path: root/contrib/cc/ccalgo.ml

(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(* $Id$ *)

(* This file implements the basic congruence-closure algorithm by *)
(* Downey,Sethi and Tarjan. *)

open Util
open Pp
open Goptions
open Names
open Term

let init_size=5

let cc_verbose=ref false 

let debug msg (stdpp:std_ppcmds) = 
  if !cc_verbose then msg stdpp

let _=
  let gdopt=
    { optsync=true;
      optname="Congruence Verbose";
      optkey=SecondaryTable("Congruence","Verbose"); 
      optread=(fun ()-> !cc_verbose); 
      optwrite=(fun b -> cc_verbose := b)}  
  in
    declare_bool_option gdopt

(* Signature table *)

module ST=struct
  
  (* l: sign -> term r: term -> sign *)
	
  type t = {toterm:(int*int,int) Hashtbl.t;
	    tosign:(int,int*int) Hashtbl.t}
	
  let empty ()=
    {toterm=Hashtbl.create init_size;
     tosign=Hashtbl.create init_size}
      
  let enter t sign st=
    if Hashtbl.mem st.toterm sign then 
	anomaly "enter: signature already entered"
    else 
	Hashtbl.replace st.toterm sign t;
	Hashtbl.replace st.tosign t sign
	  
  let query sign st=Hashtbl.find st.toterm sign
	  
  let delete st t=
    try let sign=Hashtbl.find st.tosign t in
	Hashtbl.remove st.toterm sign;
	Hashtbl.remove st.tosign t
    with
	Not_found -> ()

  let rec delete_set st s = Intset.iter (delete st) s
	  
end

type pa_constructor=
    { cnode : int;
      arity : int;
      args  : int list}

module PacMap=Map.Make(struct 
			 type t=pa_constructor 
			 let compare=Pervasives.compare end) 

type cinfo=
    {ci_constr: constructor; (* inductive type *)
     ci_arity: int;     (* # args *)
     ci_nhyps: int}     (* # projectable args *)

type term=
    Symb of constr
  | Eps
  | Appli of term*term
  | Constructor of cinfo (* constructor arity + nhyps *)

type rule=
    Congruence
  | Axiom of identifier * bool 
  | Injection of int * pa_constructor * int * pa_constructor * int

type from=
    Goal
  | Hyp of identifier
  | HeqG of identifier
  | HeqnH of identifier * identifier

type 'a eq = {lhs:int;rhs:int;rule:'a}

type equality = rule eq

type disequality = from eq

let swap eq : equality =
  let swap_rule=match eq.rule with
      Congruence -> Congruence
    | Injection (i,pi,j,pj,k) -> Injection (j,pj,i,pi,k)
    | Axiom (id,reversed) -> Axiom (id,not reversed)
  in {lhs=eq.rhs;rhs=eq.lhs;rule=swap_rule}
    
type inductive_status =
    Unknown
  | Partial of pa_constructor
  | Partial_applied
  | Total of (int * pa_constructor)

type representative=
    {mutable nfathers:int;
     mutable lfathers:Intset.t;
     mutable fathers:Intset.t;
     mutable inductive_status: inductive_status;
     mutable constructors: int PacMap.t} (*pac -> term = app(constr,t) *)

type cl = Rep of representative| Eqto of int*equality
  
type vertex = Leaf| Node of (int*int) 

type node = 
    {mutable clas:cl;
     mutable cpath: int; 
     vertex:vertex;
     term:term}
    
type forest=
    {mutable max_size:int;
     mutable size:int;
     mutable map: node array;
     axioms: (identifier,term*term) Hashtbl.t;
     mutable epsilons: pa_constructor list;
     syms:(term,int) Hashtbl.t}

type state = 
    {uf: forest;
     sigtable:ST.t;
     mutable terms: Intset.t; 
     combine: equality Queue.t; 
     marks: (int * pa_constructor) Queue.t;
     mutable diseq: disequality list;
     mutable pa_classes: Intset.t}

let dummy_node =
  {clas=Eqto(min_int,{lhs=min_int;rhs=min_int;rule=Congruence});
   cpath=min_int;
   vertex=Leaf;
   term=Symb (mkRel min_int)}

let empty ():state =
  {uf=
     {max_size=init_size;
      size=0;
      map=Array.create init_size dummy_node;
      epsilons=[];
      axioms=Hashtbl.create init_size;
      syms=Hashtbl.create init_size};
  terms=Intset.empty;
  combine=Queue.create ();
  marks=Queue.create ();
  sigtable=ST.empty ();
  diseq=[];
  pa_classes=Intset.empty}

let forest state = state.uf 
       
let compress_path uf i j = uf.map.(j).cpath<-i
			     
let rec find_aux uf visited i=  
  let j = uf.map.(i).cpath in 
    if j<0 then let _ = List.iter (compress_path uf i) visited in i else
      find_aux uf (i::visited) j
	
let find uf i= find_aux uf [] i
		 
let get_representative uf i=
  match uf.map.(i).clas with
      Rep r -> r
    | _ -> anomaly "get_representative: not a representative"

let find_pac uf i pac =
  PacMap.find pac (get_representative uf i).constructors

let get_constructor_info uf i=
  match uf.map.(i).term with
      Constructor cinfo->cinfo
    | _ -> anomaly "get_constructor: not a constructor"
	
let size uf i=
  (get_representative uf i).nfathers

let axioms uf = uf.axioms

let epsilons uf = uf.epsilons

let add_lfather uf i t=
  let r=get_representative uf i in
    r.nfathers<-r.nfathers+1;
    r.lfathers<-Intset.add t r.lfathers;
    r.fathers <-Intset.add t r.fathers

let add_rfather uf i t=
  let r=get_representative uf i in
    r.nfathers<-r.nfathers+1;
    r.fathers <-Intset.add t r.fathers

exception Discriminable of int * pa_constructor * int * pa_constructor 

let append_pac t p =
  {p with arity=pred p.arity;args=t::p.args} 

let tail_pac p=
  {p with arity=succ p.arity;args=List.tl p.args}
    
let add_pac rep pac t =
  if not (PacMap.mem pac rep.constructors) then
    rep.constructors<-PacMap.add pac t rep.constructors

let term uf i=uf.map.(i).term
		
let subterms uf i=
  match uf.map.(i).vertex with
      Node(j,k) -> (j,k)
    | _ -> anomaly "subterms: not a node"
	
let signature uf i=
  let j,k=subterms uf i in (find uf j,find uf k)
			     
let next uf=
  let size=uf.size in
  let nsize= succ size in
    if nsize=uf.max_size then
      let newmax=uf.max_size * 3 / 2 + 1 in
      let newmap=Array.create newmax dummy_node in
	begin
	  uf.max_size<-newmax;
	  Array.blit uf.map 0 newmap 0 size;
	  uf.map<-newmap
	end 
    else ();
    uf.size<-nsize; 
    size
	
let new_representative ()=
  {nfathers=0;
   lfathers=Intset.empty;
   fathers=Intset.empty;
   inductive_status=Unknown;
   constructors=PacMap.empty}
    
let rec add_term state t= 
  let uf=state.uf in
    try Hashtbl.find uf.syms t with 
	Not_found ->
	  let b=next uf in
	  let new_node=
	    match t with
		Symb _ | Eps -> 
		  {clas= Rep (new_representative ());
		   cpath= -1;
		   vertex= Leaf;
		   term= t}
	      | Appli (t1,t2) -> 
		  let i1=add_term state t1 and i2=add_term state t2 in
		    add_lfather uf (find uf i1) b;
		    add_rfather uf (find uf i2) b;
		    state.terms<-Intset.add b state.terms;
		    {clas= Rep (new_representative ());
		     cpath= -1;
		     vertex= Node(i1,i2);
		     term= t}
	      | Constructor cinfo ->
		  let pac =
		    {cnode= b;
		     arity= cinfo.ci_arity;
		     args=[]} in
		    Queue.add (b,pac) state.marks;
		    {clas=Rep (new_representative ());
		     cpath= -1;
		     vertex=Leaf;
		     term=t}
	  in
	    uf.map.(b)<-new_node;
	    Hashtbl.add uf.syms t b;
	    b

let add_equality state id s t=
  let i = add_term state s in
  let j = add_term state t in
    Queue.add {lhs=i;rhs=j;rule=Axiom(id,false)} state.combine;
    Hashtbl.add state.uf.axioms id (s,t)

let add_disequality state from s t =
  let i = add_term state s in
  let j = add_term state t in
    state.diseq<-{lhs=i;rhs=j;rule=from}::state.diseq

let link uf i j eq = (* links i -> j *)
  let node=uf.map.(i) in 
    node.clas<-Eqto (j,eq);
    node.cpath<-j
	
let rec down_path uf i l=
  match uf.map.(i).clas with
      Eqto(j,t)->down_path uf j (((i,j),t)::l)
    | Rep _ ->l
	
let rec min_path=function
    ([],l2)->([],l2)
  | (l1,[])->(l1,[])
  | (((c1,t1)::q1),((c2,t2)::q2)) when c1=c2 -> min_path (q1,q2) 
  | cpl -> cpl
      
let join_path uf i j=
  assert (find uf i=find uf j);
  min_path (down_path uf i [],down_path uf j [])

let union state i1 i2 eq=
  debug msgnl (str "Linking " ++ int i1 ++ str " and " ++ int i2 ++ str ".");
  let r1= get_representative state.uf i1 
  and r2= get_representative state.uf i2 in
    link state.uf i1 i2 eq;
    let f= Intset.union r1.fathers r2.fathers in
      r2.nfathers<-Intset.cardinal f;
      r2.fathers<-f;
      r2.lfathers<-Intset.union r1.lfathers r2.lfathers;
      ST.delete_set state.sigtable r1.fathers;
      state.terms<-Intset.union state.terms r1.fathers;       
      PacMap.iter (fun pac b -> Queue.add (b,pac) state.marks) r1.constructors;
      match r1.inductive_status,r2.inductive_status with 
	  Unknown,_ -> ()
	| Partial pac,Unknown -> 
	    r2.inductive_status<-Partial pac;
	    state.pa_classes<-Intset.remove i1 state.pa_classes;
	    state.pa_classes<-Intset.add i2 state.pa_classes
	| Partial _ ,(Partial _ |Partial_applied) -> 
	    state.pa_classes<-Intset.remove i1 state.pa_classes
	| Partial_applied,Unknown -> 
	    r2.inductive_status<-Partial_applied	      
	| Partial_applied,Partial _ -> 
	    state.pa_classes<-Intset.remove i2 state.pa_classes;
	    r2.inductive_status<-Partial_applied
	| Total cpl,Unknown -> r2.inductive_status<-Total cpl;
	| Total cpl,Total _ -> Queue.add cpl state.marks    
	| _,_ -> () 
            
let merge eq state = (* merge and no-merge *)
  debug msgnl 
    (str "Merging " ++ int eq.lhs ++ str " and " ++ int eq.rhs ++ str ".");
  let uf=state.uf in
  let i=find uf eq.lhs 
  and j=find uf eq.rhs in
    if i<>j then 
      if (size uf i)<(size uf j) then
	union state i j eq
      else
	union state j i (swap eq)

let update t state = (* update 1 and 2 *)
  debug msgnl 
    (str "Updating term " ++ int t ++ str ".");
  let (i,j) as sign = signature state.uf t in
  let (u,v) = subterms state.uf t in
  let rep = get_representative state.uf i in
    begin
      match rep.inductive_status with 
	  Partial _ ->
	    rep.inductive_status <- Partial_applied;
	    state.pa_classes <- Intset.remove i state.pa_classes
	| _ -> ()
    end;
    PacMap.iter 
      (fun pac _ -> Queue.add (t,append_pac v pac) state.marks) 
      rep.constructors; 
    try 
      let s = ST.query sign state.sigtable in 
	Queue.add {lhs=t;rhs=s;rule=Congruence} state.combine
    with 
	Not_found -> ST.enter t sign state.sigtable

let process_mark t pac state =
  debug msgnl 
    (str "Processing mark for term " ++ int t ++ str ".");
  let i=find state.uf t in
  let rep=get_representative state.uf i in
    match rep.inductive_status with
	Total (s,opac) ->
	  if pac.cnode <> opac.cnode then (* Conflict *) 
	    raise (Discriminable (s,opac,t,pac)) 
	  else (* Match *)
	    let cinfo = get_constructor_info state.uf pac.cnode in
	    let rec f n oargs args=
	      if n > 0 then 
		match (oargs,args) with
		    s1::q1,s2::q2->
		      Queue.add 
			{lhs=s1;rhs=s2;rule=Injection(s,opac,t,pac,n)}
			state.combine;
		      f (n-1) q1 q2 
		  | _-> anomaly 
		      "add_pacs : weird error in injection subterms merge" 
	    in f cinfo.ci_nhyps opac.args pac.args
      | Partial_applied | Partial _ ->
	  add_pac rep pac t;
	  state.terms<-Intset.union rep.lfathers state.terms
      | Unknown ->
	  if pac.arity = 0 then
	    rep.inductive_status <- Total (t,pac)
	  else
	    begin
	      add_pac rep pac t;
	      state.terms<-Intset.union rep.lfathers state.terms;
	      rep.inductive_status <- Partial pac;
	      state.pa_classes<- Intset.add i state.pa_classes
	    end

type explanation =
    Discrimination of (int*pa_constructor*int*pa_constructor)
  | Contradiction of disequality
  | Incomplete

let check_disequalities state =
  let uf=state.uf in
  let rec check_aux = function
      dis::q -> 
	debug msg 
	(str "Checking if " ++ int dis.lhs ++ str " = " ++ 
	 int dis.rhs ++ str " ... ");  
	if find uf dis.lhs=find uf dis.rhs then 
	  begin debug msgnl (str "Yes");Some dis end 
	else
	  begin debug msgnl (str "No");check_aux q end
    | [] -> None 
  in
    check_aux state.diseq

let one_step state =
    try
      let eq = Queue.take state.combine in
	merge eq state
    with Queue.Empty -> 
      try 
	let (t,m) = Queue.take state.marks in
	  process_mark t m state
      with Queue.Empty ->
	  let t = Intset.choose state.terms in
	    state.terms<-Intset.remove t state.terms;
	    update t state

let complete_one_class state i=
  match (get_representative state.uf i).inductive_status with
      Partial pac ->
	let rec app t n = 
	  if n<=0 then t else
	    app (Appli(t,Eps)) (n-1) in
	  state.uf.epsilons <- pac :: state.uf.epsilons; 
	  ignore (add_term state (app (term state.uf i) pac.arity))
    | _ -> anomaly "wrong incomplete class" 

let complete state =
  Intset.iter (complete_one_class state) state.pa_classes

let rec execute first_run state =
  debug msgnl (str "Executing ... ");
  try
    while true do 
      one_step state
    done;
    anomaly "keep out of here" 
  with 
      Discriminable(s,spac,t,tpac) -> 
	Some
	begin
	  if first_run then 
	    Discrimination (s,spac,t,tpac)
	  else
	    Incomplete
	end
    | Not_found ->
	match check_disequalities state with
	    None -> 
	      if not(Intset.is_empty state.pa_classes) then
		begin 
		  debug msgnl 
		    (str "First run was incomplete, completing ... ");
		  complete state;
		  execute false state
		end
	      else None
	  | Some dis -> Some
	      begin
		if first_run then 
		  Contradiction dis
		else
		  Incomplete
	      end