = addlhs (newextract trc foldarea trace) where (recursive,recurseresult) = recurse foldarea fnsymbol trace addlhs = mapsnd3 (pair (arguments rule)) (Trace _ rule _ _ _) = trace /* `Recurse foldarea fnsymbol trace' is a pair `(recursive,recurseresult)'. `Recurseresult' is the derived function definition (strictness, rules, and new areas), obtained by folding the trace. `Recurse' tries to fold the areas in the trace to recursive function calls when at all possible. The allowed patterns for the autorecursion are derived from the top of the trace. If no recursive function call can be found, `recurseresult' is `False'. */ recurse :: ((Rgraph sym var)->(sym,[var])) sym -> (Trace sym var pvar) -> (Bool,([Bool],FuncBody sym var,[Rgraph sym var])) | == sym & == var & == pvar & toString sym & toString var & toString pvar & <<< var & <<< pvar recurse foldarea fnsymbol = f ([],[]) where f newhisthist trace | (trace--->trace) $ False = error "shouldn't happen" f newhisthist (Trace stricts rule answer history (Reduce reductroot trace)) | isEmpty pclosed && superset popen ropen = f (newhist`,newhist`) trace where rargs = arguments rule; rroot = ruleroot rule; rgraph = rulegraph rule (pclosed,popen) = graphvars rgraph rargs (_,ropen) = graphvars rgraph [rroot] newhist` = [(rroot,rgraph):newhist] (newhist,hist) = newhisthist f newhisthist (Trace stricts rule answer history (Annotate trace)) | isEmpty pclosed && superset popen ropen = f (newhist`,hist) trace where rargs = arguments rule; rroot = ruleroot rule; rgraph = rulegraph rule (pclosed,popen) = graphvars rgraph rargs (_,ropen) = graphvars rgraph [rroot] newhist` = [(rroot,rgraph):newhist] (newhist,hist) = newhisthist f newhisthist (Trace stricts rule answer history transf) = foldtips foldarea (fnsymbol,arguments rule) (removeDup newhist`,removeDup hist) (Trace stricts rule answer history transf) where rroot = ruleroot rule; rgraph = rulegraph rule newhist` = [(rroot,rgraph):newhist] (newhist,hist) = newhisthist /* `Foldtips foldarea foldcont hist trace' folds all occurrences of (rooted graphs in hist) in the tips of the trace. It returns a list of rules, which are the results of folding, and a list of areas for which functions must be introduced. If no occurrences were found, Absent is returned. */ foldtips :: ((Rgraph sym var)->(sym,[var])) (sym,[var]) -> ([(var,Graph sym var)],[(var,Graph sym var)]) (Trace sym var pvar) -> (Bool,([Bool],FuncBody sym var,[Rgraph sym var])) | == sym & == var & == pvar foldtips foldarea foldcont = ft where ft hist trace = case transf of Stop -> foldoptional exres (pair True o addstrict stricts o mapfst rule2body) (actualfold deltanodes rnfnodes foldarea (==) foldcont (snd hist) rule) where deltanodes = foldoptional [] getdeltanodes answer rnfnodes = foldoptional [ruleroot rule] (const []) answer Instantiate ipattern yestrace notrace -> ft` (ft hist yestrace) (ft hist notrace) where ft` (False,yessra) (False,nosra) = exres ft` (yesfound,(yesstricts,yesbody,yesareas)) (nofound,(nostricts,nobody,noareas)) = (True,(stricts,MatchPattern ipattern yesbody nobody,yesareas++noareas)) Reduce reductroot trace -> ft` (ft (fst hist,fst hist) trace) where ft` (False,sra) = exres ft` (found,sra) = (True,sra) Annotate trace -> ft` (ft hist trace) where ft` (False,sra) = exres ft` (found,sra) = (True,sra) where (Trace stricts rule answer _ transf) = trace exres = (False,newextract noetrc foldarea trace) rule2body rule = buildgraph (arguments rule) (ruleroot rule) (rulegraph rule) addstrict stricts (body,areas) = (stricts,body,areas) noetrc trace area = id pair x y = (x,y) /* ------------------------------------------------------------------------ `Extract foldarea trace (rules,areas)' folds the trace, creating rules which are prepended to `rules' and areas for introduced functions which are prepended to `areas'. The use of `extract' is to derive rules for parts of a trace that aren't already folded by the detection of either auto or introduced recursion. The accumulator argument is for efficiency reasons. It is probably clearer to drop it and instead apply `concat' at a higher level. Introduced recursion may be detected inside the trace. Since the trace is in practice a subtrace of another trace, introduced recursion might exist to the supertrace. This does not count, since it is not possible to fold the first occurrence of the termination history pattern which is in the supertrace. */ :: Etracer sym var pvar :== (Trace sym var pvar) (Rgraph sym var) Bool -> Bool newextract :: (Etracer sym var pvar) ((Rgraph sym var)->(sym,[var])) (Trace sym var pvar) -> ([Bool],FuncBody sym var,[Rgraph sym var]) | == sym & == var & == pvar newextract trc newname (Trace stricts rule answer history transf) | recursive = (stricts,rule2body recrule,recareas) = case transf of Reduce reductroot trace -> newextract trc newname trace Annotate trace -> newextract trc newname trace Instantiate ipattern yestrace notrace -> (stricts,MatchPattern ipattern yesbody nobody,yesareas++noareas) where (_,yesbody,yesareas) = newextract trc newname yestrace (_,nobody,noareas) = newextract trc newname notrace Stop -> (stricts,buildgraph rargs rroot stoprgraph,stopareas) where (recursive,unsafearea) = if (isreduce transf) (foldoptional (False,dummycontents) (findspinepart rule transf) answer) (False,abort "newextract: not a Reduce transformation") dummycontents = abort "newfold: newextract: accessing dummy node contents" (recrule,recareas) = splitrule newname rnfnodes deltanodes rule unsafearea (stoprgraph,stopareas) = finishfold newname rnfnodes deltanodes rroot rgraph rargs = arguments rule; rroot = ruleroot rule; rgraph = rulegraph rule rnfnodes = foldoptional (cons rroot) (const id) answer (varlist rgraph rargs) deltanodes = foldoptional [] getdeltanodes answer buildgraph :: [var] var (Graph sym var) -> FuncBody sym var | == var buildgraph args root graph = BuildGraph (mkrgraph root (compilegraph (map (pairwith (snd o varcontents graph)) newnodes))) where newnodes = closedreplnodes--patnodes closedreplnodes = fst (graphvars graph [root]) patnodes = varlist graph args isreduce (Reduce reductroot trace) = True isreduce transf = False /* `Findspinepart toprule rule spine (transformation,trace)' is a pair with a boolean determining whether some instance of the `spine', determined using `toprule', occurs in a residu of itself in `trace'. The use of `findspinepart' is to detect introduced recursion in `trace' to its root. */ findspinepart :: (Rule sym var) (Transformation sym var pvar) (Spine sym var pvar) -> (Bool,Rgraph sym var) | == sym & == var & == pvar findspinepart rule transf spine = snd (foldspine pair stop stop force stop (const stop) partial (const stop) redex stop spine) where pair node (pattern,recursion) = (pattern`,recursion`) where pattern` = if def (updategraph node cnt pattern) pattern (def,cnt) = dnc (const "in findspinepart") graph node recursion` | findpattern (pattern`,node) (spinenodes spine) node transf = (True,mkrgraph node pattern`) = recursion force _ res = res partial rule matching _ pr = (extgraph` graph rule matching pattern,recursion) where (pattern,recursion) = pr redex rule matching = (extgraph` graph rule matching emptygraph,norecursion) stop = (emptygraph,norecursion) norecursion = (False,abort "findspinepart: no part of spine found") graph = rulegraph rule extgraph` sgraph rule = extgraph sgraph rgraph (varlist rgraph (arguments rule)) where rgraph = rulegraph rule /* `Findpattern pattern rule residuroot transformation trace' bepaalt of een instance van `pattern' voorkomt in een residu van `residuroot' in de `trace'. Omwille van optimalisatie worden, met behulp van `transformation' en `rule', alleen nieuw toegevoegde nodes na een rewrite in de trace bekeken. De rest is toch niet veranderd. */ findpattern :: (Graph sym var2,var2) [var] var (Transformation sym var pvar) -> Bool | == sym & == var & == var2 & == pvar findpattern pattern thespinenodes residuroot transf | isMember residuroot thespinenodes = False // Root of residu no longer in spine - must have come to RNF. findpattern pattern thespinenodes residuroot (Reduce reductroot trace) = fp (redirect residuroot) trace where fp residuroot (Trace stricts rule answer history transf) | or [isinstance pattern (graph,node) \\ node<-varlist graph [residuroot]] = True where graph = rulegraph rule fp residuroot trace = findpattern` pattern residuroot trace redirect = adjust (last thespinenodes) reductroot id findpattern pattern thespinenodes residuroot (Instantiate ipattern yestrace notrace) = findpattern` pattern residuroot yestrace || findpattern` pattern residuroot notrace findpattern pattern thespinenodes residuroot (Annotate trace) = findpattern` pattern residuroot trace findpattern pattern thespinenodes residuroot Stop = False findpattern` :: (Graph sym var2,var2) var (Trace sym var pvar) -> Bool | == sym & == var & == var2 & == pvar findpattern` pattern residuroot (Trace stricts rule answer history transf) = findpattern pattern thespinenodes residuroot transf where thespinenodes = foldoptional [] spinenodes answer /* `Getdeltanodes spine' is the list of nodes in the spine that we don't want to introduce new functions for because they contain a delta symbol or a strict argument. */ getdeltanodes :: (Spine sym var pvar) -> [var] getdeltanodes spine = foldspine pair none (True,[]) force none (const none) partial (const none) redex none spine where pair node (forced,nodes) = if forced [node:nodes] nodes none = (False,[]) force _ nodes = (True,nodes) partial _ _ _ nodes = (False,nodes) redex _ _ = none instance <<< (FuncBody sym var) | toString sym & ==,toString var where (<<<) file (MatchPattern pat yesbody nobody) = file <<< "?Match: " /* <<< toString (rgraphroot pat) <<< " =?= " */ <<< pat <<< nl <<< "Match succes:" <<< nl <<< yesbody <<< "Match failure:" <<< nl <<< nobody (<<<) file (BuildGraph rgraph) = file <<< "Build: " <<< toString rgraph <<< nl printfuncdef :: (sym->String) (var->String) (FuncDef sym var) *File -> .File | == var printfuncdef showsym showvar funcdef file = printfuncbody showsym showvar "" body (file <<< "Arguments: " <<< showlist showvar args <<< nl) where (args,body) = funcdef printfuncbody :: (sym->String) (var->String) String (FuncBody sym var) *File -> .File | == var printfuncbody showsym showvar indent (MatchPattern pattern yesbody nobody) file0 = file3 where file3 = printfuncbody showsym showvar indent nobody (file2 <<< indent <<< "Otherwise:" <<< nl) file2 = printfuncbody showsym showvar (indent+++" ") yesbody file1 file1 = file0 <<< indent <<< "Match " <<< showvar (rgraphroot pattern) <<< " =?= " <<< showrgraph showsym showvar pattern <<< nl printfuncbody showsym showvar indent (BuildGraph replacement) file0 = file1 where file1 = file0 <<< indent <<< showrgraph showsym showvar replacement <<< nl