scyther/src/term.c

1609 lines
32 KiB
C

/*
* Scyther : An automatic verifier for security protocols.
* Copyright (C) 2007-2013 Cas Cremers
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
/** @file term.c \brief Term related base functions.
*
* Intended to be a standalone file, however during development it turned out
* that a termlist structure was needed to define term types, so there is now a
* dependency loop with termlists.c.
*
* Until now, symbols were unique and never deleted. The same holds for basic
* terms; leaves are equal when their pointers are equal. We are looking to
* extend this to whole terms. At that point, term equality is be reduced to
* pointer comparison, which is what we want.
*/
#include <stdlib.h>
#include <stdio.h>
#include <limits.h>
#include <string.h>
#include "term.h"
#include "debug.h"
#include "error.h"
#include "ctype.h"
#include "specialterm.h"
/* public flag */
int rolelocal_variable;
char *RUNSEP;
/* external definitions */
extern int inTermlist (); // suppresses a warning, but at what cost?
/* forward declarations */
void indent (void);
/* main code */
/* Two types of terms: general, and normalized. Normalized rewrites all
tuples to (x,(y,z))..NULL form, making list traversal easy. */
//! Initialization of terms code.
void
termsInit (void)
{
rolelocal_variable = 0;
RUNSEP = "#";
return;
}
//! Cleanup of terms code.
void
termsDone (void)
{
return;
}
//! Allocate memory for a term.
/**
*@return A pointer to the new term memory, which is not yet initialised.
*/
Term
makeTerm ()
{
return (Term) malloc (sizeof (struct term));
}
//! Create a fresh encrypted term from two existing terms.
/**
* The first argument is the message,
* the second argument is the key.
*
*@return A pointer to the new term.
*/
Term
makeTermEncrypt (Term t1, Term t2)
{
Term term = makeTerm ();
term->type = ENCRYPT;
term->stype = NULL;
term->helper.fcall = false;
term->subst = NULL;
TermOp (term) = t1;
TermKey (term) = t2;
return term;
}
Term
makeTermFcall (Term t1, Term t2)
//! Create a fresh function application term from two existing terms.
/**
* The first argument is the function argument,
* the second argument is the function (name).
*
* These behave like encryptions in most cases.
*
*@return A pointer to the new term.
*/
{
Term t;
t = makeTermEncrypt (t1, t2);
t->helper.fcall = true;
return t;
}
//! Create a fresh term tuple from two existing terms.
/**
*@return A pointer to the new term.
*/
Term
makeTermTuple (Term t1, Term t2)
{
Term tt;
if (t1 == NULL)
{
if (t2 == NULL)
{
#ifdef DEBUG
debug (5, "Trying to make a tuple node with an empty term.");
#endif
return NULL;
}
else
{
return t2;
}
}
if (t2 == NULL)
{
return t1;
}
tt = makeTerm ();
tt->type = TUPLE;
tt->stype = NULL;
tt->helper.roleVar = 0;
tt->subst = NULL;
TermOp1 (tt) = t1;
TermOp2 (tt) = t2;
return tt;
}
//! Make a term of the given type with run identifier and symbol.
/**
*@return A pointer to the new term.
*\sa GLOBAL, VARIABLE, LEAF, ENCRYPT, TUPLE
*/
Term
makeTermType (const int type, const Symbol symb, const int runid)
{
Term term = makeTerm ();
term->type = type;
term->stype = NULL;
if ((type == ENCRYPT) || (type == TUPLE))
{
// Non-leaf
term->helper.fcall = false;
}
else
{
// Leaf
term->helper.roleVar = 0;
}
term->subst = NULL;
TermSymb (term) = symb;
TermRunid (term) = runid;
return term;
}
//! Unwrap any substitutions.
/**
* For speed, it is also a macro. Sometimes it will call
* deVarScan to do the actual unwinding.
*@return A term that is either not a variable, or has a NULL substitution.
*\sa deVar()
*/
Term
deVarScan (Term t)
{
while (realTermVariable (t) && t->subst != NULL)
t = t->subst;
return t;
}
//! Determine whether a term contains an unsubstituted variable as subterm.
/**
*@return True iff there is an open variable as subterm.
*/
int
hasTermVariable (Term term)
{
if (term == NULL)
return 0;
term = deVar (term);
if (realTermLeaf (term))
return realTermVariable (term);
else
{
if (realTermTuple (term))
return (hasTermVariable (TermOp1 (term))
|| hasTermVariable (TermOp2 (term)));
else
return (hasTermVariable (TermOp (term))
|| hasTermVariable (TermKey (term)));
}
}
//! Safe wrapper for isTermEqual
int
isTermEqualDebug (Term t1, Term t2)
{
return isTermEqualFn (t1, t2);
}
//!Tests whether two terms are completely identical.
/**
* This also includes
* variables. This is the recursive function.
* We assume the term is normalized, e.g. no tupling has direct
* subtupling.
*@return True iff the terms are equal.
*\sa isTermEqual()
*/
int
isTermEqualFn (Term term1, Term term2)
{
term1 = deVar (term1);
term2 = deVar (term2);
if (term1 == term2)
return 1;
if ((term1 == NULL) || (term2 == NULL))
return 0;
if (term1->type != term2->type)
{
return 0;
}
if (realTermLeaf (term1))
{
return (TermSymb (term1) == TermSymb (term2)
&& TermRunid (term1) == TermRunid (term2));
}
else
{
/* ENCRYPT or TUPLE */
if (realTermEncrypt (term1))
{
/* for optimization of encryption equality, we compare
operator 2 first (we expect it to be a smaller term)
*/
return (isTermEqualFn (TermKey (term1), TermKey (term2)) &&
isTermEqualFn (TermOp (term1), TermOp (term2)));
}
else
{
/* tuple */
return (isTermEqualFn (TermOp1 (term1), TermOp1 (term2)) &&
isTermEqualFn (TermOp2 (term1), TermOp2 (term2)));
}
}
}
//! See if a term is a subterm of another.
/**
*@param t Term to be checked for a subterm.
*@param tsub Subterm.
* Note that if t is non-null and tsub is null, it is a valid subterm.
*@return True iff tsub is a subterm of t.
*/
int
termSubTerm (Term t, Term tsub)
{
t = deVar (t);
tsub = deVar (tsub);
if (isTermEqual (t, tsub))
{
return true;
}
else
{
if (t == NULL)
{
return false;
}
else
{
if (tsub == NULL)
{
return true;
}
else
{
if (realTermLeaf (t))
{
return false;
}
else
{
if (realTermTuple (t))
return (termSubTerm (TermOp1 (t), tsub)
|| termSubTerm (TermOp2 (t), tsub));
else
return (termSubTerm (TermOp (t), tsub)
|| termSubTerm (TermKey (t), tsub));
}
}
}
}
}
//! See if a term is an interm of another.
/**
*@param t Term to be checked for a subterm.
*@param tsub interm.
*@return True iff tsub is an interm of t.
*/
int
termInTerm (Term t, Term tsub)
{
t = deVar (t);
tsub = deVar (tsub);
if (isTermEqual (t, tsub))
return true;
if (realTermLeaf (t))
return false;
if (realTermTuple (t))
return (termInTerm (TermOp1 (t), tsub) || termInTerm (TermOp2 (t), tsub));
else
return false;
}
//! Print a term to stdout.
/**
* The tuple printing only works correctly for normalized terms.
* If not, they might are displayed as "((x,y),z)". Maybe that is even
* desirable to distinguish them.
*\sa termTuplePrint()
*/
void
termPrintCustom (Term term, char *leftvar, char *rightvar, char *lefttup,
char *righttup, char *leftenc, char *rightenc,
void (*callback) (const Term t))
{
#ifdef DEBUG
if (!DEBUGL (4))
{
term = deVar (term);
}
#else
term = deVar (term);
#endif
if (term == NULL)
{
eprintf ("*");
return;
}
if (realTermLeaf (term))
{
if (term->type == VARIABLE && TermRunid (term) >= 0)
eprintf (leftvar);
symbolPrint (TermSymb (term));
if (term->type == VARIABLE && TermRunid (term) >= 0)
eprintf (rightvar);
if (TermRunid (term) >= 0)
{
if (callback == NULL)
{
eprintf ("%s%i", RUNSEP, TermRunid (term));
}
else
{
callback (term);
}
}
if (term->subst != NULL)
{
eprintf ("->");
termPrintCustom (term->subst, leftvar, rightvar, lefttup, righttup,
leftenc, rightenc, callback);
}
}
if (realTermTuple (term))
{
eprintf ("(");
termTuplePrintCustom (term, leftvar, rightvar, lefttup, righttup,
leftenc, rightenc, callback);
eprintf (")");
return;
}
if (realTermEncrypt (term))
{
if (term->helper.fcall)
{
/* function application */
termPrintCustom (TermKey (term), leftvar, rightvar, lefttup,
righttup, leftenc, rightenc, callback);
eprintf (lefttup);
termTuplePrintCustom (TermOp (term), leftvar, rightvar, lefttup,
righttup, leftenc, rightenc, callback);
eprintf (righttup);
}
else
{
/* normal encryption */
eprintf (leftenc);
termTuplePrintCustom (TermOp (term), leftvar, rightvar, lefttup,
righttup, leftenc, rightenc, callback);
eprintf (rightenc);
termPrintCustom (TermKey (term), leftvar, rightvar, lefttup,
righttup, leftenc, rightenc, callback);
}
}
}
void
termPrint (Term term)
{
termPrintCustom (term, "", "V", "(", ")", "{ ", " }", NULL);
}
//! Print an inner (tuple) term to stdout, without brackets.
/**
* The tuple printing only works correctly for normalized terms.
* If not, they might are displayed as "((x,y),z)". Maybe that is even
* desirable to distinguish them.
*/
void
termTuplePrintCustom (Term term, char *leftvar, char *rightvar, char *lefttup,
char *righttup, char *leftenc, char *rightenc,
void (*callback) (const Term t))
{
if (term == NULL)
{
eprintf ("Empty term");
return;
}
term = deVar (term);
while (realTermTuple (term))
{
// To remove any brackets, change this into termTuplePrint.
termPrintCustom (TermOp1 (term), leftvar, rightvar, lefttup, righttup,
leftenc, rightenc, callback);
eprintf (",");
term = deVar (TermOp2 (term));
}
termPrintCustom (term, leftvar, rightvar, lefttup, righttup, leftenc,
rightenc, callback);
return;
}
//! Print inner tuple
void
termTuplePrint (Term term)
{
termTuplePrintCustom (term, "", "V", "(", ")", "{ ", " }", NULL);
}
//! Make a deep copy of a term.
/**
* Leaves are not copied.
*@return If the original was a leaf, then the pointer is simply returned. Otherwise, new memory is allocated and the node is copied recursively.
*\sa termDuplicateDeep()
*/
Term
termDuplicate (const Term term)
{
Term newterm;
if (term == NULL)
return NULL;
if (realTermLeaf (term))
return term;
newterm = (Term) malloc (sizeof (struct term));
memcpy (newterm, term, sizeof (struct term));
if (realTermEncrypt (term))
{
TermOp (newterm) = termDuplicate (TermOp (term));
TermKey (newterm) = termDuplicate (TermKey (term));
}
else
{
TermOp1 (newterm) = termDuplicate (TermOp1 (term));
TermOp2 (newterm) = termDuplicate (TermOp2 (term));
}
return newterm;
}
//! Make a deep copy of a term node (one-level)
/**
* Leaves are not copied.
*@return If the original was a leaf, then the pointer is simply returned. Otherwise, new memory is allocated and the node is copied recursively.
*\sa termDuplicateDeep()
*/
Term
termNodeDuplicate (const Term term)
{
Term newterm;
if (term == NULL)
return NULL;
if (realTermLeaf (term))
return term;
newterm = (Term) malloc (sizeof (struct term));
memcpy (newterm, term, sizeof (struct term));
return newterm;
}
//! Make a true deep copy of a term.
/**
* Currently, this function is not to be used, so we can be sure leaf nodes occur only once in the system.
*@return New memory is allocated and the node is copied recursively.
*\sa termDuplicate()
*/
Term
termDuplicateDeep (const Term term)
{
Term newterm;
if (term == NULL)
return NULL;
newterm = (Term) malloc (sizeof (struct term));
memcpy (newterm, term, sizeof (struct term));
if (!realTermLeaf (term))
{
if (realTermEncrypt (term))
{
TermOp (newterm) = termDuplicateDeep (TermOp (term));
TermKey (newterm) = termDuplicateDeep (TermKey (term));
}
else
{
TermOp1 (newterm) = termDuplicateDeep (TermOp1 (term));
TermOp2 (newterm) = termDuplicateDeep (TermOp2 (term));
}
}
return newterm;
}
//! Make a copy of a term, but remove substituted variable nodes.
/**
* Remove all instantiated variables on the way down.
*\sa termDuplicate()
*/
Term
termDuplicateUV (Term term)
{
Term newterm;
term = deVar (term);
if (term == NULL)
return NULL;
if (realTermLeaf (term))
return term;
newterm = (Term) malloc (sizeof (struct term));
memcpy (newterm, term, sizeof (struct term));
if (realTermEncrypt (term))
{
TermOp (newterm) = termDuplicateUV (TermOp (term));
TermKey (newterm) = termDuplicateUV (TermKey (term));
}
else
{
TermOp1 (newterm) = termDuplicateUV (TermOp1 (term));
TermOp2 (newterm) = termDuplicateUV (TermOp2 (term));
}
return newterm;
}
//! Make a deep copy of a term, also of leaves
Term
realTermDuplicate (const Term term)
{
Term newterm;
if (term == NULL)
return NULL;
newterm = (Term) malloc (sizeof (struct term));
if (realTermLeaf (term))
{
memcpy (newterm, term, sizeof (struct term));
}
else
{
newterm->type = term->type;
if (realTermEncrypt (term))
{
TermOp (newterm) = realTermDuplicate (TermOp (term));
TermKey (newterm) = realTermDuplicate (TermKey (term));
}
else
{
TermOp1 (newterm) = realTermDuplicate (TermOp1 (term));
TermOp2 (newterm) = realTermDuplicate (TermOp2 (term));
}
}
return newterm;
}
//!Removes a term and deallocates memory.
/**
* Is meant to remove terms make with termDuplicate. Only deallocates memory
* of nodes, not of leaves.
*\sa termDuplicate(), termDuplicateUV()
*/
void
termDelete (const Term term)
{
if (term != NULL && !realTermLeaf (term))
{
if (realTermEncrypt (term))
{
termDelete (TermOp (term));
termDelete (TermKey (term));
}
else
{
termDelete (TermOp1 (term));
termDelete (TermOp2 (term));
}
free (term);
}
}
//! Normalize a term with respect to tupling.
/**
* Avoids problems with associativity by rewriting every ((x,y),z) to
* (x,(y,z)), i.e. a normal form for terms, after which equality is
* okay. No memory was allocated or deallocated, as only pointers are swapped.
*
*@return After execution, the term pointed at has been normalized. */
void
termNormalize (Term term)
{
term = deVar (term);
if (term == NULL || realTermLeaf (term))
return;
if (realTermEncrypt (term))
{
termNormalize (TermOp (term));
termNormalize (TermKey (term));
}
else
{
/* normalize left hand first,both for tupling and for
encryption */
termNormalize (TermOp1 (term));
/* check for ((x,y),z) construct */
if (realTermTuple (TermOp1 (term)))
{
/* temporarily store the old terms */
Term tx = TermOp1 (TermOp1 (term));
Term ty = TermOp2 (TermOp1 (term));
Term tz = TermOp2 (term);
/* move node */
TermOp2 (term) = TermOp1 (term);
/* construct (x,(y,z)) version */
TermOp1 (term) = tx;
TermOp1 (TermOp2 (term)) = ty;
TermOp2 (TermOp2 (term)) = tz;
}
termNormalize (TermOp2 (term));
}
}
//! Copy a term, and ensure all run identifiers are set to the new value.
/**
* Strange code. Only to be used on locals, as is stupidly replaces all run identifiers.
*@return The new term.
*\sa termDuplicate()
*/
Term
termRunid (Term term, int runid)
{
if (term == NULL)
return NULL;
if (realTermLeaf (term))
{
/* leaf */
if (TermRunid (term) == runid)
return term;
else
{
Term newt = termDuplicate (term);
TermRunid (newt) = runid;
return newt;
}
}
else
{
/* anything else, recurse */
if (realTermEncrypt (term))
{
Term t;
t = makeTermEncrypt (termRunid (TermOp (term), runid),
termRunid (TermKey (term), runid));
t->helper.fcall = term->helper.fcall;
return t;
}
else
{
return makeTermTuple (termRunid (TermOp1 (term), runid),
termRunid (TermOp2 (term), runid));
}
}
}
//! Determine tuple width of a given term.
/**
*\sa tupleProject()
*/
int
tupleCount (Term tt)
{
if (tt == NULL)
{
return 0;
}
else
{
tt = deVar (tt);
if (!realTermTuple (tt))
{
return 1;
}
else
{
return (tupleCount (TermOp1 (tt)) + tupleCount (TermOp2 (tt)));
}
}
}
//! Yield the projection Pi(n) of a term.
/**
*@param tt Term
*@param n The index in the tuple [0..tupleCount-1]
*@return Returns either a pointer to a term, or NULL if the index is out of range.
*\sa tupleCount()
*/
Term
tupleProject (Term tt, int n)
{
if (tt == NULL)
{
return NULL;
}
tt = deVar (tt);
if (!realTermTuple (tt))
{
if (n > 0)
{
/* no tuple, adressing error */
return NULL;
}
else
{
/* no tuple */
return tt;
}
}
else
{
/* there is a tuple to traverse */
int left = tupleCount (TermOp1 (tt));
if (n >= left)
{
/* it's in the right hand side */
return tupleProject (TermOp2 (tt), n - left);
}
else
{
/* left hand side */
return tupleProject (TermOp1 (tt), n);
}
}
}
//! Determine size of term.
/**
* Determines the size of a term according to some heuristic.
* Currently, the encryption operator is weighed as well.
*@return Returns a nonnegative integer.
*\sa termDistance()
*/
int
termSize (Term t)
{
if (t == NULL)
{
return 0;
}
t = deVar (t);
if (realTermLeaf (t))
{
return 1;
}
else
{
if (realTermEncrypt (t))
{
return 1 + termSize (TermOp (t)) + termSize (TermKey (t));
}
else
{
return termSize (TermOp1 (t)) + termSize (TermOp2 (t));
}
}
}
//! Determine distance between two terms.
/**
*@return A float value between 0, completely dissimilar, and 1, equal.
*\sa termSize()
*/
float
termDistance (Term t1, Term t2)
{
int t1s;
int t2s;
/* First the special cases: no equal subterms, completely equal */
if (isTermEqual (t1, t2))
return 1;
t1 = deVar (t1);
t2 = deVar (t2);
t1s = termSize (t1);
t2s = termSize (t2);
if (t1 == NULL || t2 == NULL)
{
return 0;
}
if (t1->type != t2->type)
{
/* unequal type, maybe one is a subterm of the other? */
if (t1s > t2s && termSubTerm (t1, t2))
{
return (float) t2s / t1s;
}
if (t2s > t1s && termSubTerm (t2, t1))
{
return (float) t1s / t2s;
}
return 0;
}
else
{
/* equal types */
if (isTermLeaf (t1))
{
/* we had established before that they are not equal */
return 0;
}
else
{
/* non-leaf recurse */
if (isTermEncrypt (t1))
{
/* encryption */
return (termDistance (TermOp (t1), TermOp (t2)) +
termDistance (TermKey (t1), TermKey (t2))) / 2;
}
else
{
return (termDistance (TermOp1 (t1), TermOp1 (t2)) +
termDistance (TermOp2 (t1), TermOp2 (t2))) / 2;
}
}
}
}
/**
* Enforce a (arbitrary) ordering on terms
* <0 means a<b, 0 means a=b, >0 means a>b.
*/
int
termOrder (Term t1, Term t2)
{
t1 = deVar (t1);
t2 = deVar (t2);
if (isTermEqual (t1, t2))
{
/* equal terms */
return 0;
}
/* differ */
if (t1->type != t2->type)
{
/* different types, so ordering on types first */
if (t1->type < t2->type)
return -1;
else
return 1;
}
/* same type
* distinguish cases
*/
if (realTermLeaf (t1))
{
/* compare names */
int comp;
comp = strcmp (TermSymb (t1)->text, TermSymb (t2)->text);
if (comp != 0)
{
/* names differ */
return comp;
}
else
{
/* equal names, compare run identifiers */
if (TermRunid (t1) == TermRunid (t2))
{
error
("termOrder: two terms seem to be identical although local precondition says they aren't.");
}
else
{
if (TermRunid (t1) < TermRunid (t2))
return -1;
else
return 1;
}
}
}
else
{
/* non-leaf */
int compL, compR;
if (isTermEncrypt (t1))
{
compL = termOrder (TermOp (t1), TermOp (t2));
compR = termOrder (TermKey (t1), TermKey (t2));
}
else
{
compL = termOrder (TermOp1 (t1), TermOp1 (t2));
compR = termOrder (TermOp2 (t1), TermOp2 (t2));
}
if (compL != 0)
return compL;
else
return compR;
}
// @TODO Should be considered an error
return 0;
}
//! Generic term iteration
int
term_iterate (const Term term, int (*leaf) (Term t), int (*nodel) (Term t),
int (*nodem) (Term t), int (*noder) (Term t))
{
if (term != NULL)
{
if (realTermLeaf (term))
{
// Leaf
if (leaf != NULL)
{
return leaf (term);
}
}
else
{
int flag;
flag = 1;
if (nodel != NULL)
flag = flag && nodel (term);
// Left part
if (realTermTuple (term))
flag = flag
&& (term_iterate (TermOp1 (term), leaf, nodel, nodem, noder));
else
flag = flag
&& (term_iterate (TermOp (term), leaf, nodel, nodem, noder));
if (nodem != NULL)
flag = flag && nodem (term);
// Right part
if (realTermTuple (term))
flag = flag
&& (term_iterate (TermOp2 (term), leaf, nodel, nodem, noder));
else
flag = flag
&& (term_iterate (TermKey (term), leaf, nodel, nodem, noder));
if (noder != NULL)
flag = flag && noder (term);
return flag;
}
}
return 1;
}
//! Generic term iteration with state
int
term_iterate_state_deVar (Term term, int (*leaf) (),
int (*nodel) (),
int (*nodem) (), int (*noder) (), void (*state))
{
term = deVar (term);
if (term != NULL)
{
if (realTermLeaf (term))
{
// Leaf
if (leaf != NULL)
{
return leaf (term, state);
}
else
{
return true;
}
}
else
{
int flag;
flag = true;
if (nodel != NULL)
flag = flag && nodel (term, state);
// Left part
if (realTermTuple (term))
flag = flag
&&
(term_iterate_state_deVar
(TermOp1 (term), leaf, nodel, nodem, noder, state));
else
flag = flag
&&
(term_iterate_state_deVar
(TermOp (term), leaf, nodel, nodem, noder, state));
// Center
if (nodem != NULL)
flag = flag && nodem (term, state);
// right part
if (realTermTuple (term))
flag = flag
&&
(term_iterate_state_deVar
(TermOp2 (term), leaf, nodel, nodem, noder, state));
else
flag = flag
&&
(term_iterate_state_deVar
(TermKey (term), leaf, nodel, nodem, noder, state));
if (noder != NULL)
flag = flag && noder (term, state);
return flag;
}
}
return true;
}
//! Iterate over the leaves in a term, stateful
/**
* Note that this function iterates over real leaves; thus closed variables can occur as
* well. It is up to func to decide wether or not to recurse.
*/
int
term_iterate_state_leaves (const Term term, int (*func) (), void (*state))
{
if (term != NULL)
{
if (realTermLeaf (term))
{
if (!func (term, state))
return 0;
}
else
{
if (realTermTuple (term))
return (term_iterate_state_leaves (TermOp1 (term), func, state)
&& term_iterate_state_leaves (TermOp2 (term), func,
state));
else
return (term_iterate_state_leaves (TermOp (term), func, state)
&& term_iterate_state_leaves (TermKey (term), func,
state));
}
}
return 1;
}
//! Iterate over the leaves in a term
/**
* Note that this function iterates over real leaves; thus closed variables can occur as
* well. It is up to func to decide wether or not to recurse.
*/
int
term_iterate_state_open_leaves (const Term term, int (*func) (), void *state)
{
if (term != NULL)
{
if (realTermLeaf (term))
{
if (substVar (term))
{
return term_iterate_state_open_leaves (term->subst, func,
state);
}
else
{
return func (term, state);
}
}
else
{
if (realTermTuple (term))
return (term_iterate_state_open_leaves
(TermOp1 (term), func, state)
&& term_iterate_state_open_leaves (TermOp2 (term), func,
state));
else
return (term_iterate_state_open_leaves
(TermOp (term), func, state)
&& term_iterate_state_open_leaves (TermKey (term), func,
state));
}
}
return 1;
}
//! Turn all rolelocals into variables
void
term_rolelocals_are_variables ()
{
rolelocal_variable = 1;
}
//! Helper for counting encryption level of a term
int
iter_maxencrypt (Term baseterm, Term t)
{
if (isTicketTerm (t))
{
return 0;
}
t = deVar (t);
if (t == NULL)
{
#ifdef DEBUG
if (DEBUGL (2))
{
eprintf ("Warning: Term encryption level finds a NULL for term ");
termPrint (baseterm);
eprintf ("\n");
}
#endif
return 0;
}
if (realTermLeaf (t))
{
return 0;
}
else
{
int l, r;
if (realTermTuple (t))
{
l = iter_maxencrypt (baseterm, TermOp1 (t));
r = iter_maxencrypt (baseterm, TermOp2 (t));
}
else
{
// encrypt
l = 1 + iter_maxencrypt (baseterm, TermOp (t));
r = iter_maxencrypt (baseterm, TermKey (t));
}
if (l > r)
return l;
else
return r;
}
}
//! Count the encryption level of a term
/**
* Note that this stops at any variable that is of ticket type.
*/
int
term_encryption_level (const Term term)
{
return iter_maxencrypt (term, term);
}
struct ti_data
{
int vars;
int structure;
};
void
tcl_iterate (struct ti_data *p_data, Term t)
{
t = deVar (t);
(p_data->structure)++;
if (realTermLeaf (t))
{
if (realTermVariable (t))
(p_data->vars)++;
}
else
{
if (realTermTuple (t))
{
tcl_iterate (p_data, TermOp1 (t));
tcl_iterate (p_data, TermOp2 (t));
}
else
{
tcl_iterate (p_data, TermOp (t));
tcl_iterate (p_data, TermKey (t));
}
}
}
//! Determine 'constrained factor' of a term
/**
* Actually this is (number of vars/structure).
* Thus, 0 means very constrained, no variables.
* Everything else has higher float, but always <=1. In fact, only a single variable has a level 1.
*/
float
term_constrain_level (const Term term)
{
struct ti_data data;
if (term == NULL)
error ("Cannot determine constrain level of empty term.");
data.vars = 0;
data.structure = 0;
tcl_iterate (&data, term);
return ((float) data.vars / (float) data.structure);
}
void
scan_levels (int level, Term t)
{
#ifdef DEBUG
if (DEBUGL (5))
{
int c;
c = 0;
while (c < level)
{
eprintf (" ");
c++;
}
eprintf ("Scanning keylevel %i for term ", level);
termPrint (t);
eprintf ("\n");
}
#endif
if (realTermLeaf (t))
{
Symbol sym;
// So, it occurs at 'level' as key. If that is less than known, store.
sym = TermSymb (t);
if (level < sym->keylevel)
{
// New minimum level
sym->keylevel = level;
}
}
else
{
if (realTermTuple (t))
{
scan_levels (level, TermOp1 (t));
scan_levels (level, TermOp2 (t));
}
else
{
scan_levels (level, TermOp (t));
scan_levels ((level + 1), TermKey (t));
}
}
}
//! Adjust the keylevels of the symbols in a term.
/**
* This is used to scan the roles. For each symbol, this function does the bookkeeping of the keylevels at which they occur.
*/
void
term_set_keylevels (const Term term)
{
scan_levels (0, term);
}
void
termFromTo (Term t1, Term t2)
{
t1 = deVar (t1);
t2 = deVar (t2);
eprintf (" [");
termPrint (t1);
eprintf ("]->[");
termPrint (t2);
eprintf ("] ");
}
//! Print the term diff of two terms
/**
* This is not correct yet. We need to add function application and correct tuple handing.
*/
void
termPrintDiff (Term t1, Term t2)
{
t1 = deVar (t1);
t2 = deVar (t2);
if (isTermEqual (t1, t2))
{
// Equal, simply print
termPrint (t1);
}
else
{
if (t1->type != t2->type)
{
// Different types
termFromTo (t1, t2);
}
else
{
// Equal types, but not the same
// If component type, but both components different, we simply do moveto at the node level.
if (realTermLeaf (t1))
{
// Different constants
termFromTo (t1, t2);
}
else
{
if (realTermEncrypt (t1))
{
// Encryption
if (isTermEqual (TermOp (t1), TermOp (t2))
|| isTermEqual (TermKey (t1), TermKey (t2)))
{
eprintf ("{");
termPrintDiff (TermOp (t1), TermOp (t2));
eprintf ("}");
termPrintDiff (TermKey (t1), TermKey (t2));
}
else
{
termFromTo (t1, t2);
}
}
else
{
// Tupling
if (isTermEqual (TermOp1 (t1), TermOp1 (t2))
|| isTermEqual (TermOp2 (t1), TermOp2 (t2)))
{
eprintf ("(");
termPrintDiff (TermOp1 (t1), TermOp1 (t2));
eprintf (")");
termPrintDiff (TermOp2 (t1), TermOp2 (t2));
}
else
{
termFromTo (t1, t2);
}
}
}
}
}
}
//! Test two leaf terms for abstract equality (abstracting from the run identifiers)
int
isLeafNameEqual (Term t1, Term t2)
{
return (TermSymb (t1) == TermSymb (t2));
}
//! Generate a fresh term, that does not occur yet, prefixed with the string of the given term.
Term
freshTermPrefix (Term prefixterm)
{
Symbol prefixsymbol;
Symbol freshsymbol;
prefixsymbol = NULL;
if (prefixterm != NULL && realTermLeaf (prefixterm))
{
prefixsymbol = TermSymb (prefixterm);
}
freshsymbol = symbolNextFree (prefixsymbol);
return makeTermType (GLOBAL, freshsymbol, -1);
}
//! Generate a term from an int, prefixed with the string of the given term.
Term
intTermPrefix (const int n, Term prefixterm)
{
Symbol prefixsymbol;
Symbol freshsymbol;
prefixsymbol = NULL;
if (prefixterm != NULL && realTermLeaf (prefixterm))
{
prefixsymbol = TermSymb (prefixterm);
}
freshsymbol = symbolFromInt (n, prefixsymbol);
return makeTermType (GLOBAL, freshsymbol, -1);
}
//! Determine whether a term is a functor
int
isTermFunctionName (Term t)
{
t = deVar (t);
if (t != NULL && isTermLeaf (t) && t->stype != NULL
&& inTermlist (t->stype, TERM_Function))
return 1;
return 0;
}
//! Determine whether a term is a function application. Returns the function term.
Term
getTermFunction (Term t)
{
t = deVar (t);
if (realTermEncrypt (t))
{
if (t->helper.fcall)
{
return TermKey (t);
}
}
return NULL;
}
//! Return hidelevel for a single term within another
unsigned int
termHidelevel (const Term tsmall, Term tbig)
{
tbig = deVar (tbig);
if (isTermEqual (tsmall, tbig))
{
// It's simply here: not hidden at any level
return 0;
}
else
{
if (realTermLeaf (tbig))
{
// Not here: infinitely hidden
return INT_MAX;
}
else
{
// Nested term
unsigned int t1, t2;
if (realTermTuple (tbig))
{
// Tupling
t1 = termHidelevel (tsmall, TermOp1 (tbig));
t2 = termHidelevel (tsmall, TermOp2 (tbig));
}
else
{
// Encryption
t1 = termHidelevel (tsmall, TermOp (tbig));
t2 = termHidelevel (tsmall, TermKey (tbig));
if (t2 < INT_MAX)
t2++;
}
// Return minimum
if (t1 < t2)
{
return t1;
}
else
{
return t2;
}
}
}
}
//! Show a substitution of t
void
termSubstPrint (Term t)
{
if (realTermVariable (t))
{
Term tbuf;
tbuf = t->subst;
t->subst = NULL;
termPrint (t);
t->subst = tbuf;
eprintf (":=");
termSubstPrint (t->subst);
}
else
{
termPrint (t);
}
}
typedef int (*CallBack) ();
struct ito_contain
{
int myrun;
CallBack callback;
void *ito_state;
};
int
testOther (Term t, struct ito_contain *state)
{
int run;
run = TermRunid (t);
if (run >= 0 && run != state->myrun)
{
return state->callback (t, state->ito_state);
}
return true;
}
// Iterate over subterm constants of other runs in a term
// Callback should return true to progress. This is reported in the final thing.
int
iterateTermOther (const int myrun, Term t, int (*callback) (),
void *ito_state)
{
struct ito_contain State;
State.myrun = myrun;
State.callback = callback;
State.ito_state = ito_state;
return term_iterate_state_deVar (t, testOther, NULL, NULL, NULL, &State);
}