ref: 3e1e9621d1f19b221d59191ed55e78b171a5fe93
dir: /eval.c/
#include <u.h> #include <libc.h> #include <bio.h> #include "dat.h" #include "fns.h" Predicate *findpredicate(Predicate *, Term *); Clause *findclause(Clause *, Term *, Binding **); int equalterms(Term *, Term *); Goal *copygoals(Goal *); Builtin findbuiltin(Term *); void addchoicepoints(Clause *, Term *, Goal *, Module *); static uvlong clausenr; int evalquery(Term *query, Binding **resultbindings) { if(choicestack == nil){ /* The goal stack has the original query at the very bottom, protected by a catch frame where the ->goal field is nil. This makes it so that we can continue until we hit the protective goal, at which point we have solved everything and to get the result we can unify the original query with the one at the bottom of the stack, to get the bindings applied. */ goalstack = malloc(sizeof(Goal)); goalstack->goal = copyterm(query, nil); goalstack->module = usermodule; goalstack->catcher = nil; goalstack->next = nil; Goal *protector = malloc(sizeof(Goal)); protector->goal = nil; protector->module = usermodule; protector->catcher = mkvariable(L"catch-var"); protector->next = goalstack; goalstack = protector; /* Now add the actual goals */ goalstack = addgoals(goalstack, query, usermodule); clausenr = 2; /* Start at two since 0 is for the facts in the database, and 1 is for queries */ }else{ goto Backtrack; } while(goalstack->goal != nil){ Term *goal = goalstack->goal; Term *catcher = goalstack->catcher; Module *module = goalstack->module; goalstack = goalstack->next; if(catcher) continue; if(debug) print("Working goal: %S:%S\n", module->name, prettyprint(goal, 0, 0, 0)); Binding *bindings = nil; Clause *clause = nil; /* Try to see if the goal can be solved using a builtin first */ Builtin builtin = findbuiltin(goal); if(builtin != nil){ int success = builtin(goal, &bindings, module); if(!success) goto Backtrack; }else{ Predicate *pred = findpredicate(module->predicates, goal); if(pred == nil){ print("No predicate matches: %S:%S\n", module->name, prettyprint(goal, 0, 0, 0)); goto Backtrack; } /* Find a clause where the head unifies with the goal */ clause = findclause(pred->clauses, goal, &bindings); if(clause != nil) addchoicepoints(clause, goal, goalstack, module); else{ Backtrack: if(choicestack == nil) return 0; if(debug) print("Backtracking..\n"); Choicepoint *cp = choicestack; choicestack = cp->next; goalstack = cp->goalstack; module = cp->currentmodule; clause = cp->alternative; bindings = cp->altbindings; } } /* Apply bindings to all goals on the stack except catchframes */ Goal *g; for(g = goalstack; g != nil; g = g->next){ if(g->goal != nil && g->catcher == nil) applybinding(g->goal, bindings); } /* Add clause body as goals, with bindings applied */ if(clause != nil && clause->body != nil){ Term *subgoal = copyterm(clause->body, nil); applybinding(subgoal, bindings); goalstack = addgoals(goalstack, subgoal, module); } } goalstack = goalstack->next; unify(query, goalstack->goal, resultbindings); return 1; } Goal * addgoals(Goal *goals, Term *t, Module *module) { if(t->tag == CompoundTerm && runestrcmp(t->text, L",") == 0 && t->arity == 2){ goals = addgoals(goals, t->children->next, module); goals = addgoals(goals, t->children, module); }else{ if(t->tag == CompoundTerm && runestrcmp(t->text, L":") == 0 && t->arity == 2){ Term *moduleterm = t->children; if(moduleterm->tag == AtomTerm){ Module *m = getmodule(moduleterm->text); if(m == nil) t = existenceerror(L"module", moduleterm); else{ t = moduleterm->next; module = m; } }else t = typeerror(L"module", moduleterm); } Goal *g = malloc(sizeof(Goal)); g->goal = t; g->module = module; g->catcher = nil; g->next = goals; goals = g; } return goals; } Clause * findclause(Clause *clauses, Term *goal, Binding **bindings) { Clause *clause; for(; clauses != nil; clauses = clauses->next){ if(!clauses->public) continue; clause = copyclause(clauses, &clausenr); clausenr++; clause->next = clauses->next; if(unify(clause->head, goal, bindings)) return clause; } return nil; } Predicate * findpredicate(Predicate *preds, Term *goal) { Rune *name; int arity; name = goal->text; if(goal->tag == AtomTerm) arity = 0; else arity = goal->arity; Predicate *p; for(p = preds; p != nil; p = p->next){ if(runestrcmp(p->name, name) == 0 && p->arity == arity) return p; } return nil; } int unify(Term *a, Term *b, Binding **bindings) { Term *leftstack; Term *rightstack; Term *left; Term *right; leftstack = copyterm(a, nil); rightstack = copyterm(b, nil); while(leftstack != nil && rightstack != nil){ left = leftstack; leftstack = left->next; right = rightstack; rightstack = right->next; if(equalterms(left, right)) continue; else if(left->tag == VariableTerm || right->tag == VariableTerm){ if(left->tag != VariableTerm && right->tag == VariableTerm){ Term *tmp = left; left = right; right = tmp; } if(runestrcmp(left->text, L"_") == 0) continue; /* _ doesn't introduce a new binding */ Binding *b = malloc(sizeof(Binding)); b->name = left->text; b->nr = left->clausenr; b->value = right; b->next = *bindings; *bindings = b; Term *t; for(t = leftstack; t != nil; t = t->next) applybinding(t, b); for(t = rightstack; t != nil; t = t->next) applybinding(t, b); Binding *tmpb; for(tmpb = *bindings; tmpb != nil; tmpb = tmpb->next) applybinding(tmpb->value, b); }else if(left->tag == CompoundTerm && right->tag == CompoundTerm && left->arity == right->arity && runestrcmp(left->text, right->text) == 0){ Term *leftchild = left->children; Term *rightchild = right->children; while(leftchild != nil && rightchild != nil){ Term *t1 = copyterm(leftchild, nil); t1->next = leftstack; leftstack = t1; leftchild = leftchild->next; Term *t2 = copyterm(rightchild, nil); t2->next = rightstack; rightstack = t2; rightchild = rightchild->next; } }else{ *bindings = nil; return 0; /* failure */ } } return 1; } int equalterms(Term *a, Term *b) { /* Check that two non-compound terms are identical */ if(a->tag != b->tag) return 0; switch(a->tag){ case AtomTerm: return runestrcmp(a->text, b->text) == 0; case VariableTerm: return (runestrcmp(a->text, b->text) == 0 && a->clausenr == b->clausenr); case FloatTerm: return a->dval == b->dval; case IntegerTerm: return a->ival == b->ival; default: return 0; } } void applybinding(Term *t, Binding *bindings) { if(t->tag == VariableTerm){ Binding *b; for(b = bindings; b != nil; b = b->next){ if(runestrcmp(t->text, b->name) == 0 && t->clausenr == b->nr){ Term *next = t->next; memcpy(t, b->value, sizeof(Term)); t->next = next; return; } } }else if(t->tag == CompoundTerm){ Term *child; for(child = t->children; child != nil; child = child->next) applybinding(child, bindings); } } Goal * copygoals(Goal *goals) { if(goals != nil){ Goal *g = malloc(sizeof(Goal)); g->module = goals->module; if(goals->goal) g->goal = copyterm(goals->goal, nil); else g->goal = nil; if(goals->catcher) g->catcher = copyterm(goals->catcher, nil); else g->catcher = nil; g->next = copygoals(goals->next); return g; }else return nil; } void addchoicepoints(Clause *clause, Term *goal, Goal *goals, Module *mod){ /* Find all alternative clauses that would have matched, and create a choicepoint for them */ Choicepoint *cps = nil; Choicepoint *last = nil; Clause *alt = clause->next; while(alt != nil){ Binding *altbindings = nil; clause = findclause(alt, goal, &altbindings); if(clause){ /* Add choicepoint here */ Choicepoint *cp = malloc(sizeof(Choicepoint)); cp->goalstack = copygoals(goals); cp->next = nil; cp->alternative = clause; cp->altbindings = altbindings; cp->id = clause->clausenr; cp->currentmodule = mod; if(cps == nil){ cps = cp; last = cp; }else{ last->next = cp; last = cp; } alt = clause->next; }else alt = nil; } if(last){ last->next = choicestack; choicestack = cps; } }