scyther/src/arachne.c

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/**
*
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*@file arachne.c
*
* Introduces a method for proofs akin to the Athena modelchecker
* http://www.ece.cmu.edu/~dawnsong/athena/
*
*/
#include <limits.h>
#ifdef DEBUG
#include <malloc.h>
#endif
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#include "term.h"
#include "termlist.h"
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#include "role.h"
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#include "system.h"
#include "knowledge.h"
#include "compiler.h"
#include "states.h"
#include "mgu.h"
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#include "arachne.h"
#include "memory.h"
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#include "error.h"
#include "claim.h"
#include "debug.h"
#include "binding.h"
#include "warshall.h"
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extern Term CLAIM_Secret;
extern Term CLAIM_Nisynch;
extern Term CLAIM_Niagree;
extern Term TERM_Agent;
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extern Term TERM_Hidden;
extern Term TERM_Function;
extern int *graph;
extern int nodes;
extern int graph_uordblks;
static System sys;
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static Claimlist current_claim;
static int attack_length;
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Protocol INTRUDER; // Pointers, to be set by the Init
Role I_M; // Same here.
Role I_F;
Role I_T;
Role I_V;
Role I_R;
Role I_E;
Role I_D;
Role I_RRS;
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static int indentDepth;
static int proofDepth;
static int max_encryption_level;
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static int num_regular_runs;
static int num_intruder_runs;
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struct goalstruct
{
int run;
int index;
Roledef rd;
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};
typedef struct goalstruct Goal;
/**
* Forward declarations
*/
int iterate ();
void printSemiState ();
/**
* Program code
*/
//! Init Arachne engine
void
arachneInit (const System mysys)
{
Term GVT;
Roledef rd = NULL;
Termlist tl, know0;
void add_event (int event, Term message)
{
rd = roledefAdd (rd, event, NULL, NULL, NULL, message, NULL);
}
Role add_role (const char *rolenamestring)
{
Role r;
Term rolename;
rolename = makeGlobalConstant (rolenamestring);
r = roleCreate (rolename);
r->roledef = rd;
rd = NULL;
r->next = INTRUDER->roles;
INTRUDER->roles = r;
// compute_role_variables (sys, INTRUDER, r);
return r;
}
sys = mysys; // make sys available for this module as a global
/**
* Very important: turn role terms that are local to a run, into variables.
*/
term_rolelocals_are_variables ();
/*
* Add intruder protocol roles
*/
INTRUDER = protocolCreate (makeGlobalConstant (" INTRUDER "));
add_event (SEND, NULL);
I_M = add_role ("I_M: Atomic message");
add_event (READ, NULL);
add_event (READ, NULL);
add_event (SEND, NULL);
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I_RRS = add_role ("I_E: Encrypt");
return;
}
//! Close Arachne engine
void
arachneDone ()
{
return;
}
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//------------------------------------------------------------------------
// Detail
//------------------------------------------------------------------------
/*
* runs[rid].step is now the number of 'valid' events within the run, but we
* call it 'length' here.
*/
#define INVALID -1
#define isGoal(rd) (rd->type == READ && !rd->internal)
#define isBound(rd) (rd->bound)
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#define length step
//! Indent print
void
indentPrint ()
{
if (sys->output == ATTACK && globalError == 0)
{
// Arachne, attack, not an error
// We assume that means DOT output
eprintf ("// ");
}
else
{
// If it is not to stdout, or it is not an attack...
int i;
for (i = 0; i < indentDepth; i++)
{
if (i % 3 == 0)
eprintf ("|");
else
eprintf (" ");
eprintf (" ");
}
}
}
//! Print indented binding
void
binding_indent_print (const Binding b, const int flag)
{
indentPrint ();
if (flag)
eprintf ("!! ");
binding_print (b);
eprintf ("\n");
}
//! Determine whether a term is a functor
int
isTermFunctionName (Term t)
{
t = deVar (t);
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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 (t != NULL)
{
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if (realTermEncrypt (t) && isTermFunctionName (TermKey (t)))
{
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return TermKey (t);
}
}
return NULL;
}
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//! Wrapper for roleInstance
/**
*@return Returns the run number
*/
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int
semiRunCreate (const Protocol p, const Role r)
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{
int run;
if (p == INTRUDER)
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num_intruder_runs++;
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else
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num_regular_runs++;
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roleInstance (sys, p, r, NULL, NULL);
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run = sys->maxruns - 1;
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sys->runs[run].length = 0;
return run;
}
//! Wrapper for roleDestroy
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void
semiRunDestroy ()
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{
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if (sys->maxruns > 0)
{
Protocol p;
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p = sys->runs[sys->maxruns - 1].protocol;
roleInstanceDestroy (sys);
if (p == INTRUDER)
num_intruder_runs--;
else
num_regular_runs--;
}
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}
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//! After a role instance, or an extension of a run, we might need to add some goals
/**
* From old to new. Sets the new length to new.
*@returns The number of goals added (for destructions)
*/
int
add_read_goals (const int run, const int old, const int new)
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{
int count;
int i;
Roledef rd;
sys->runs[run].length = new;
i = old;
rd = roledef_shift (sys->runs[run].start, i);
count = 0;
while (i < new && rd != NULL)
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{
if (rd->type == READ)
{
if (sys->output == PROOF)
{
if (count == 0)
{
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indentPrint ();
eprintf ("Thus, we must also produce ");
}
else
{
eprintf (", ");
}
termPrint (rd->message);
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}
count = count + goal_add (rd->message, run, i, 0);
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}
rd = rd->next;
i++;
}
if ((count > 0) && sys->output == PROOF)
{
eprintf ("\n");
}
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return count;
}
//! Determine the run that follows from a substitution.
/**
* After an Arachne unification, stuff might go wrong w.r.t. nonce instantiation.
* This function determines the run that is implied by a substitution list.
* @returns >= 0: a run, -1 for invalid, -2 for any run.
*/
int
determine_unification_run (Termlist tl)
{
int run;
run = -2;
while (tl != NULL)
{
//! Again, hardcoded reference to compiler.c. Level -3 means a local constant for a role.
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if (tl->term->type != VARIABLE && TermRunid (tl->term) == -3)
{
Term t;
t = tl->term->subst;
// It is required that it is actually a leaf, because we construct it.
if (!realTermLeaf (t))
{
return -1;
}
else
{
if (run == -2)
{
// Any run
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run = TermRunid (t);
}
else
{
// Specific run: compare
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if (run != TermRunid (t))
{
return -1;
}
}
}
}
tl = tl->next;
}
return run;
}
//! Determine trace length
int
get_trace_length ()
{
int run;
int length;
run = 0;
length = 0;
while (run < sys->maxruns)
{
if (sys->runs[run].protocol != INTRUDER)
{
// Non-intruder run: count length
// Subtract 'firstReal' to ignore chooses.
length = length + sys->runs[run].length - sys->runs[run].firstReal;
}
run++;
}
return length;
}
//------------------------------------------------------------------------
// Proof reporting
//------------------------------------------------------------------------
//! Protocol/role name of a run
void
role_name_print (const int run)
{
eprintf ("protocol ");
termPrint (sys->runs[run].protocol->nameterm);
eprintf (", role ");
termPrint (sys->runs[run].role->nameterm);
}
//! Adding a run/extending a run
void
proof_suppose_run (const int run, const int oldlength, const int newlength)
{
if (sys->output == PROOF)
{
int reallength;
indentPrint ();
eprintf ("Suppose ");
if (oldlength == 0)
eprintf ("there is a ");
else
eprintf ("we extend ");
reallength = roledef_length (sys->runs[run].start);
if (reallength > newlength)
eprintf ("semi-");
eprintf ("run #%i of ", run);
role_name_print (run);
if (reallength > newlength)
{
if (oldlength == 0)
eprintf (" of");
else
eprintf (" to");
eprintf (" length %i", newlength);
}
eprintf ("\n");
}
}
//! Select a goal
void
proof_select_goal (Binding b)
{
if (sys->output == PROOF)
{
Roledef rd;
rd = roledef_shift (sys->runs[b->run_to].start, b->ev_to);
indentPrint ();
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eprintf ("Selected goal: Where does term ");
termPrint (b->term);
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eprintf (" occur first as an interm?\n");
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indentPrint ();
eprintf ("* It is required for ");
roledefPrint (rd);
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eprintf (" at index %i in run %i\n", b->ev_to, b->run_to);
}
}
//! Cannot bind because of cycle
void
proof_cannot_bind (const Binding b, const int run, const int index)
{
if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Cannot bind this to run %i, index %i because that introduces a cycle.\n",
run, index);
}
}
//! Test a binding
void
proof_suppose_binding (Binding b)
{
if (sys->output == PROOF)
{
Roledef rd;
indentPrint ();
rd = roledef_shift (sys->runs[b->run_from].start, b->ev_from);
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eprintf ("Suppose it originates in run %i, at index %i\n", b->run_from,
b->ev_from);
indentPrint ();
eprintf ("* I.e. event ");
roledefPrint (rd);
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eprintf ("\n");
indentPrint ();
eprintf ("* from ");
role_name_print (b->run_from);
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eprintf ("\n");
}
}
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//------------------------------------------------------------------------
// Sub
//------------------------------------------------------------------------
//! Iterate over all send types in the roles (including the intruder ones)
/**
* Function is called with (protocol pointer, role pointer, roledef pointer, index)
* and returns an integer. If it is false, iteration aborts.
*/
int
iterate_role_sends (int (*func) ())
{
Protocol p;
p = sys->protocols;
while (p != NULL)
{
Role r;
r = p->roles;
while (r != NULL)
{
Roledef rd;
int index;
rd = r->roledef;
index = 0;
while (rd != NULL)
{
if (rd->type == SEND)
{
if (!func (p, r, rd, index))
return 0;
}
index++;
rd = rd->next;
}
r = r->next;
}
p = p->next;
}
return 1;
}
//! Try to bind a specific existing run to a goal.
/**
* The key goals are bound to the goal.
*@param subterm determines whether it is a subterm unification or not.
*/
int
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bind_existing_to_goal (const Binding b, const int run, const int index)
{
Roledef rd;
int flag;
int old_length;
int newgoals;
int found;
int subterm_iterate (Termlist substlist, Termlist keylist)
{
int flag;
found++;
flag = 1;
/**
* Now create the new bindings
*/
if (goal_bind (b, run, index))
{
int newgoals;
Termlist tl;
proof_suppose_binding (b);
if (keylist != NULL && sys->output == PROOF)
{
indentPrint ();
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eprintf
("This introduces the obligation to produce the following keys: ");
termlistPrint (keylist);
eprintf ("\n");
}
newgoals = 0;
tl = keylist;
while (tl != NULL)
{
int keyrun;
int prioritylevel;
/* normally, a key gets higher priority */
prioritylevel = 1;
if (realTermEncrypt (tl->term))
{
/* the key is a construction itself */
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if (inKnowledge (sys->know, TermKey (tl->term)))
{
/* the key is constructed by a public thing */
/* typically, this is a public key, so we postpone it */
prioritylevel = -1;
}
}
/* add the key as a goal */
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newgoals =
newgoals + goal_add (tl->term, b->run_to, b->ev_to,
prioritylevel);
tl = tl->next;
}
indentDepth++;
flag = flag && iterate ();
indentDepth--;
goal_remove_last (newgoals);
}
else
{
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proof_cannot_bind (b, run, index);
}
goal_unbind (b);
return flag;
}
//----------------------------
// Roledef entry
rd = roledef_shift (sys->runs[run].start, index);
// Fix length
old_length = sys->runs[run].length;
if ((index + 1) > old_length)
newgoals = add_read_goals (run, old_length, index + 1);
else
newgoals = 0;
// Bind to existing run
found = 0;
flag = termMguSubTerm (b->term, rd->message,
subterm_iterate, sys->know->inverses, NULL);
// Did it work?
if (found == 0 && sys->output == PROOF)
{
indentPrint ();
eprintf ("Cannot bind ");
termPrint (b->term);
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eprintf (" to run %i, index %i because it does not subterm-unify.\n",
run, index);
}
// Reset length
goal_remove_last (newgoals);
sys->runs[run].length = old_length;
return flag;
}
//! Bind a goal to an existing regular run, if possible
int
bind_existing_run (const Binding b, const Protocol p, const Role r,
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const int index)
{
int run, flag;
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int found;
flag = 1;
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found = 0;
for (run = 0; run < sys->maxruns; run++)
{
if (sys->runs[run].protocol == p && sys->runs[run].role == r)
{
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found++;
if (sys->output == PROOF)
{
if (found == 1)
{
indentPrint ();
eprintf ("Can we bind it to an existing regular run of ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
eprintf ("?\n");
}
indentPrint ();
eprintf ("%i. Can we bind it to run %i?\n", found, run);
}
indentDepth++;
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flag = flag && bind_existing_to_goal (b, run, index);
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indentDepth--;
}
}
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if (sys->output == PROOF && found == 0)
{
indentPrint ();
eprintf ("There is no existing run for ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
eprintf ("\n");
}
return flag;
}
//! Bind a goal to a new run
int
bind_new_run (const Binding b, const Protocol p, const Role r,
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const int index)
{
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int run;
int flag;
int newgoals;
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findLoserBegin (graph_uordblks);
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run = semiRunCreate (p, r);
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proof_suppose_run (run, 0, index + 1);
{
findLoserBegin (graph_uordblks);
newgoals = add_read_goals (run, 0, index + 1);
indentDepth++;
flag = bind_existing_to_goal (b, run, index);
indentDepth--;
goal_remove_last (newgoals);
findLoserEnd (graph_uordblks, "bind_new_run: add read goals");
}
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semiRunDestroy ();
findLoserEnd (graph_uordblks, "bind_new_run: inner");
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return flag;
}
//! Display the current semistate using dot output format.
void
dotSemiState ()
{
static int attack_number = 0;
int run;
Protocol p;
int *ranks;
int maxrank;
void node (const int run, const int index)
{
if (sys->runs[run].protocol == INTRUDER)
{
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if (sys->runs[run].role == I_M)
{
eprintf ("m0");
}
else
{
eprintf ("i%i", run);
}
}
else
{
eprintf ("r%ii%i", run, index);
}
}
// Open graph
attack_number++;
eprintf ("digraph semiState%i {\n", attack_number);
eprintf ("\tlabel = \"Protocol ");
p = (Protocol) current_claim->protocol;
termPrint (p->nameterm);
eprintf (", role ");
termPrint (current_claim->rolename);
eprintf (", claim type ");
termPrint (current_claim->type);
eprintf ("\";\n");
// Needed for the bindings later on: create graph
goal_graph_create (); // create graph
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if (warshall (graph, nodes) == 0) // determine closure
{
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eprintf
("// This graph was not completely closed transitively because it contains a cycle!\n");
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}
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ranks = memAlloc (nodes * sizeof (int));
maxrank = graph_ranks (graph, ranks, nodes); // determine ranks
#ifdef DEBUG
// For debugging purposes, we also display an ASCII version of some stuff in the comments
printSemiState ();
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// Even draw all dependencies for non-intruder runs
// Real nice debugging :(
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{
int run;
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run = 0;
while (run < sys->maxruns)
{
int ev;
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ev = 0;
while (ev < sys->runs[run].length)
{
int run2;
int notfirstrun;
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eprintf ("// precedence: r%ii%i <- ", run, ev);
run2 = 0;
notfirstrun = 0;
while (run2 < sys->maxruns)
{
int notfirstev;
int ev2;
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notfirstev = 0;
ev2 = 0;
while (ev2 < sys->runs[run2].length)
{
if (graph[graph_nodes (nodes, run2, ev2, run, ev)] != 0)
{
if (notfirstev)
eprintf (",");
else
{
if (notfirstrun)
eprintf (" ");
eprintf ("r%i:", run2);
}
eprintf ("%i", ev2);
notfirstrun = 1;
notfirstev = 1;
}
ev2++;
}
run2++;
}
eprintf ("\n");
ev++;
}
run++;
}
}
#endif
// Draw graph
// First, all simple runs
run = 0;
while (run < sys->maxruns)
{
Roledef rd;
int index;
index = 0;
rd = sys->runs[run].start;
if (sys->runs[run].protocol != INTRUDER && sys->runs[run].length > 0)
{
// Regular run
/* DISABLED subgraphs
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eprintf ("\tsubgraph cluster_run%i {\n", run);
eprintf ("\t\tlabel = \"");
eprintf ("#%i: ", run);
termPrint (sys->runs[run].protocol->nameterm);
eprintf (", ");
agentsOfRunPrint (sys, run);
eprintf ("\";\n", run);
if (run == 0)
{
eprintf ("\t\tcolor = red;\n");
}
else
{
eprintf ("\t\tcolor = blue;\n");
}
*/
// Display the respective events
while (index < sys->runs[run].length)
{
// Print node itself
eprintf ("\t\t");
node (run, index);
eprintf (" [");
if (run == 0 && index == current_claim->ev)
{
eprintf
("style=filled,fillcolor=mistyrose,color=salmon,shape=doubleoctagon,");
}
else
{
eprintf ("shape=box,");
}
eprintf ("label=\"");
roledefPrintShort (rd);
eprintf ("\"]");
eprintf (";\n");
// Print binding to previous node
if (index > sys->runs[run].firstReal)
{
// index > 0
eprintf ("\t\t");
node (run, index - 1);
eprintf (" -> ");
node (run, index);
eprintf (" [style=\"bold\", weight=\"10.0\"]");
eprintf (";\n");
}
else
{
// index <= firstReal
if (index == sys->runs[run].firstReal)
{
// index == firstReal
Roledef rd;
int send_before_read;
int done;
// Determine if it is an active role or note
/**
*@todo note that this will probably become a standard function call for role.h
*/
rd =
roledef_shift (sys->runs[run].start,
sys->runs[run].firstReal);
done = 0;
send_before_read = 0;
while (!done && rd != NULL)
{
if (rd->type == READ)
{
done = 1;
}
if (rd->type == SEND)
{
done = 1;
send_before_read = 1;
}
rd = rd->next;
}
// Draw the first box
// This used to be drawn only if done && send_before_read, now we always draw it.
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eprintf ("\t\ts%i [label=\"Run %i\\n", run, run);
agentsOfRunPrint (sys, run);
eprintf ("\", shape=diamond];\n");
eprintf ("\t\ts%i -> ", run);
node (run, index);
eprintf (";\n");
}
}
index++;
rd = rd->next;
}
/* DISABLED subgraphs
2004-11-16 12:07:55 +00:00
eprintf ("\t}\n");
*/
}
run++;
}
// Second, all bindings.
// We now determine them ourselves between existing runs
run = 0;
while (run < sys->maxruns)
{
if (sys->runs[run].protocol != INTRUDER)
{
int ev;
ev = 0;
while (ev < sys->runs[run].length)
2004-08-28 13:42:11 +01:00
{
/**
* Determine wheter to draw an incoming arrow to this event.
* We check all other runs, to see if they are ordered.
*/
int run2;
run2 = 0;
while (run2 < sys->maxruns)
{
if (run2 != run && sys->runs[run2].protocol != INTRUDER)
{
// Is this run before the event?
int ev2;
int found;
found = 0;
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ev2 = sys->runs[run2].length;
while (found == 0 && ev2 > 0)
{
2004-10-28 16:23:16 +01:00
ev2--;
if (graph[graph_nodes (nodes, run2, ev2, run, ev)]
!= 0)
{
found = 1;
}
}
if (found == 1)
{
// It is before the event, and thus we would like to draw it.
// However, if there is another path along which we can get here, forget it
2004-08-28 15:05:38 +01:00
/**
* Note that this algorithm is similar to Floyd's algorithm for all shortest paths.
* The goal here is to select only the path with distance 1 (as viewed from the regular runs),
* so we can simplify stuff a bit.
* Nevertheless, using Floyd first would probably be faster.
2004-08-28 15:05:38 +01:00
*/
int other_route;
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int run3;
int ev3;
other_route = 0;
run3 = 0;
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ev3 = 0;
while (other_route == 0 && run3 < sys->maxruns)
{
if (sys->runs[run3].protocol != INTRUDER)
{
ev3 = 0;
while (other_route == 0
&& ev3 < sys->runs[run3].length)
{
if (graph
[graph_nodes
(nodes, run2, ev2, run3, ev3)] != 0
&&
graph[graph_nodes
(nodes, run3, ev3, run,
ev)] != 0)
{
// other route found
other_route = 1;
}
ev3++;
}
}
run3++;
}
if (other_route == 0)
{
2004-11-16 12:07:55 +00:00
Roledef rd, rd2;
/*
* We have decided to draw this binding,
* from run2,ev2 to run,ev
* However, me might need to decide some colouring for this node.
*/
eprintf ("\t");
node (run2, ev2);
eprintf (" -> ");
node (run, ev);
eprintf (" ");
// decide color
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rd = roledef_shift (sys->runs[run].start, ev);
rd2 =
roledef_shift (sys->runs[run2].start, ev2);
if (rd->type == CLAIM)
{
// Towards a claim, so only indirect dependency
eprintf ("[color=cornflowerblue]");
}
else
{
// Not towards claim should imply towards read,
// but we check it to comply with future stuff.
if (rd->type == READ && rd2->type == SEND)
{
// We want to distinguish where it is from a 'broken' send
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if (isTermEqual
(rd->message, rd2->message))
{
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if (isTermEqual
(rd->from, rd2->from)
&& isTermEqual (rd->to,
rd2->to))
{
// Wow, a perfect match. Leave the arrow as-is :)
eprintf ("[color=forestgreen]");
}
else
{
// Same message, different people
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eprintf
("[label=\"redirect\",color=darkorange2]");
}
}
else
{
// Not even the same message, intruder construction
2004-11-16 12:07:55 +00:00
eprintf
("[label=\"construct\",color=red]");
}
}
}
// close up
eprintf (";\n");
}
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#ifdef DEBUG
else
{
// for debugging: show other route
run3--;
ev3--;
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eprintf
("\t// HIDDEN r%ii%i -> r%ii%i because route through r%ii%i\n",
run2, ev2, run, ev, run3, ev3);
2004-10-28 16:23:16 +01:00
}
#endif
}
}
run2++;
}
ev++;
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}
}
run++;
}
// Third, all ranking info
2004-11-16 12:07:55 +00:00
{
int myrank;
#ifdef DEBUG
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{
int n;
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eprintf ("/* ranks: %i\n", maxrank);
n = 0;
while (n < nodes)
{
eprintf ("%i ", ranks[n]);
n++;
}
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eprintf ("\n*/\n\n");
}
#endif
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myrank = 0;
while (myrank < maxrank)
{
int count;
int run;
int run1;
int ev1;
count = 0;
run = 0;
while (run < sys->maxruns)
{
if (sys->runs[run].protocol != INTRUDER)
{
int ev;
2004-11-16 12:07:55 +00:00
ev = 0;
while (ev < sys->runs[run].step)
{
if (myrank == ranks[node_number (run, ev)])
{
if (count == 0)
eprintf ("\t{ rank = same; ");
count++;
eprintf ("r%ii%i; ", run, ev);
}
ev++;
}
}
run++;
}
if (count > 0)
eprintf ("}\t\t// rank %i\n", myrank);
myrank++;
}
}
// clean memory
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memFree (ranks, nodes * sizeof (int)); // ranks
// close graph
eprintf ("};\n\n");
}
//! Print the current semistate
void
printSemiState ()
{
int run;
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int open;
List bl;
int binding_state_print (void *dt)
{
binding_indent_print ((Binding) dt, 1);
return 1;
}
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indentPrint ();
eprintf ("!! --=[ Semistate ]=--\n");
indentPrint ();
eprintf ("!!\n");
indentPrint ();
eprintf ("!! Trace length: %i\n", get_trace_length ());
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open = 0;
for (run = 0; run < sys->maxruns; run++)
{
int index;
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Role r;
Roledef rd;
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Term oldagent;
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indentPrint ();
eprintf ("!!\n");
indentPrint ();
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eprintf ("!! [ Run %i, ", run);
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termPrint (sys->runs[run].protocol->nameterm);
eprintf (", ");
r = sys->runs[run].role;
oldagent = r->nameterm->subst;
r->nameterm->subst = NULL;
termPrint (r->nameterm);
r->nameterm->subst = oldagent;
if (oldagent != NULL)
{
eprintf (": ");
termPrint (oldagent);
}
eprintf (" ]\n");
index = 0;
rd = sys->runs[run].start;
while (index < sys->runs[run].length)
{
indentPrint ();
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eprintf ("!! %i ", index);
roledefPrint (rd);
eprintf ("\n");
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if (isGoal (rd) && !isBound (rd))
open++;
index++;
rd = rd->next;
}
}
if (sys->bindings != NULL)
{
indentPrint ();
eprintf ("!!\n");
list_iterate (sys->bindings, binding_state_print);
}
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indentPrint ();
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eprintf ("!!\n");
indentPrint ();
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eprintf ("!! - open: %i -\n", open);
}
//------------------------------------------------------------------------
// Larger logical componentents
//------------------------------------------------------------------------
//! Goal selection
/**
* Selects the most constrained goal.
*
* First selection is on level; thus, keys are selected first.
*
* Because the list starts with the newest terms, and we use <= (as opposed to <), we
* ensure that for goals with equal constraint levels, we select the oldest one.
*/
Binding
select_goal ()
{
List bl;
Binding best;
float min_constrain;
int max_level;
// Find the most constrained goal
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Listing open goals that might be chosen: ");
}
max_level = INT_MIN;
best = NULL;
bl = sys->bindings;
while (bl != NULL)
{
Binding b;
b = (Binding) bl->data;
// Ignore singular variables
2004-11-16 12:07:55 +00:00
if (!b->done && !realTermVariable (deVar (b->term)))
//if (!b->done)
{
float cons;
if (sys->output == PROOF && best != NULL)
eprintf (", ");
if (b->level >= max_level)
{
if (b->level > max_level)
{
max_level = b->level;
min_constrain = 1; // 1 is the maximum
}
cons = term_constrain_level (b->term);
if (cons <= min_constrain)
{
min_constrain = cons;
best = b;
if (sys->output == PROOF)
eprintf ("*");
}
}
if (sys->output == PROOF)
{
termPrint (b->term);
eprintf ("[%i]", b->level);
}
}
bl = bl->next;
}
if (sys->output == PROOF)
{
if (best == NULL)
eprintf ("none");
eprintf ("\n");
}
return best;
}
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//! Create a new intruder run to generate knowledge from m0
int
bind_goal_new_m0 (const Binding b)
{
Termlist m0tl,tl;
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int flag;
int found;
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findLoserBegin(graph_uordblks);
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flag = 1;
found = 0;
2004-08-18 19:22:59 +01:00
m0tl = knowledgeSet (sys->know);
tl = m0tl;
while (flag && tl != NULL)
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{
Term m0t;
Termlist subst;
findLoserBegin (graph_uordblks);
2004-08-18 19:22:59 +01:00
m0t = tl->term;
2004-08-18 19:22:59 +01:00
subst = termMguTerm (b->term, m0t);
if (subst != MGUFAIL)
{
int run;
findLoserBegin (graph_uordblks);
I_M->roledef->message = b->term;
2004-08-19 13:47:53 +01:00
run = semiRunCreate (INTRUDER, I_M);
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proof_suppose_run (run, 0, 1);
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sys->runs[run].length = 1;
{
findLoserBegin (graph_uordblks);
indentDepth++;
if (goal_bind (b, run, 0))
2004-08-18 19:22:59 +01:00
{
found++;
proof_suppose_binding (b);
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("* I.e. retrieving ");
termPrint (b->term);
eprintf (" from the initial knowledge.\n");
}
flag = flag && iterate ();
2004-08-18 19:22:59 +01:00
}
else
{
proof_cannot_bind (b, run, 0);
}
goal_unbind (b);
indentDepth--;
findLoserEnd (graph_uordblks, "bind goal new m0 sugar core");
2004-08-19 12:37:41 +01:00
}
2004-08-19 13:47:53 +01:00
semiRunDestroy ();
2004-08-19 15:49:03 +01:00
findLoserEnd (graph_uordblks, "bind goal new m0: inner loop 2");
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termlistSubstReset (subst);
termlistDelete (subst);
}
tl = tl->next;
findLoserEnd(graph_uordblks, "bind goal new m0: inner loop");
2004-08-18 19:22:59 +01:00
}
if (found == 0 && sys->output == PROOF)
{
indentPrint ();
eprintf ("Term ");
termPrint (b->term);
eprintf (" cannot be constructed from the initial knowledge.\n");
}
2004-08-18 19:22:59 +01:00
termlistDelete (m0tl);
findLoserEnd(graph_uordblks, "bind goal new m0");
2004-08-18 19:22:59 +01:00
return flag;
}
//! Bind an intruder goal by intruder composition construction
/**
* Handles the case where the intruder constructs a composed term himself.
*/
2004-08-13 11:25:23 +01:00
int
2004-08-18 19:22:59 +01:00
bind_goal_new_encrypt (const Binding b)
2004-08-13 11:25:23 +01:00
{
Term term;
int flag;
2004-08-19 15:49:03 +01:00
int can_be_encrypted;
findLoserBegin(graph_uordblks);
flag = 1;
2004-08-19 15:55:21 +01:00
term = deVar (b->term);
2004-08-19 15:49:03 +01:00
can_be_encrypted = 0;
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if (!realTermLeaf (term))
{
int run;
int index;
int newgoals;
Roledef rd;
Term t1, t2;
2004-08-19 15:49:03 +01:00
if (!realTermEncrypt (term))
{
// tuple construction
error ("Goal that is a tuple should not occur!");
}
// must be encryption
2004-11-16 12:07:55 +00:00
t1 = TermOp (term);
t2 = TermKey (term);
2004-08-19 15:49:03 +01:00
if (t2 != TERM_Hidden)
{
2004-08-19 15:49:03 +01:00
can_be_encrypted = 1;
run = semiRunCreate (INTRUDER, I_RRS);
rd = sys->runs[run].start;
rd->message = termDuplicateUV (t1);
rd->next->message = termDuplicateUV (t2);
2004-08-19 15:49:03 +01:00
rd->next->next->message = termDuplicateUV (term);
index = 2;
proof_suppose_run (run, 0, index + 1);
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("* Encrypting ");
termPrint (term);
eprintf (" using term ");
termPrint (t1);
eprintf (" and key ");
termPrint (t2);
eprintf ("\n");
}
{ // indenting purely added for findLoser
findLoserBegin(graph_uordblks);
newgoals = add_read_goals (run, 0, index + 1);
2004-08-19 15:55:21 +01:00
indentDepth++;
if (goal_bind (b, run, index))
{
proof_suppose_binding (b);
flag = flag && iterate ();
}
else
{
proof_cannot_bind (b, run, index);
}
goal_unbind (b);
indentDepth--;
goal_remove_last (newgoals);
findLoserEnd(graph_uordblks, "Goal bindings within m0 new");
2004-08-19 15:49:03 +01:00
}
semiRunDestroy ();
2004-08-19 12:37:41 +01:00
}
}
2004-08-19 15:49:03 +01:00
if (!can_be_encrypted)
{
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Term ");
termPrint (b->term);
eprintf (" cannot be constructed by encryption.\n");
}
}
findLoserEnd(graph_uordblks, "bind goal new encrypt");
return flag;
2004-08-13 11:25:23 +01:00
}
2004-08-18 19:22:59 +01:00
//! Bind an intruder goal by intruder construction
/**
* Handles the case where the intruder constructs a composed term himself.
*/
int
bind_goal_new_intruder_run (const Binding b)
{
int flag;
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Can we bind ");
termPrint (b->term);
eprintf (" from a new intruder run?\n");
}
indentDepth++;
flag = bind_goal_new_m0 (b);
flag = flag && bind_goal_new_encrypt (b);
indentDepth--;
return flag;
2004-08-18 19:22:59 +01:00
}
2004-08-13 11:25:23 +01:00
//! Bind a regular goal
/**
* Problem child. Valgrind does not like it.
*/
2004-08-11 13:08:10 +01:00
int
bind_goal_regular_run (const Binding b)
2004-08-11 13:08:10 +01:00
{
2004-08-15 18:07:38 +01:00
int flag;
2004-08-19 12:37:41 +01:00
int found;
2004-08-15 18:07:38 +01:00
2004-08-30 22:49:51 +01:00
int test_sub_unification (Termlist substlist, Termlist keylist)
{
// A unification exists; return the signal
return 0;
}
/*
* This is a local function so we have access to goal
*/
int bind_this_role_send (Protocol p, Role r, Roledef rd, int index)
{
if (p == INTRUDER)
{
// No intruder roles here
return 1;
}
// Test for interm unification
#ifdef DEBUG
if (DEBUGL (5))
{
indentPrint ();
eprintf ("Checking send candidate with message ");
termPrint (rd->message);
eprintf (" from ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
eprintf (", index %i\n", index);
}
#endif
if (!termMguSubTerm
2004-11-16 12:07:55 +00:00
(b->term, rd->message, test_sub_unification, sys->know->inverses,
NULL))
{
int sflag;
findLoserBegin (graph_uordblks);
// A good candidate
2004-08-19 12:37:41 +01:00
found++;
if (sys->output == PROOF && found == 1)
{
indentPrint ();
eprintf ("The term ", found);
termPrint (b->term);
2004-08-19 14:09:35 +01:00
eprintf
(" matches patterns from the role definitions. Investigate.\n");
}
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("%i. It matches the pattern ", found);
2004-08-19 12:37:41 +01:00
termPrint (rd->message);
eprintf (" from ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
2004-08-19 12:37:41 +01:00
eprintf (", at %i\n", index);
}
indentDepth++;
// Bind to existing run
sflag = bind_existing_run (b, p, r, index);
// bind to new run
{
findLoserBegin (graph_uordblks);
sflag = sflag && bind_new_run (b, p, r, index);
findLoserEnd (graph_uordblks, "bind this role send; new run");
}
indentDepth--;
findLoserEnd (graph_uordblks, "bind this role send x");
return sflag;
}
else
{
return 1;
}
}
// Bind to all possible sends of regular runs
2004-08-19 12:37:41 +01:00
found = 0;
flag = iterate_role_sends (bind_this_role_send);
if (sys->output == PROOF && found == 0)
{
indentPrint ();
eprintf ("The term ");
termPrint (b->term);
eprintf (" does not match any pattern from the role definitions.\n");
}
return flag;
}
// Bind to all possible sends of intruder runs
2004-08-18 20:43:58 +01:00
int
bind_goal_old_intruder_run (Binding b)
{
int run;
int flag;
int found;
found = 0;
flag = 1;
for (run = 0; run < sys->maxruns; run++)
{
if (sys->runs[run].protocol == INTRUDER)
{
int ev;
Roledef rd;
2004-08-18 20:43:58 +01:00
rd = sys->runs[run].start;
ev = 0;
while (ev < sys->runs[run].length)
{
if (rd->type == SEND)
{
found++;
if (sys->output == PROOF && found == 1)
{
indentPrint ();
2004-08-19 14:09:35 +01:00
eprintf
("Suppose it is from an existing intruder run.\n");
}
2004-08-19 14:09:35 +01:00
indentDepth++;
2004-08-18 20:43:58 +01:00
flag = flag && bind_existing_to_goal (b, run, ev);
2004-08-19 14:09:35 +01:00
indentDepth--;
}
rd = rd->next;
ev++;
}
}
}
if (sys->output == PROOF && found == 0)
{
indentPrint ();
eprintf ("No existing intruder runs to match to.\n");
}
return flag;
2004-08-11 13:08:10 +01:00
}
//! Bind a goal in all possible ways
int
bind_goal (const Binding b)
2004-08-11 13:08:10 +01:00
{
if (!b->done)
2004-08-11 13:08:10 +01:00
{
int flag;
int know_only;
Term function;
flag = 1;
proof_select_goal (b);
indentDepth++;
// Prune: if it is an SK type construct, ready
// No regular run will apply SK for you.
//!@todo This still needs a lemma, and a more generic (correct) algorithm!!
know_only = 0;
function = getTermFunction (b->term);
if (function != NULL)
{
if (!inKnowledge (sys->know, function))
{
// Prune because we didn't know it before, and it is never subterm-sent
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("* Because ");
termPrint (b->term);
eprintf
(" is never sent from a regular run (STILL NEEDS LEMMA!), we only intruder construct it.\n");
}
know_only = 1;
}
}
proofDepth++;
if (know_only)
{
findLoserBegin (graph_uordblks);
// Special case: only from intruder
flag = flag && bind_goal_old_intruder_run (b);
flag = flag && bind_goal_new_intruder_run (b);
findLoserEnd (graph_uordblks, "bind_goal intruder case");
}
else
{
// Normal case
{
findLoserBegin (graph_uordblks);
flag = bind_goal_regular_run (b);
findLoserEnd (graph_uordblks, "bind_goal case regular run");
}
flag = flag && bind_goal_old_intruder_run (b);
flag = flag && bind_goal_new_intruder_run (b);
}
proofDepth--;
indentDepth--;
return flag;
2004-08-11 13:08:10 +01:00
}
else
{
return 1;
2004-08-11 13:08:10 +01:00
}
}
2004-08-19 14:09:35 +01:00
//! Prune determination because of theorems
/**
2004-08-19 14:09:35 +01:00
*@returns true iff this state is invalid because of a theorem
*/
int
2004-08-19 14:09:35 +01:00
prune_theorems ()
{
Termlist tl;
2004-08-18 20:43:58 +01:00
List bl;
int run;
// Check if all agents are agents (!)
run = 0;
while (run < sys->maxruns)
{
Termlist agl;
agl = sys->runs[run].agents;
while (agl != NULL)
{
Term agent;
2004-11-16 12:07:55 +00:00
agent = deVar (agl->term);
if (agent == NULL)
{
error ("Agent of run %i is NULL", run);
}
2004-11-16 12:07:55 +00:00
if (!realTermLeaf (agent)
|| (agent->stype != NULL
&& !inTermlist (agent->stype, TERM_Agent)))
{
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Pruned because the agent ");
termPrint (agent);
eprintf (" of run %i is not of a compatible type.\n", run);
}
return 1;
}
agl = agl->next;
}
run++;
}
// Check if all agents of the main run are valid
tl = sys->runs[0].agents;
while (tl != NULL)
{
Term agent;
agent = deVar (tl->term);
if (!realTermVariable (agent) && inTermlist (sys->untrusted, agent))
{
if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Pruned because all agents of the claim run must be trusted.\n");
}
return 1;
}
tl = tl->next;
}
// Check if the actors of all other runs are not untrusted
if (sys->untrusted != NULL)
{
int run;
run = 1;
while (run < sys->maxruns)
{
if (sys->runs[run].protocol != INTRUDER)
{
if (sys->runs[run].agents != NULL)
{
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Term actor;
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actor = agentOfRun (sys, run);
if (actor == NULL)
{
error ("Agent of run %i is NULL", run);
}
if (inTermlist (sys->untrusted, actor))
{
if (sys->output == PROOF)
{
indentPrint ();
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eprintf
("Pruned because the actor of run %i is untrusted.\n",
run);
}
return 1;
}
}
else
{
Protocol p;
globalError++;
eprintf ("Run %i: ", run);
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role_name_print (run);
eprintf (" has an empty agents list.\n");
eprintf ("protocol->rolenames: ");
p = (Protocol) sys->runs[run].protocol;
termlistPrint (p->rolenames);
eprintf ("\n");
error ("Aborting.");
globalError--;
return 1;
}
}
run++;
}
}
// Check for c-minimality
{
findLoserBegin(graph_uordblks);
if (!bindings_c_minimal ())
{
if (sys->output == PROOF)
{
findLoserBegin(graph_uordblks);
indentPrint ();
eprintf ("Pruned because this is not <=c-minimal.\n");
}
return 1;
}
findLoserEnd(graph_uordblks, "C-minimality test");
}
/**
* Check whether the bindings are valid
*/
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bl = sys->bindings;
while (bl != NULL)
{
Binding b;
b = bl->data;
// Check for "Hidden" interm goals
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if (termInTerm (b->term, TERM_Hidden))
{
// Prune the state: we can never meet this
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Pruned because intruder can never construnct ");
termPrint (b->term);
eprintf ("\n");
}
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return 1;
}
// Check for encryption levels
if (sys->match < 2
&& (term_encryption_level (b->term) > max_encryption_level))
{
// Prune: we do not need to construct such terms
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Pruned because the encryption level of ");
termPrint (b->term);
eprintf (" is too high.\n");
}
return 1;
}
// Check for SK-type function occurrences
//!@todo Needs a LEMMA, although this seems to be quite straightforward to prove.
// The idea is that functions are never sent as a whole, but only used in applications.
if (isTermFunctionName (b->term))
{
if (!inKnowledge (sys->know, b->term))
{
// Not in initial knowledge of the intruder
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Pruned because the function ");
termPrint (b->term);
eprintf (" is not known initially to the intruder.\n");
}
return 1;
}
}
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bl = bl->next;
}
return 0;
}
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//! Prune determination for bounds
/**
*@returns true iff this state is invalid for some reason
*/
int
prune_bounds ()
{
Termlist tl;
List bl;
if (proofDepth > sys->switch_maxtracelength)
{
// Hardcoded limit on proof tree depth
if (sys->output == PROOF)
{
indentPrint ();
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eprintf ("Pruned: proof tree too deep: %i (-l %i switch)\n",
proofDepth, sys->switch_maxtracelength);
}
return 1;
}
if (num_regular_runs > sys->switchRuns)
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{
// Hardcoded limit on runs
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if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Pruned: too many regular runs (%i).\n", num_regular_runs);
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}
return 1;
}
// This needs some foundation. Probably * 2^max_encryption_level
//!@todo Fix this bound
if ((sys->match < 2)
&& (num_intruder_runs >
((double) sys->switchRuns * max_encryption_level * 8)))
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{
// Hardcoded limit on iterations
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if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Pruned: %i intruder runs is too much. (max encr. level %i)\n",
num_intruder_runs, max_encryption_level);
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}
return 1;
}
// Limit on exceeding any attack length
if (sys->prune == 2 && get_trace_length () >= attack_length)
{
if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Pruned: we already know an attack of length %i.\n",
attack_length);
}
return 1;
}
// No pruning because of bounds
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return 0;
}
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//! Prune determination for specific properties
/**
* Sometimes, a property holds in part of the tree. Thus, we don't need to explore that part further if we want to find an attack.
*
*@returns true iff this state is invalid for some reason
*/
int
prune_claim_specifics ()
{
if (current_claim->type == CLAIM_Niagree)
{
if (arachne_claim_niagree (sys, 0, current_claim->ev))
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{
current_claim->count = statesIncrease (current_claim->count);
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if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Pruned: niagree holds in this part of the proof tree.\n");
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}
return 1;
}
}
if (current_claim->type == CLAIM_Nisynch)
{
if (arachne_claim_nisynch (sys, 0, current_claim->ev))
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{
current_claim->count = statesIncrease (current_claim->count);
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if (sys->output == PROOF)
{
indentPrint ();
eprintf
("Pruned: nisynch holds in this part of the proof tree.\n");
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}
return 1;
}
}
return 0;
}
//! Setup system for specific claim test
add_claim_specifics (const Claimlist cl, const Roledef rd)
{
if (cl->type == CLAIM_Secret)
{
/**
* Secrecy claim
*/
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("* To verify the secrecy claim, we add the term ");
termPrint (rd->message);
eprintf (" as a goal.\n");
indentPrint ();
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eprintf
("* If all goals can be bound, this constitutes an attack.\n");
}
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/**
* We say that a state exists for secrecy, but we don't really test wheter the claim can
* be reached (without reaching the attack).
*/
cl->count = statesIncrease (cl->count);
goal_add (rd->message, 0, cl->ev, 0); // Assumption that all claims are in run 0
}
}
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//! Count a false claim
void
count_false ()
{
current_claim->failed = statesIncrease (current_claim->failed);
}
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//------------------------------------------------------------------------
// Main logic core
//------------------------------------------------------------------------
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//! Check properties
int
property_check ()
{
int flag;
int attack_this;
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flag = 1;
/**
* By the way the claim is handled, this automatically means a flaw.
*/
count_false ();
if (sys->output == ATTACK)
dotSemiState ();
// Store attack length if shorter
attack_this = get_trace_length ();
if (attack_this < attack_length)
{
// Shortest attack
attack_length = attack_this;
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("New shortest attack found with trace length %i.\n",
attack_length);
}
}
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return flag;
}
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//! Main recursive procedure for Arachne
int
iterate ()
{
int flag;
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findLoserBegin(graph_uordblks);
flag = 1;
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if (!prune_theorems ())
{
findLoserBegin(graph_uordblks);
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if (!prune_claim_specifics ())
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{
findLoserBegin(graph_uordblks);
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if (!prune_bounds ())
{
Binding b;
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/**
* Not pruned: count
*/
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sys->states = statesIncrease (sys->states);
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/**
* Check whether its a final state (i.e. all goals bound)
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*/
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b = select_goal ();
if (b == NULL)
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{
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/*
* all goals bound, check for property
*/
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("All goals are now bound.\n");
}
sys->claims = statesIncrease (sys->claims);
current_claim->count =
statesIncrease (current_claim->count);
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flag = property_check ();
}
else
{
/*
* bind this goal in all possible ways and iterate
*/
findLoserBegin (graph_uordblks);
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flag = bind_goal (b);
findLoserEnd (graph_uordblks, "bind_goal outer");
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}
}
else
{
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// Pruned because of bound!
current_claim->complete = 0;
}
findLoserEnd(graph_uordblks, "just outside prune_bounds condition");
}
findLoserEnd(graph_uordblks, "just outside prune_claim_specifics condition");
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}
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#ifdef DEBUG
if (DEBUGL (5) && !flag)
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{
warning ("Flag has turned 0!");
}
#endif
#ifdef DEBUG
findLoserEnd (graph_uordblks, "iterate");
#endif
return flag;
}
//! Main code for Arachne
/**
* For this test, we manually set up some stuff.
*
* But later, this will just iterate over all claims.
*/
int
arachne ()
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{
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Claimlist cl;
int print_send (Protocol p, Role r, Roledef rd, int index)
{
eprintf ("IRS: ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
eprintf (", %i, ", index);
roledefPrint (rd);
eprintf ("\n");
return 1;
}
int determine_encrypt_max (Protocol p, Role r, Roledef rd, int index)
{
int tlevel;
tlevel = term_encryption_level (rd->message);
if (tlevel > max_encryption_level)
max_encryption_level = tlevel;
return 1;
}
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/*
* set up claim role(s)
*/
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if (sys->switchRuns == 0)
{
// No real checking.
return;
}
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if (sys->maxruns > 0)
{
error ("Something is wrong, number of runs >0.");
}
num_regular_runs = 0;
num_intruder_runs = 0;
max_encryption_level = 0;
iterate_role_sends (determine_encrypt_max);
#ifdef DEBUG
if (DEBUGL (1))
{
eprintf ("Maximum encryption level: %i\n", max_encryption_level);
iterate_role_sends (print_send);
}
#endif
indentDepth = 0;
proofDepth = 0;
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cl = sys->claimlist;
while (cl != NULL)
{
/**
* Check each claim
*/
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Protocol p;
Role r;
if (sys->switchClaimToCheck == NULL
|| sys->switchClaimToCheck == cl->type)
{
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int run;
current_claim = cl;
attack_length = INT_MAX;
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cl->complete = 1;
p = (Protocol) cl->protocol;
r = (Role) cl->role;
if (sys->output == PROOF)
{
indentPrint ();
eprintf ("Testing Claim ");
termPrint (cl->type);
eprintf (" from ");
termPrint (p->nameterm);
eprintf (", ");
termPrint (r->nameterm);
eprintf (" at index %i.\n", cl->ev);
}
indentDepth++;
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run = semiRunCreate (p, r);
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proof_suppose_run (run, 0, cl->ev + 1);
add_read_goals (run, 0, cl->ev + 1);
/**
* Add specific goal info
*/
add_claim_specifics (cl,
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roledef_shift (sys->runs[run].start, cl->ev));
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#ifdef DEBUG
if (DEBUGL (5))
{
printSemiState ();
}
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#endif
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// Iterate
iterate ();
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//! Destroy
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while (sys->bindings != NULL)
{
goal_remove_last (1);
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}
while (sys->maxruns > 0)
{
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semiRunDestroy ();
}
indentDepth--;
}
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// next
cl = cl->next;
}
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}