public DiscardInfo isObviousStatically(VarInfo[] vis) { VarInfo subvar = var1(vis); VarInfo supervar = var2(vis); // check for x[i..j] subsequence of x[] VarInfo subvar_super = subvar.isDerivedSubSequenceOf(); if (subvar_super == supervar) { debug.fine(" returning true because subvar_super == supervar"); return new DiscardInfo(this, DiscardCode.obvious, "x[i..j] subsequence of x[] is obvious"); } Object[] obv1 = SubSequence.isObviousSubSequence(subvar, supervar); if (obv1[1] != null) { return new DiscardInfo(this, (DiscardCode) obv1[0], (String) obv1[1]); } // JHP: This is not a valid obvious check, since it doesn't imply that // the invariant is true. if (!subvar.aux.getFlag(VarInfoAux.HAS_ORDER) || !supervar.aux.getFlag(VarInfoAux.HAS_ORDER)) { // Doesn't make sense to consider subsequence if order doens't matter return new DiscardInfo( this, DiscardCode.obvious, "Order doesn't matter, so subsequence is meaningless"); } return super.isObviousStatically(vis); }
public String format_simplify() { String[] form = VarInfo.simplify_quantify(QuantFlags.adjacent(), var(), var()); String comparator = "EQ"; return form[0] + "(" + comparator + " " + form[1] + " " + form[2] + ")" + form[3]; }
private VariableManager(VarInfo varInfo, String condition, String className) throws ParseException { this.varInfo = varInfo; name = varInfo.name(); compilableName = compilableName(varInfo, className); fieldName = fieldName(varInfo, className); varName = varName(varInfo, className); type = makeIndexIfNeeded(getVarType(varInfo), compilableName, varInfo, condition); }
/* IOA */ public String format_ioa() { Quantify.IOAQuantification quant = VarInfo.get_ioa_quantify(var(), var()); String result = quant.getQuantifierExp() + "(" + quant.getMembershipRestriction(0) + " /\\ " + quant.getMembershipRestriction(1); // i \in X /\ j \in X => X[i] = X[j] result += ") => " + quant.getVarIndexedString(0) + " = " + quant.getVarIndexedString(1); return result + quant.getClosingExp(); }
/** * Calculates the base name of a variable. The base name of a variable is the part of the variable * with prefixes "this." and className removed, and "orig()" replaced by "orig_". For example * orig(this.x) goes to orig_x. If className is "Class" then "Class.x" would yield "x" and * "someOtherClass.x" would yield "someOtherClass_x". Finally, Java Reserved words are replaced * with appropriate substitutes. * * @param varInfo the VarInfo for the variable whose base name is desired. * @return the base name of the variable represented by varInfo. */ private static String getBaseName(VarInfo varInfo, String className) { String name = varInfo.name(); name = replaceReservedWords(name); if (name.length() > 5 && name.substring(0, 5).equals("orig(") && name.endsWith(")")) { name = name.substring(5, name.length() - 1); name = fixPrefixes(name, className); name = "orig_" + name; } else { name = fixPrefixes(name, className); } name = name.replace('.', '_'); name = remove(name, ']'); name = remove(name, '['); return name; }
// (Seems overkill to check for other transitive relationships. // Eventually that is probably the right thing, however.) public DiscardInfo isObviousDynamically(VarInfo[] vis) { // System.out.println("checking isObviousImplied for: " + format()); if (debug.isLoggable(Level.FINE)) { debug.fine("isObviousDynamically: checking " + vis[0].name() + " in " + vis[1].name()); } DiscardInfo super_result = super.isObviousDynamically(vis); if (super_result != null) { return super_result; } VarInfo subvar = var1(vis); VarInfo supervar = var2(vis); // JHP: The next check is an un-interesting check, not // an obvious check. We need to figure out how to resolve this. // Uninteresting if this is of the form x[0..i] subsequence // x[0..j]. Not necessarily obvious. VarInfo subvar_super = subvar.isDerivedSubSequenceOf(); VarInfo supervar_super = supervar.isDerivedSubSequenceOf(); if (subvar_super != null && subvar_super == supervar_super) { debug.fine(" returning true because subvar_super == supervar_super"); return new DiscardInfo( this, DiscardCode.obvious, "x[0..i] subsequence of x[0..j] is uninteresting"); } if (isObviousSubSequenceDynamically(this, subvar, supervar)) { return new DiscardInfo( this, DiscardCode.obvious, subvar.name() + " is an obvious subsequence of " + supervar.name()); } return null; }
/** * Returns true if the two original variables are related in a way that makes subsequence or * subset detection not informative. */ public static boolean isObviousSubSequenceDynamically( Invariant inv, VarInfo subvar, VarInfo supervar) { VarInfo[] vis = {subvar, supervar}; ProglangType rep1 = subvar.rep_type; ProglangType rep2 = supervar.rep_type; if (!(((rep1 == ProglangType.INT_ARRAY) && (rep2 == ProglangType.INT_ARRAY)) || ((rep1 == ProglangType.DOUBLE_ARRAY) && (rep2 == ProglangType.DOUBLE_ARRAY)) || ((rep1 == ProglangType.STRING_ARRAY) && (rep2 == ProglangType.STRING_ARRAY)))) return false; if (debug.isLoggable(Level.FINE)) { debug.fine( "Checking isObviousSubSequenceDynamically " + subvar.name() + " in " + supervar.name()); } Object[] di = isObviousSubSequence(subvar, supervar); if (di[1] != null) { inv.log("ObvSubSeq- true from isObviousSubSequence: " + di[1]); return true; } debug.fine(" not isObviousSubSequence(statically)"); PptTopLevel ppt_parent = subvar.ppt; // If the elements of supervar are always the same (EltOneOf), // we aren't going to learn anything new from this invariant, // since each sequence should have an EltOneOf over it. if (false) { PptSlice1 slice = ppt_parent.findSlice(supervar); if (slice == null) { System.out.println("No slice: parent =" + ppt_parent); } else { System.out.println("Slice var =" + slice.var_infos[0]); for (Invariant superinv : slice.invs) { System.out.println("Inv = " + superinv); if (superinv instanceof EltOneOf) { EltOneOf eltinv = (EltOneOf) superinv; if (eltinv.num_elts() > 0) { inv.log(" obvious because of " + eltinv.format()); return true; } } } } } // Obvious if subvar is always just [] if (true) { PptSlice1 slice = ppt_parent.findSlice(subvar); if (slice != null) { for (Invariant subinv : slice.invs) { if (subinv instanceof OneOfSequence) { OneOfSequence seqinv = (OneOfSequence) subinv; if (seqinv.num_elts() == 1) { Object elt = seqinv.elt(); if (elt instanceof long[] && ((long[]) elt).length == 0) { Debug.log( debug, inv.getClass(), inv.ppt, vis, "ObvSubSeq- True from subvar being []"); return true; } if (elt instanceof double[] && ((double[]) elt).length == 0) { inv.log("ObvSubSeq- True from subvar being []"); return true; } } } } } } // Check for a[0..i] subseq a[0..j] but i < j. VarInfo subvar_super = subvar.isDerivedSubSequenceOf(); VarInfo supervar_super = supervar.isDerivedSubSequenceOf(); if (subvar_super != null && subvar_super == supervar_super) { // both sequences are derived from the same supersequence if ((subvar.derived instanceof SequenceScalarSubsequence || subvar.derived instanceof SequenceScalarArbitrarySubsequence) && (supervar.derived instanceof SequenceScalarSubsequence || supervar.derived instanceof SequenceScalarArbitrarySubsequence)) { VarInfo sub_left_var = null, sub_right_var = null, super_left_var = null, super_right_var = null; // I'm careful not to access foo_shift unless foo_var has been set // to a non-null value, but Java is too stupid to recognize that. int sub_left_shift = 42, sub_right_shift = 69, super_left_shift = 1492, super_right_shift = 1776; if (subvar.derived instanceof SequenceScalarSubsequence) { SequenceScalarSubsequence sub = (SequenceScalarSubsequence) subvar.derived; if (sub.from_start) { sub_right_var = sub.sclvar(); sub_right_shift = sub.index_shift; } else { sub_left_var = sub.sclvar(); sub_left_shift = sub.index_shift; } } else if (subvar.derived instanceof SequenceScalarArbitrarySubsequence) { SequenceScalarArbitrarySubsequence sub = (SequenceScalarArbitrarySubsequence) subvar.derived; sub_left_var = sub.startvar(); sub_left_shift = (sub.left_closed ? 0 : 1); sub_right_var = sub.endvar(); sub_right_shift = (sub.right_closed ? 0 : -1); } else { Assert.assertTrue(false); } if (supervar.derived instanceof SequenceScalarSubsequence) { SequenceScalarSubsequence super_ = (SequenceScalarSubsequence) supervar.derived; if (super_.from_start) { super_right_var = super_.sclvar(); super_right_shift = super_.index_shift; } else { super_left_var = super_.sclvar(); super_left_shift = super_.index_shift; } } else if (supervar.derived instanceof SequenceScalarArbitrarySubsequence) { SequenceScalarArbitrarySubsequence super_ = (SequenceScalarArbitrarySubsequence) supervar.derived; super_left_var = super_.startvar(); super_left_shift = (super_.left_closed ? 0 : 1); super_right_var = super_.endvar(); super_right_shift = (super_.right_closed ? 0 : -1); } else { Assert.assertTrue(false); } boolean left_included, right_included; if (super_left_var == null) left_included = true; else if (sub_left_var == null) // we know super_left_var != null here left_included = false; else left_included = VarInfo.compare_vars( super_left_var, super_left_shift, sub_left_var, sub_left_shift, true /* <= */); if (super_right_var == null) right_included = true; else if (sub_right_var == null) // we know super_right_var != null here right_included = false; else right_included = VarInfo.compare_vars( super_right_var, super_right_shift, sub_right_var, sub_right_shift, false /* >= */); // System.out.println("Is " + subvar.name() + " contained in " // + supervar.name() // + "? left: " + left_included + ", right: " // + right_included); if (left_included && right_included) { inv.log("ObvSubSeq- True a[0..i] subseq a[0..j] and i < j"); return true; } } else if ((subvar.derived instanceof SequenceStringSubsequence) && (supervar.derived instanceof SequenceStringSubsequence)) { // Copied from just above SequenceStringSubsequence sss1 = (SequenceStringSubsequence) subvar.derived; SequenceStringSubsequence sss2 = (SequenceStringSubsequence) supervar.derived; VarInfo index1 = sss1.sclvar(); int shift1 = sss1.index_shift; boolean start1 = sss1.from_start; VarInfo index2 = sss2.sclvar(); int shift2 = sss2.index_shift; boolean start2 = sss2.from_start; if (start1 == start2) if (VarInfo.compare_vars(index1, shift1, index2, shift2, start1)) { inv.log("True from comparing indices"); return true; } } else { Assert.assertTrue( false, "how can this happen? " + subvar.name() + " " + subvar.derived.getClass() + " " + supervar.name() + " " + supervar.derived.getClass()); } } // Also need to check A[0..i] subseq A[0..j] via compare_vars. // A subseq B[0..n] => A subseq B List<Derivation> derivees = supervar.derivees(); // For each variable derived from supervar ("B") for (Derivation der : derivees) { // System.out.println(" ... der = " + der.getVarInfo().name() + " " + der); if (der instanceof SequenceScalarSubsequence) { // If that variable is "B[0..n]" VarInfo supervar_part = der.getVarInfo(); // Get the canonical version; being equal to it is good enough. if (supervar_part.get_equalitySet_leader() == subvar) { Debug.log(debug, inv.getClass(), inv.ppt, vis, "ObvSubSeq- True from canonical leader"); return true; } if (supervar_part.isCanonical()) { if (subvar == supervar_part) { System.err.println( "Error: variables " + subvar.name() + " and " + supervar_part.name() + " are identical. Canonical"); System.err.println(subvar.isCanonical()); System.err.println(supervar_part.isCanonical()); throw new Error(); } // Check to see if there is a subsequence over the supervar if (ppt_parent.is_subsequence(subvar, supervar_part)) { if (Debug.logOn()) inv.log( "ObvSubSeq- true from A subseq B[0..n] " + subvar.name() + "/" + supervar_part.name()); return (true); } } } } return false; }
/** * @return Array "a" such that a[0] is a valid discardCode and a[1] is a valid discardString. If * the Invariant is not an obvious subsequence, both are null */ public static Object[] isObviousSubSequence(VarInfo subvar, VarInfo supervar) { // Must typecheck since this could be called with non sequence variables in // some methods. ProglangType rep1 = subvar.rep_type; ProglangType rep2 = supervar.rep_type; if (!(((rep1 == ProglangType.INT_ARRAY) && (rep2 == ProglangType.INT_ARRAY)) || ((rep1 == ProglangType.DOUBLE_ARRAY) && (rep2 == ProglangType.DOUBLE_ARRAY)) || ((rep1 == ProglangType.STRING_ARRAY) && (rep2 == ProglangType.STRING_ARRAY)))) { return new Object[] {null, null}; } if (debug.isLoggable(Level.FINE)) { debug.fine("isObviousSubSequence " + subvar.name() + "in " + supervar.name()); } // Standard discard reason/string DiscardCode discardCode = DiscardCode.obvious; String discardString = subvar.name() + " obvious subset/subsequence of " + supervar.name(); // For unions and intersections, it probably doesn't make sense to // do subsequence or subset detection. This is mainly to prevent // invariants of the form (x subset of union(x, y)) but this means // we also miss those of the form (z subset of union(x,y)) which // might be useful. Subsequence, however, seems totally useless // on unions and intersections. if (supervar.derived instanceof SequenceScalarIntersection || supervar.derived instanceof SequenceScalarUnion || subvar.derived instanceof SequenceScalarIntersection || subvar.derived instanceof SequenceScalarUnion) { discardCode = DiscardCode.obvious; discardString = "Invariants involving subsets/subsequences of unions/intersections" + "are suppressed"; debug.fine(" returning true because of union or intersection"); return new Object[] {discardCode, discardString}; } if (subvar.derived instanceof SequencesPredicate) { // It's not useful that predicate(x[], b[]) is a subsequence or subset // of x[] SequencesPredicate derived = (SequencesPredicate) subvar.derived; if (derived.var1().equals(supervar)) { discardCode = DiscardCode.obvious; discardString = subvar.name() + " is derived from " + supervar.name(); debug.fine(" returning true because of predicate slicing"); return new Object[] {discardCode, discardString + " [pred slicing]"}; } } VarInfo subvar_super = subvar.isDerivedSubSequenceOf(); if (subvar_super == null) { // If it's not a union, intersection or a subsequence, it's not obvious debug.fine(" returning false because subvar_super == null"); return new Object[] {null, null}; } if (subvar_super == supervar) { // System.out.println("SubSequence.isObviousDerived(" + subvar.name() + ", " + supervar.name + // ") = true"); // System.out.println(" details: subvar_super=" + subvar_super.name + "; supervar_super=" + // supervar.isDerivedSubSequenceOf() == null ? "null" : // supervar.isDerivedSubSequenceOf().name); discardCode = DiscardCode.obvious; discardString = subvar.name() + "==" + supervar.name(); debug.fine(" returning true because subvar_super == supervar"); return new Object[] {discardCode, discardString + " [subvar_super == supervar]"}; } // a[i+a..j+b] cmp a[i+c..j+d] VarInfo supervar_super = supervar.isDerivedSubSequenceOf(); // we know subvar_super != null due to check above if (subvar_super == supervar_super) { // both sequences are derived from the same supersequence if ((subvar.derived instanceof SequenceScalarSubsequence || subvar.derived instanceof SequenceScalarArbitrarySubsequence) && (supervar.derived instanceof SequenceScalarSubsequence || supervar.derived instanceof SequenceScalarArbitrarySubsequence)) { // In "A[i..j] subseq B[k..l]": i=sub_left_var, j=sub_right_var, // k=super_left_var, l=super_right_var. VarInfo sub_left_var = null, sub_right_var = null, super_left_var = null, super_right_var = null; // I'm careful not to access foo_shift unless foo_var has been set // to a non-null value, but Java is too stupid to recognize that. int sub_left_shift = 42, sub_right_shift = 69, super_left_shift = 1492, super_right_shift = 1776; if (subvar.derived instanceof SequenceScalarSubsequence) { SequenceScalarSubsequence sub = (SequenceScalarSubsequence) subvar.derived; if (sub.from_start) { sub_right_var = sub.sclvar(); sub_right_shift = sub.index_shift; } else { sub_left_var = sub.sclvar(); sub_left_shift = sub.index_shift; } } else if (subvar.derived instanceof SequenceScalarArbitrarySubsequence) { SequenceScalarArbitrarySubsequence sub = (SequenceScalarArbitrarySubsequence) subvar.derived; sub_left_var = sub.startvar(); sub_left_shift = (sub.left_closed ? 0 : 1); sub_right_var = sub.endvar(); sub_right_shift = (sub.right_closed ? 0 : -1); } else { Assert.assertTrue(false); } if (supervar.derived instanceof SequenceScalarSubsequence) { SequenceScalarSubsequence super_ = (SequenceScalarSubsequence) supervar.derived; if (super_.from_start) { super_right_var = super_.sclvar(); super_right_shift = super_.index_shift; } else { super_left_var = super_.sclvar(); super_left_shift = super_.index_shift; } } else if (supervar.derived instanceof SequenceScalarArbitrarySubsequence) { SequenceScalarArbitrarySubsequence super_ = (SequenceScalarArbitrarySubsequence) supervar.derived; super_left_var = super_.startvar(); super_left_shift = (super_.left_closed ? 0 : 1); super_right_var = super_.endvar(); super_right_shift = (super_.right_closed ? 0 : -1); } else { Assert.assertTrue(false); } boolean left_included = false, right_included = false; if (super_left_var == null) left_included = true; if (super_left_var == sub_left_var) { if (super_left_shift < sub_left_shift) left_included = true; } if (super_right_var == null) right_included = true; if (super_right_var == sub_right_var) { if (super_right_shift > sub_right_shift) right_included = true; } if (left_included && right_included) { discardCode = DiscardCode.obvious; discardString = subvar.name() + " obvious subset/subsequence of " + supervar.name(); return new Object[] {discardCode, discardString + " [obvious]"}; } } else if ((subvar.derived instanceof SequenceStringSubsequence) && (supervar.derived instanceof SequenceStringSubsequence)) { // Copied from (an old version) just above // XXX I think this code is dead; why isn't it just produced // from the above by macro expansion? -smcc SequenceStringSubsequence sss1 = (SequenceStringSubsequence) subvar.derived; SequenceStringSubsequence sss2 = (SequenceStringSubsequence) supervar.derived; VarInfo index1 = sss1.sclvar(); int shift1 = sss1.index_shift; boolean start1 = sss1.from_start; VarInfo index2 = sss2.sclvar(); int shift2 = sss2.index_shift; boolean start2 = sss2.from_start; if (index1 == index2) { if (start1 == true && start2 == true) { if (shift1 <= shift2) return new Object[] {discardCode, discardString + " [shift1]"}; } else if (start1 == false && start2 == false) { if (shift1 >= shift2) return new Object[] {discardCode, discardString + " [shift2]"}; } } } else { Assert.assertTrue( false, "how can this happen? " + subvar.name() + " " + subvar.derived.getClass() + " " + supervar.name() + " " + supervar.derived.getClass()); } } return new Object[] {null, null}; }
public String format_esc() { String[] form = VarInfo.esc_quantify(false, var(), var()); return form[0] + "(" + form[1] + " == " + form[2] + ")" + form[3]; }
public String format_esc() { String[] form = VarInfo.esc_quantify(false, var(), var()); return form[0] + "((i+1 == j) ==> (" + form[1] + " < " + form[2] + "))" + form[3]; }
/** * Extract consequents from a implications at a single program point. It only searches for top * level Program points because Implications are produced only at those points. */ public static void extract_consequent_maybe(PptTopLevel ppt, PptMap all_ppts) { ppt.simplify_variable_names(); List<Invariant> invs = new ArrayList<Invariant>(); if (invs.size() > 0) { String pptname = cleanup_pptname(ppt.name()); for (Invariant maybe_as_inv : invs) { Implication maybe = (Implication) maybe_as_inv; // don't print redundant invariants. if (Daikon.suppress_redundant_invariants_with_simplify && maybe.ppt.parent.redundant_invs.contains(maybe)) { continue; } // don't print out invariants with min(), max(), or sum() variables boolean mms = false; VarInfo[] varbls = maybe.ppt.var_infos; for (int v = 0; !mms && v < varbls.length; v++) { mms |= varbls[v].isDerivedSequenceMinMaxSum(); } if (mms) { continue; } if (maybe.ppt.parent.ppt_name.isExitPoint()) { for (int i = 0; i < maybe.ppt.var_infos.length; i++) { VarInfo vi = maybe.ppt.var_infos[i]; if (vi.isDerivedParam()) { continue; } } } Invariant consequent = maybe.consequent(); Invariant predicate = maybe.predicate(); Invariant inv, cluster_inv; boolean cons_uses_cluster = false, pred_uses_cluster = false; // extract the consequent (predicate) if the predicate // (consequent) uses the variable "cluster". Ignore if they // both depend on "cluster" if (consequent.usesVarDerived("cluster")) cons_uses_cluster = true; if (predicate.usesVarDerived("cluster")) pred_uses_cluster = true; if (!(pred_uses_cluster ^ cons_uses_cluster)) { continue; } else if (pred_uses_cluster) { inv = consequent; cluster_inv = predicate; } else { inv = predicate; cluster_inv = consequent; } if (!inv.isInteresting()) { continue; } if (!inv.isWorthPrinting()) { continue; } if (contains_constant_non_012(inv)) { continue; } // filter out unwanted invariants // 1) Invariants involving sequences if (inv instanceof daikon.inv.binary.twoSequence.TwoSequence || inv instanceof daikon.inv.binary.sequenceScalar.SequenceScalar || inv instanceof daikon.inv.binary.sequenceString.SequenceString || inv instanceof daikon.inv.unary.sequence.SingleSequence || inv instanceof daikon.inv.unary.stringsequence.SingleStringSequence) { continue; } if (inv instanceof daikon.inv.ternary.threeScalar.LinearTernary || inv instanceof daikon.inv.binary.twoScalar.LinearBinary) { continue; } String inv_string = inv.format_using(OutputFormat.JAVA); if (orig_pattern.matcher(inv_string).find() || dot_class_pattern.matcher(inv_string).find()) { continue; } String fake_inv_string = simplify_inequalities(inv_string); HashedConsequent real = new HashedConsequent(inv, null); if (!fake_inv_string.equals(inv_string)) { // For instance, inv_string is "x != y", fake_inv_string is "x == y" HashedConsequent fake = new HashedConsequent(inv, inv_string); boolean added = store_invariant( cluster_inv.format_using(OutputFormat.JAVA), fake_inv_string, fake, pptname); if (!added) { // We couldn't add "x == y", (when we're "x != y") because // it already exists; so don't add "x == y" either. continue; } } store_invariant(cluster_inv.format_using(OutputFormat.JAVA), inv_string, real, pptname); } } }
private void add(PptTopLevel ppt, ValueTuple vt) { // Add the sample to any splitters if (ppt.has_splitters()) { for (PptSplitter ppt_split : ppt.splitters) { PptConditional ppt_cond = ppt_split.choose_conditional(vt); if (ppt_cond != null) add(ppt_cond, vt); else debug.fine(": sample doesn't pick conditional"); } } // if this is a numbered exit, apply to the combined exit as well if (!(ppt instanceof PptConditional) && ppt.ppt_name.isNumberedExitPoint()) { PptTopLevel parent = all_ppts.get(ppt.ppt_name.makeExit()); if (parent != null) { parent.get_missingOutOfBounds(ppt, vt); add(parent, vt); } } // If the point has no variables, skip it if (ppt.var_infos.length == 0) return; // We should have received sample here before, or there is nothing // to check. // Yoav added: It can be that the different dtrace and inv files have different program points if (false && ppt.num_samples() <= 0) Assert.assertTrue( ppt.num_samples() > 0, "ppt " + ppt.name + " has 0 samples and " + ppt.var_infos.length + " variables"); // Loop through each slice slice_loop: for (Iterator<PptSlice> i = ppt.views_iterator(); i.hasNext(); ) { PptSlice slice = i.next(); if (debug_detail.isLoggable(Level.FINE)) debug_detail.fine( ": processing slice " + slice + "vars: " + Debug.toString(slice.var_infos, vt)); // If any variables are missing, skip this slice for (int j = 0; j < slice.var_infos.length; j++) { VarInfo v = slice.var_infos[j]; int mod = vt.getModified(v); if (v.isMissing(vt)) { if (debug_detail.isLoggable(Level.FINE)) debug_detail.fine(": : Skipping slice, " + v.name() + " missing"); continue slice_loop; } if (v.missingOutOfBounds()) { if (debug_detail.isLoggable(Level.FINE)) debug.fine(": : Skipping slice, " + v.name() + " out of bounds"); continue slice_loop; } } // Loop through each invariant for (Invariant inv : slice.invs) { if (debug_detail.isLoggable(Level.FINE)) debug_detail.fine(": : Processing invariant: " + inv); if (!inv.isActive()) { if (debug_detail.isLoggable(Level.FINE)) debug_detail.fine(": : skipped non-active " + inv); continue; } // Yoav added if (!activeInvariants.contains(inv)) { // System.out.printf ("skipping invariant %s:%s\n", inv.ppt.name(), // inv.format()); continue; } // String invRep = invariant2str(ppt, inv); testedInvariants.add(inv); InvariantStatus status = inv.add_sample(vt, 1); sample_cnt++; if (status != InvariantStatus.NO_CHANGE) { LineNumberReader lnr = FileIO.data_trace_state.reader; String line = (lnr == null) ? "?" : String.valueOf(lnr.getLineNumber()); if (!quiet) { output_stream.println( "At ppt " + ppt.name + ", Invariant '" + inv.format() + "' invalidated by sample " + Debug.toString(slice.var_infos, vt) + "at line " + line + " in file " + FileIO.data_trace_state.filename); } failedInvariants.add(inv); activeInvariants.remove(inv); error_cnt++; } } } }
/** Determines if the variable represented by varInfo is a "this" variable. */ private static boolean isThisVar(VarInfo varInfo) { return varInfo.isThis(); }
/** * Determines if the variable represented by varInfo is a "size" variable. * * @param varInfo the VarInfo of the variable being tested. * @return true iff varInfo is a "size" variable. */ private static boolean isSizeVar(VarInfo varInfo) { return varInfo.is_size(); }
/** * Determines if the variable represented by varInfo is a ".getClass()" variable. * * @param varInfo the VarInfo of the variable being tested. * @return true iff varInfo is a ".getClass()" variable. */ private static boolean isTypeOfVar(VarInfo varInfo) { return varInfo.has_typeof(); }