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authorGravatar tabarbe <unknown>2010-07-28 22:18:03 +0000
committerGravatar tabarbe <unknown>2010-07-28 22:18:03 +0000
commit1f7016e583f2264340385b480a4507e35133669d (patch)
tree7cd577156d94170f74eb2e253c7bb60abc15f7c5 /Source/VCGeneration/VC.cs
parent85ccac1149dc04f6cb1bdc5bb39c8c2e40d000d7 (diff)
Boogie\VCGeneration: Renaming sources in preparation for my addition of the ported C# version
Diffstat (limited to 'Source/VCGeneration/VC.cs')
-rw-r--r--Source/VCGeneration/VC.cs4340
1 files changed, 4340 insertions, 0 deletions
diff --git a/Source/VCGeneration/VC.cs b/Source/VCGeneration/VC.cs
new file mode 100644
index 00000000..0f42939d
--- /dev/null
+++ b/Source/VCGeneration/VC.cs
@@ -0,0 +1,4340 @@
+//-----------------------------------------------------------------------------
+//
+// Copyright (C) Microsoft Corporation. All Rights Reserved.
+//
+//-----------------------------------------------------------------------------
+using System;
+using System.Collections;
+using System.Collections.Generic;
+using System.Diagnostics;
+using System.Threading;
+using System.IO;
+using Microsoft.Boogie;
+using Graphing;
+using AI = Microsoft.AbstractInterpretationFramework;
+using Microsoft.Contracts;
+using Microsoft.Basetypes;
+using Microsoft.Boogie.VCExprAST;
+
+
+namespace VC
+{
+ using Bpl = Microsoft.Boogie;
+
+ public class VCGen : ConditionGeneration
+ {
+
+ /// <summary>
+ /// Constructor. Initializes the theorem prover.
+ /// </summary>
+ [NotDelayed]
+ public VCGen(Program! program, string/*?*/ logFilePath, bool appendLogFile)
+ // throws ProverException
+ {
+ this.appendLogFile = appendLogFile;
+ this.logFilePath = logFilePath;
+ implName2LazyInliningInfo = new Dictionary<string!, LazyInliningInfo!>();
+ implName2StratifiedInliningInfo = new Dictionary<string!, StratifiedInliningInfo!>();
+ base(program);
+ if (CommandLineOptions.Clo.LazyInlining > 0)
+ {
+ this.GenerateVCsForLazyInlining(program);
+ }
+ if (CommandLineOptions.Clo.StratifiedInlining > 0)
+ {
+
+ this.GenerateVCsForStratifiedInlining(program);
+
+ }
+ // base();
+ }
+
+ private static AssumeCmd! AssertTurnedIntoAssume(AssertCmd! assrt)
+ {
+ Expr! expr = assrt.Expr;
+
+ switch (Wlp.Subsumption(assrt)) {
+ case CommandLineOptions.SubsumptionOption.Never:
+ expr = Expr.True;
+ break;
+ case CommandLineOptions.SubsumptionOption.Always:
+ break;
+ case CommandLineOptions.SubsumptionOption.NotForQuantifiers:
+ if (expr is QuantifierExpr) {
+ expr = Expr.True;
+ }
+ break;
+ default:
+ assert false; // unexpected case
+ }
+
+ return new AssumeCmd(assrt.tok, expr);
+ }
+
+ #region LazyInlining
+ public class LazyInliningInfo {
+ public Implementation! impl;
+ public int uniqueId;
+ public Function! function;
+ public Variable! controlFlowVariable;
+ public List<Variable!>! interfaceVars;
+ public Expr! assertExpr;
+ public VCExpr vcexpr;
+ public Dictionary<Incarnation, Absy!> incarnationOriginMap;
+ public Hashtable /*Variable->Expr*/ exitIncarnationMap;
+ public Hashtable /*GotoCmd->returnCmd*/ gotoCmdOrigins;
+ public Hashtable/*<int, Absy!>*/ label2absy;
+
+ public LazyInliningInfo(Implementation! impl, Program! program, int uniqueId)
+ {
+ this.impl = impl;
+ this.uniqueId = uniqueId;
+ this.controlFlowVariable = new LocalVariable(Token.NoToken, new TypedIdent(Token.NoToken, "cfc", Microsoft.Boogie.Type.Int));
+
+ Procedure! proc = (!)impl.Proc;
+ List<Variable!>! interfaceVars = new List<Variable!>();
+ Expr! assertExpr = new LiteralExpr(Token.NoToken, true);
+ foreach (Variable! v in program.GlobalVariables())
+ {
+ interfaceVars.Add(v);
+ }
+ // InParams must be obtained from impl and not proc
+ foreach (Variable! v in impl.InParams)
+ {
+ interfaceVars.Add(v);
+ }
+ // OutParams must be obtained from impl and not proc
+ foreach (Variable! v in impl.OutParams)
+ {
+ Constant c = new Constant(Token.NoToken,
+ new TypedIdent(Token.NoToken, impl.Name + "_" + v.Name, v.TypedIdent.Type));
+ interfaceVars.Add(c);
+ Expr eqExpr = Expr.Eq(new IdentifierExpr(Token.NoToken, c), new IdentifierExpr(Token.NoToken, v));
+ assertExpr = Expr.And(assertExpr, eqExpr);
+ }
+ foreach (IdentifierExpr! e in proc.Modifies)
+ {
+ if (e.Decl == null) continue;
+ Variable! v = e.Decl;
+ Constant c = new Constant(Token.NoToken,
+ new TypedIdent(Token.NoToken, impl.Name + "_" + v.Name, v.TypedIdent.Type));
+ interfaceVars.Add(c);
+ Expr eqExpr = Expr.Eq(new IdentifierExpr(Token.NoToken, c), new IdentifierExpr(Token.NoToken, v));
+ assertExpr = Expr.And(assertExpr, eqExpr);
+ }
+ this.interfaceVars = interfaceVars;
+ this.assertExpr = Expr.Not(assertExpr);
+ VariableSeq! functionInterfaceVars = new VariableSeq();
+ foreach (Variable! v in interfaceVars)
+ {
+ functionInterfaceVars.Add(new Formal(Token.NoToken, new TypedIdent(Token.NoToken, v.Name, v.TypedIdent.Type), true));
+ }
+ TypedIdent! ti = new TypedIdent(Token.NoToken, "", Microsoft.Boogie.Type.Bool);
+ Formal! returnVar = new Formal(Token.NoToken, ti, false);
+ this.function = new Function(Token.NoToken, proc.Name, functionInterfaceVars, returnVar);
+ }
+ }
+
+ private Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo;
+
+ public void GenerateVCsForLazyInlining(Program! program)
+ {
+ Checker! checker = FindCheckerFor(null, CommandLineOptions.Clo.ProverKillTime);
+ foreach (Declaration! decl in program.TopLevelDeclarations)
+ {
+ Implementation impl = decl as Implementation;
+ if (impl == null) continue;
+ Procedure! proc = (!)impl.Proc;
+ if (proc.FindExprAttribute("inline") != null) {
+ LazyInliningInfo info = new LazyInliningInfo(impl, program, QuantifierExpr.GetNextSkolemId());
+ implName2LazyInliningInfo[impl.Name] = info;
+ impl.LocVars.Add(info.controlFlowVariable);
+ ExprSeq! exprs = new ExprSeq();
+ foreach (Variable! v in program.GlobalVariables())
+ {
+ exprs.Add(new OldExpr(Token.NoToken, new IdentifierExpr(Token.NoToken, v)));
+ }
+ foreach (Variable! v in proc.InParams)
+ {
+ exprs.Add(new IdentifierExpr(Token.NoToken, v));
+ }
+ foreach (Variable! v in proc.OutParams)
+ {
+ exprs.Add(new IdentifierExpr(Token.NoToken, v));
+ }
+ foreach (IdentifierExpr! ie in proc.Modifies)
+ {
+ if (ie.Decl == null) continue;
+ exprs.Add(ie);
+ }
+ Expr freePostExpr = new NAryExpr(Token.NoToken, new FunctionCall(info.function), exprs);
+ proc.Ensures.Add(new Ensures(true, freePostExpr));
+ }
+ }
+
+ foreach (LazyInliningInfo! info in implName2LazyInliningInfo.Values)
+ {
+ GenerateVCForLazyInlining(program, info, checker);
+ }
+ }
+
+ private void GenerateVCForLazyInlining(Program! program, LazyInliningInfo! info, Checker! checker)
+ requires info.impl != null;
+ requires info.impl.Proc != null;
+ {
+ Implementation! impl = info.impl;
+ ConvertCFG2DAG(impl, program);
+ info.gotoCmdOrigins = PassifyImpl(impl, program);
+ assert info.exitIncarnationMap != null;
+ Hashtable/*<int, Absy!>*/! label2absy;
+ VCExpressionGenerator! gen = checker.VCExprGen;
+ VCExpr! vcexpr = gen.Not(GenerateVC(impl, info.controlFlowVariable, out label2absy, checker));
+ info.label2absy = label2absy;
+
+ Boogie2VCExprTranslator! translator = checker.TheoremProver.Context.BoogieExprTranslator;
+ List<VCExprVar!> privateVars = new List<VCExprVar!>();
+ foreach (Variable! v in impl.LocVars)
+ {
+ privateVars.Add(translator.LookupVariable(v));
+ }
+ foreach (Variable! v in impl.OutParams)
+ {
+ privateVars.Add(translator.LookupVariable(v));
+ }
+ if (privateVars.Count > 0)
+ {
+ vcexpr = gen.Exists(new List<TypeVariable!>(), privateVars, new List<VCTrigger!>(),
+ new VCQuantifierInfos(impl.Name, info.uniqueId, false, null), vcexpr);
+ }
+
+ List<VCExprVar!> interfaceExprVars = new List<VCExprVar!>();
+ List<VCExpr!> interfaceExprs = new List<VCExpr!>();
+ foreach (Variable! v in info.interfaceVars)
+ {
+ VCExprVar! ev = translator.LookupVariable(v);
+ interfaceExprVars.Add(ev);
+ interfaceExprs.Add(ev);
+ }
+
+ Function! function = (!)info.function;
+ VCExpr! expr = gen.Function(function, interfaceExprs);
+ if (CommandLineOptions.Clo.LazyInlining == 1) {
+ vcexpr = gen.Implies(expr, vcexpr);
+ } else {
+ assert CommandLineOptions.Clo.LazyInlining == 2;
+ vcexpr = gen.Eq(expr, vcexpr);
+ }
+
+ List<VCTrigger!> triggers = new List<VCTrigger!>();
+ List<VCExpr!> exprs = new List<VCExpr!>();
+ exprs.Add(expr);
+ VCTrigger! trigger = new VCTrigger(true, exprs);
+ triggers.Add(trigger);
+
+ Expr e = new LiteralExpr(Token.NoToken, BigNum.FromInt(1));
+ QKeyValue q = new QKeyValue(Token.NoToken, "weight", new List<object!>(new object![] { e }), null);
+ interfaceExprVars.Reverse();
+ vcexpr = gen.Forall(new List<TypeVariable!>(), interfaceExprVars, triggers,
+ new VCQuantifierInfos(impl.Name, QuantifierExpr.GetNextSkolemId(), false, q), vcexpr);
+
+ info.vcexpr = vcexpr;
+ checker.TheoremProver.PushVCExpression(vcexpr);
+ }
+ #endregion
+
+ #region StratifiedInlining
+ public class StratifiedInliningInfo : LazyInliningInfo
+ {
+ public int inline_cnt;
+ public List<VCExprVar!>! privateVars;
+ public List<VCExprVar!>! interfaceExprVars;
+ public VCExpr funcExpr;
+ public VCExpr falseExpr;
+
+ public StratifiedInliningInfo(Implementation! impl, Program! program, int uniqueid)
+ : base(impl, program, uniqueid)
+ {
+ inline_cnt = 0;
+ privateVars = new List<VCExprVar!>();
+ interfaceExprVars = new List<VCExprVar!>();
+ }
+
+ }
+
+ private Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo;
+
+ public void GenerateVCsForStratifiedInlining(Program! program)
+ {
+ //Checker! checker = FindCheckerFor(null, CommandLineOptions.Clo.ProverKillTime);
+ foreach (Declaration! decl in program.TopLevelDeclarations)
+ {
+ Implementation impl = decl as Implementation;
+ if (impl == null) continue;
+ Procedure! proc = (!)impl.Proc;
+ if (proc.FindExprAttribute("inline") != null) {
+ StratifiedInliningInfo info = new StratifiedInliningInfo(impl, program, QuantifierExpr.GetNextSkolemId());
+ implName2StratifiedInliningInfo[impl.Name] = info;
+ // We don't need controlFlowVariable for stratified Inlining
+ //impl.LocVars.Add(info.controlFlowVariable);
+ ExprSeq! exprs = new ExprSeq();
+ foreach (Variable! v in program.GlobalVariables())
+ {
+ exprs.Add(new OldExpr(Token.NoToken, new IdentifierExpr(Token.NoToken, v)));
+ }
+ foreach (Variable! v in proc.InParams)
+ {
+ exprs.Add(new IdentifierExpr(Token.NoToken, v));
+ }
+ foreach (Variable! v in proc.OutParams)
+ {
+ exprs.Add(new IdentifierExpr(Token.NoToken, v));
+ }
+ foreach (IdentifierExpr! ie in proc.Modifies)
+ {
+ if (ie.Decl == null) continue;
+ exprs.Add(ie);
+ }
+ Expr freePostExpr = new NAryExpr(Token.NoToken, new FunctionCall(info.function), exprs);
+ proc.Ensures.Add(new Ensures(true, freePostExpr));
+ }
+ }
+
+ }
+
+ private void GenerateVCForStratifiedInlining(Program! program, StratifiedInliningInfo! info, Checker! checker)
+ requires info.impl != null;
+ requires info.impl.Proc != null;
+ {
+ Implementation! impl = info.impl;
+ ConvertCFG2DAG(impl, program);
+ info.gotoCmdOrigins = PassifyImpl(impl, program);
+ assert info.exitIncarnationMap != null;
+ Hashtable/*<int, Absy!>*/! label2absy;
+ VCExpressionGenerator! gen = checker.VCExprGen;
+ VCExpr! vcexpr = gen.Not(GenerateVC(impl, null, out label2absy, checker));
+ info.label2absy = label2absy;
+
+ Boogie2VCExprTranslator! translator = checker.TheoremProver.Context.BoogieExprTranslator;
+ info.privateVars = new List<VCExprVar!>();
+ foreach (Variable! v in impl.LocVars)
+ {
+ info.privateVars.Add(translator.LookupVariable(v));
+ }
+ foreach (Variable! v in impl.OutParams)
+ {
+ info.privateVars.Add(translator.LookupVariable(v));
+ }
+
+ info.interfaceExprVars = new List<VCExprVar!>();
+ List<VCExpr!> interfaceExprs = new List<VCExpr!>();
+ foreach (Variable! v in info.interfaceVars)
+ {
+ VCExprVar! ev = translator.LookupVariable(v);
+ info.interfaceExprVars.Add(ev);
+ interfaceExprs.Add(ev);
+ }
+
+ Function! function = (!)info.function;
+ info.funcExpr = gen.Function(function, interfaceExprs);
+ info.vcexpr = vcexpr;
+
+ // Build the "false" expression: forall a b c: foo(a,b,c) <==> false
+
+ info.falseExpr = gen.Eq(info.funcExpr, VCExpressionGenerator.False);
+
+ List<VCTrigger!> triggers = new List<VCTrigger!>();
+ List<VCExpr!> exprs = new List<VCExpr!>();
+ exprs.Add(info.funcExpr);
+ VCTrigger! trigger = new VCTrigger(true, exprs);
+ triggers.Add(trigger);
+
+ Expr e = new LiteralExpr(Token.NoToken, BigNum.FromInt(1));
+ QKeyValue q = new QKeyValue(Token.NoToken, "weight", new List<object!>(new object![] { e }), null);
+ //info.interfaceExprVars.Reverse();
+ info.falseExpr = gen.Forall(new List<TypeVariable!>(), info.interfaceExprVars, triggers,
+ new VCQuantifierInfos(impl.Name, QuantifierExpr.GetNextSkolemId(), false, q), info.falseExpr);
+
+ //checker.TheoremProver.PushVCExpression(vcexpr);
+ /*
+ Console.WriteLine("Procedure: {0}", info.impl.Name);
+ Console.Write("For all: ");
+ foreach(VCExprVar! v in info.interfaceExprVars) {
+ Console.Write(v.ToString() + " ");
+ }
+ Console.WriteLine();
+ Console.Write("There exists: ");
+ foreach(VCExprVar! v in info.privateVars) {
+ Console.Write(v.ToString() + " ");
+ }
+ Console.WriteLine();
+ Console.WriteLine(vcexpr.ToString());
+ */
+ }
+ #endregion
+
+ #region Soundness smoke tester
+ class SmokeTester
+ {
+ VCGen! parent;
+ Implementation! impl;
+ Block! initial;
+ Program! program;
+ int id;
+ Dictionary<Block!, Block!>! copies = new Dictionary<Block!, Block!>();
+ Dictionary<Block!, bool>! visited = new Dictionary<Block!, bool>();
+ VerifierCallback! callback;
+
+ internal SmokeTester(VCGen! par, Implementation! i, Program! prog, VerifierCallback! callback)
+ {
+ parent = par;
+ impl = i;
+ initial = i.Blocks[0];
+ program = prog;
+ this.callback = callback;
+ }
+
+ internal void Copy()
+ {
+ CloneBlock(impl.Blocks[0]);
+ initial = GetCopiedBlocks()[0];
+ }
+
+ internal void Test()
+ throws UnexpectedProverOutputException;
+ {
+ DFS(initial);
+ }
+
+ void TopologicalSortImpl()
+ {
+ Graph<Block> dag = new Graph<Block>();
+ dag.AddSource((!)impl.Blocks[0]); // there is always at least one node in the graph
+ foreach (Block b in impl.Blocks)
+ {
+ GotoCmd gtc = b.TransferCmd as GotoCmd;
+ if (gtc != null)
+ {
+ assume gtc.labelTargets != null;
+ foreach (Block! dest in gtc.labelTargets)
+ {
+ dag.AddEdge(b,dest);
+ }
+ }
+ }
+ impl.Blocks = new List<Block!>();
+ foreach (Block! b in dag.TopologicalSort()) {
+ impl.Blocks.Add(b);
+ }
+ }
+
+ void Emit()
+ {
+ TopologicalSortImpl();
+ EmitImpl(impl, false);
+ }
+
+ // this one copies forward
+ Block! CloneBlock(Block! b)
+ {
+ Block fake_res;
+ if (copies.TryGetValue(b, out fake_res)) {
+ return (!)fake_res;
+ }
+ Block! res;
+ res = new Block(b.tok, b.Label, new CmdSeq(b.Cmds), null);
+ copies[b] = res;
+ if (b.TransferCmd is GotoCmd) {
+ foreach (Block! ch in (!)((GotoCmd)b.TransferCmd).labelTargets) {
+ CloneBlock(ch);
+ }
+ }
+ foreach (Block! p in b.Predecessors) {
+ res.Predecessors.Add(CloneBlock(p));
+ }
+ return res;
+ }
+
+ // this one copies backwards
+ Block! CopyBlock(Block! b)
+ {
+ Block fake_res;
+ if (copies.TryGetValue(b, out fake_res)) {
+ // fake_res should be Block! but the compiler fails
+ return (!)fake_res;
+ }
+ Block! res;
+ CmdSeq seq = new CmdSeq();
+ foreach (Cmd! c in b.Cmds) {
+ AssertCmd turn = c as AssertCmd;
+ if (!turnAssertIntoAssumes || turn == null) {
+ seq.Add(c);
+ } else {
+ seq.Add(AssertTurnedIntoAssume(turn));
+ }
+ }
+ res = new Block(b.tok, b.Label, seq, null);
+ copies[b] = res;
+ foreach (Block! p in b.Predecessors) {
+ res.Predecessors.Add(CopyBlock(p));
+ }
+ return res;
+ }
+
+ List<Block!>! GetCopiedBlocks()
+ {
+ // the order of nodes in res is random (except for the first one, being the entry)
+ List<Block!> res = new List<Block!>();
+ res.Add(copies[initial]);
+
+ foreach (KeyValuePair<Block!,Block!> kv in copies) {
+ GotoCmd go = kv.Key.TransferCmd as GotoCmd;
+ ReturnCmd ret = kv.Key.TransferCmd as ReturnCmd;
+ if (kv.Key != initial) {
+ res.Add(kv.Value);
+ }
+ if (go != null) {
+ GotoCmd copy = new GotoCmd(go.tok, new StringSeq(), new BlockSeq());
+ kv.Value.TransferCmd = copy;
+ foreach (Block! b in (!)go.labelTargets) {
+ Block c;
+ if (copies.TryGetValue(b, out c)) {
+ copy.AddTarget((!)c);
+ }
+ }
+ } else if (ret != null) {
+ kv.Value.TransferCmd = ret;
+ } else {
+ assume false;
+ }
+ }
+
+ copies.Clear();
+
+ return res;
+ }
+
+ // check if e is true, false, !true, !false
+ // if so return true and the value of the expression in val
+ bool BooleanEval(Expr! e, ref bool val)
+ {
+ LiteralExpr lit = e as LiteralExpr;
+ NAryExpr call = e as NAryExpr;
+
+ if (lit != null && lit.isBool) {
+ val = lit.asBool;
+ return true;
+ } else if (call != null &&
+ call.Fun is UnaryOperator &&
+ ((UnaryOperator)call.Fun).Op == UnaryOperator.Opcode.Not &&
+ BooleanEval((!)call.Args[0], ref val)) {
+ val = !val;
+ return true;
+ }
+ // this is for the 0bv32 != 0bv32 generated by vcc
+ else if (call != null &&
+ call.Fun is BinaryOperator &&
+ ((BinaryOperator)call.Fun).Op == BinaryOperator.Opcode.Neq &&
+ call.Args[0] is LiteralExpr &&
+ ((!)call.Args[0]).Equals(call.Args[1]))
+ {
+ val = false;
+ return true;
+ }
+
+ return false;
+ }
+
+ bool IsFalse(Expr! e)
+ {
+ bool val = false;
+ return BooleanEval(e, ref val) && !val;
+ }
+
+ bool CheckUnreachable(Block! cur, CmdSeq! seq)
+ throws UnexpectedProverOutputException;
+ {
+ foreach (Cmd cmd in seq) {
+ AssertCmd assrt = cmd as AssertCmd;
+ if (assrt != null && QKeyValue.FindBoolAttribute(assrt.Attributes, "PossiblyUnreachable"))
+ return false;
+ }
+
+ DateTime start = DateTime.Now;
+ if (CommandLineOptions.Clo.Trace) {
+ System.Console.Write(" soundness smoke test #{0} ... ", id);
+ }
+ callback.OnProgress("smoke", id, id, 0.0);
+
+ Token tok = new Token();
+ tok.val = "soundness smoke test assertion";
+ seq.Add(new AssertCmd(tok, Expr.False));
+ Block! copy = CopyBlock(cur);
+ copy.Cmds = seq;
+ List<Block!>! backup = impl.Blocks;
+ impl.Blocks = GetCopiedBlocks();
+ copy.TransferCmd = new ReturnCmd(Token.NoToken);
+ if (CommandLineOptions.Clo.TraceVerify) {
+ System.Console.WriteLine();
+ System.Console.WriteLine(" --- smoke #{0}, before passify", id);
+ Emit();
+ }
+ parent.current_impl = impl;
+ parent.PassifyImpl(impl, program);
+ Hashtable! label2Absy;
+ Checker! ch = parent.FindCheckerFor(impl, CommandLineOptions.Clo.SmokeTimeout);
+ VCExpr! vc = parent.GenerateVC(impl, null, out label2Absy, ch);
+ impl.Blocks = backup;
+
+ if (CommandLineOptions.Clo.TraceVerify) {
+ System.Console.WriteLine(" --- smoke #{0}, after passify", id);
+ Emit();
+ }
+ ch.BeginCheck((!) impl.Name + "_smoke" + id++, vc, new ErrorHandler(label2Absy, this.callback));
+ ch.ProverDone.WaitOne();
+ ProverInterface.Outcome outcome = ch.ReadOutcome();
+ parent.current_impl = null;
+
+ DateTime end = DateTime.Now;
+ TimeSpan elapsed = end - start;
+ if (CommandLineOptions.Clo.Trace) {
+ System.Console.WriteLine(" [{0} s] {1}", elapsed.TotalSeconds,
+ outcome == ProverInterface.Outcome.Valid ? "OOPS" :
+ "OK" + (outcome == ProverInterface.Outcome.Invalid ? "" : " (" + outcome + ")"));
+ }
+
+ if (outcome == ProverInterface.Outcome.Valid) {
+ // copy it again, so we get the version with calls, assignments and such
+ copy = CopyBlock(cur);
+ copy.Cmds = seq;
+ impl.Blocks = GetCopiedBlocks();
+ TopologicalSortImpl();
+ callback.OnUnreachableCode(impl);
+ impl.Blocks = backup;
+ return true;
+ }
+ return false;
+ }
+
+ const bool turnAssertIntoAssumes = false;
+
+ void DFS(Block! cur)
+ throws UnexpectedProverOutputException;
+ {
+ if (visited.ContainsKey(cur)) return;
+ visited[cur] = true;
+
+ CmdSeq! seq = new CmdSeq();
+ foreach (Cmd! cmd_ in cur.Cmds) {
+ Cmd! cmd = cmd_;
+ AssertCmd assrt = cmd as AssertCmd;
+ AssumeCmd assm = cmd as AssumeCmd;
+ CallCmd call = cmd as CallCmd;
+
+ bool assumeFalse = false;
+
+ if (assrt != null) {
+ // we're not going any further
+ // it's clear the user expected unreachable code here
+ // it's not clear where did he expect it, maybe it would be right to insert
+ // a check just one command before
+ if (IsFalse(assrt.Expr)) return;
+
+ if (turnAssertIntoAssumes) {
+ cmd = AssertTurnedIntoAssume(assrt);
+ }
+ } else if (assm != null) {
+ if (IsFalse(assm.Expr)) assumeFalse = true;
+ } else if (call != null) {
+ foreach (Ensures! e in ((!)call.Proc).Ensures) {
+ if (IsFalse(e.Condition)) assumeFalse = true;
+ }
+ }
+
+ if (assumeFalse) {
+ CheckUnreachable(cur, seq);
+ return;
+ }
+
+ seq.Add(cmd);
+ }
+
+
+ GotoCmd go = cur.TransferCmd as GotoCmd;
+ ReturnCmd ret = cur.TransferCmd as ReturnCmd;
+
+ assume !(go!= null&&go.labelTargets==null&&go.labelNames!=null&&go.labelNames.Length>0) ;
+
+ if (ret != null || (go != null && ((!)go.labelTargets).Length == 0)) {
+ // we end in return, so there will be no more places to check
+ CheckUnreachable(cur, seq);
+ } else if (go != null) {
+ bool needToCheck = true;
+ // if all of our children have more than one parent, then
+ // we're in the right place to check
+ foreach (Block! target in (!)go.labelTargets) {
+ if (target.Predecessors.Length == 1) {
+ needToCheck = false;
+ }
+ }
+ if (needToCheck) {
+ CheckUnreachable(cur, seq);
+ }
+ foreach (Block! target in go.labelTargets) {
+ DFS(target);
+ }
+ }
+ }
+
+ class ErrorHandler : ProverInterface.ErrorHandler {
+ Hashtable! label2Absy;
+ VerifierCallback! callback;
+
+ public ErrorHandler(Hashtable! label2Absy, VerifierCallback! callback) {
+ this.label2Absy = label2Absy;
+ this.callback = callback;
+ }
+
+ public override Absy! Label2Absy(string! label) {
+ int id = int.Parse(label);
+ return (Absy!) label2Absy[id];
+ }
+
+ public override void OnProverWarning(string! msg) {
+ this.callback.OnWarning(msg);
+ }
+ }
+ }
+
+
+ #endregion
+
+ #region Splitter
+ class Split
+ {
+ class BlockStats {
+ public bool big_block;
+ public int id;
+ public double assertion_cost;
+ public double assumption_cost; // before multiplier
+ public double incomming_paths;
+ public List<Block!>! virtual_successors = new List<Block!>();
+ public List<Block!>! virtual_predecesors = new List<Block!>();
+ public Dictionary<Block!,bool>? reachable_blocks;
+ public readonly Block! block;
+
+ public BlockStats(Block! b, int i)
+ {
+ block = b;
+ assertion_cost = -1;
+ id = i;
+ }
+ }
+
+ readonly List<Block!>! blocks;
+ readonly List<Block!>! big_blocks = new List<Block!>();
+ readonly Dictionary<Block!, BlockStats!>! stats = new Dictionary<Block!, BlockStats!>();
+ readonly int id;
+ static int current_id;
+ Block? split_block;
+ bool assert_to_assume;
+ List<Block!>! assumized_branches = new List<Block!>();
+ public AssertCmd? first_assert;
+
+ double score;
+ bool score_computed;
+ double total_cost;
+ int assertion_count;
+ double assertion_cost; // without multiplication by paths
+ Hashtable/*TransferCmd->ReturnCmd*/! gotoCmdOrigins;
+ VCGen! parent;
+ Implementation! impl;
+
+ Dictionary<Block!, Block!>! copies = new Dictionary<Block!, Block!>();
+ bool doing_slice;
+ double slice_initial_limit;
+ double slice_limit;
+ bool slice_pos;
+ Dictionary<Block!, bool>! protected_from_assert_to_assume = new Dictionary<Block!,bool>();
+ Dictionary<Block!, bool>! keep_at_all = new Dictionary<Block!,bool>();
+
+ // async interface
+ private Checker checker;
+ private int splitNo;
+ internal ErrorReporter reporter;
+
+ public Split(List<Block!>! blocks, Hashtable/*TransferCmd->ReturnCmd*/! gotoCmdOrigins, VCGen! par, Implementation! impl)
+ {
+ this.blocks = blocks;
+ this.gotoCmdOrigins = gotoCmdOrigins;
+ this.parent = par;
+ this.impl = impl;
+ this.id = current_id++;
+ }
+
+ public double Cost
+ {
+ get {
+ ComputeBestSplit();
+ return total_cost;
+ }
+ }
+
+ public bool LastChance
+ {
+ get {
+ ComputeBestSplit();
+ return assertion_count == 1 && score < 0;
+ }
+ }
+
+ public string Stats
+ {
+ get {
+ ComputeBestSplit();
+ return string.Format("(cost:{0:0}/{1:0}{2})", total_cost, assertion_cost, LastChance ? " last" : "");
+ }
+ }
+
+ public void DumpDot(int no)
+ {
+ using (System.IO.StreamWriter sw = System.IO.File.CreateText(string.Format("split.{0}.dot", no))) {
+ sw.WriteLine("digraph G {");
+
+ ComputeBestSplit();
+ List<Block!> saved = assumized_branches;
+ assumized_branches = new List<Block!>();
+ DoComputeScore(false);
+ assumized_branches = saved;
+
+ foreach (Block! b in big_blocks) {
+ BlockStats s = GetBlockStats(b);
+ foreach (Block! t in s.virtual_successors) {
+ sw.WriteLine("n{0} -> n{1};", s.id, GetBlockStats(t).id);
+ }
+ sw.WriteLine("n{0} [label=\"{1}:\\n({2:0.0}+{3:0.0})*{4:0.0}\"{5}];",
+ s.id, b.Label,
+ s.assertion_cost, s.assumption_cost, s.incomming_paths,
+ s.assertion_cost > 0 ? ",shape=box" : "");
+
+ }
+ sw.WriteLine("}");
+ sw.Close();
+ }
+
+ string filename = string.Format("split.{0}.bpl", no);
+ using (System.IO.StreamWriter sw = System.IO.File.CreateText(filename)) {
+ int oldPrintUnstructured = CommandLineOptions.Clo.PrintUnstructured;
+ CommandLineOptions.Clo.PrintUnstructured = 2; // print only the unstructured program
+ bool oldPrintDesugaringSetting = CommandLineOptions.Clo.PrintDesugarings;
+ CommandLineOptions.Clo.PrintDesugarings = false;
+ List<Block!> backup = impl.Blocks;
+ impl.Blocks = blocks;
+ impl.Emit(new TokenTextWriter(filename, sw, false), 0);
+ impl.Blocks = backup;
+ CommandLineOptions.Clo.PrintDesugarings = oldPrintDesugaringSetting;
+ CommandLineOptions.Clo.PrintUnstructured = oldPrintUnstructured;
+ }
+ }
+
+ int bsid;
+ BlockStats! GetBlockStats(Block! b)
+ {
+ BlockStats s;
+ if (!stats.TryGetValue(b, out s)) {
+ s = new BlockStats(b, bsid++);
+ stats[b] = s;
+ }
+ return (!)s;
+ }
+
+ double AssertionCost(PredicateCmd c)
+ {
+ return 1.0;
+ }
+
+ void CountAssertions(Block! b)
+ {
+ BlockStats s = GetBlockStats(b);
+ if (s.assertion_cost >= 0) return; // already done
+ s.big_block = true;
+ s.assertion_cost = 0;
+ s.assumption_cost = 0;
+ foreach (Cmd c in b.Cmds) {
+ if (c is AssertCmd) {
+ double cost = AssertionCost((AssertCmd)c);
+ s.assertion_cost += cost;
+ assertion_count++;
+ assertion_cost += cost;
+ } else if (c is AssumeCmd) {
+ s.assumption_cost += AssertionCost((AssumeCmd)c);
+ }
+ }
+ foreach (Block! b in Exits(b)) {
+ s.virtual_successors.Add(b);
+ }
+ if (s.virtual_successors.Count == 1) {
+ Block next = s.virtual_successors[0];
+ BlockStats se = GetBlockStats(next);
+ CountAssertions(next);
+ if (next.Predecessors.Length > 1 || se.virtual_successors.Count != 1) return;
+ s.virtual_successors[0] = se.virtual_successors[0];
+ s.assertion_cost += se.assertion_cost;
+ s.assumption_cost += se.assumption_cost;
+ se.big_block = false;
+ }
+ }
+
+ Dictionary<Block!,bool>! ComputeReachableNodes(Block! b)
+ {
+ BlockStats s = GetBlockStats(b);
+ if (s.reachable_blocks != null) {
+ return s.reachable_blocks;
+ }
+ Dictionary<Block!, bool> blocks = new Dictionary<Block!, bool>();
+ s.reachable_blocks = blocks;
+ blocks[b] = true;
+ foreach (Block! succ in Exits(b)) {
+ foreach (Block! r in ComputeReachableNodes(succ).Keys) {
+ blocks[r] = true;
+ }
+ }
+ return blocks;
+ }
+
+ double ProverCost(double vc_cost)
+ {
+ return vc_cost * vc_cost;
+ }
+
+ void ComputeBestSplit()
+ {
+ if (score_computed) return;
+ score_computed = true;
+
+ assertion_count = 0;
+
+ foreach (Block! b in blocks) {
+ CountAssertions(b);
+ }
+
+ foreach (Block! b in blocks) {
+ BlockStats bs = GetBlockStats(b);
+ if (bs.big_block) {
+ big_blocks.Add(b);
+ foreach (Block! ch in bs.virtual_successors) {
+ BlockStats chs = GetBlockStats(ch);
+ if (!chs.big_block) {
+ Console.WriteLine("non-big {0} accessed from {1}", ch, b);
+ DumpDot(-1);
+ assert false;
+ }
+ chs.virtual_predecesors.Add(b);
+ }
+ }
+ }
+
+ assumized_branches.Clear();
+ total_cost = ProverCost(DoComputeScore(false));
+
+ score = double.PositiveInfinity;
+ Block? best_split = null;
+ List<Block!>! saved_branches = new List<Block!>();
+
+ foreach (Block! b in big_blocks) {
+ GotoCmd gt = b.TransferCmd as GotoCmd;
+ if (gt == null) continue;
+ BlockSeq targ = (!)gt.labelTargets;
+ if (targ.Length < 2) continue;
+ // caution, we only consider two first exits
+
+ double left0, right0, left1, right1;
+ split_block = b;
+
+ assumized_branches.Clear();
+ assumized_branches.Add((!)targ[0]);
+ left0 = DoComputeScore(true);
+ right0 = DoComputeScore(false);
+
+ assumized_branches.Clear();
+ for (int idx = 1; idx < targ.Length; idx++) {
+ assumized_branches.Add((!)targ[idx]);
+ }
+ left1 = DoComputeScore(true);
+ right1 = DoComputeScore(false);
+
+ double current_score = ProverCost(left1) + ProverCost(right1);
+ double other_score = ProverCost(left0) + ProverCost(right0);
+
+ if (other_score < current_score) {
+ current_score = other_score;
+ assumized_branches.Clear();
+ assumized_branches.Add((!)targ[0]);
+ }
+
+ if (current_score < score) {
+ score = current_score;
+ best_split = split_block;
+ saved_branches.Clear();
+ saved_branches.AddRange(assumized_branches);
+ }
+ }
+
+ if (CommandLineOptions.Clo.VcsPathSplitMult * score > total_cost) {
+ split_block = null;
+ score = -1;
+ } else {
+ assumized_branches = saved_branches;
+ split_block = best_split;
+ }
+ }
+
+ void UpdateIncommingPaths(BlockStats! s)
+ {
+ if (s.incomming_paths < 0.0) {
+ int count = 0;
+ s.incomming_paths = 0.0;
+ if (!keep_at_all.ContainsKey(s.block)) return;
+ foreach (Block! b in s.virtual_predecesors) {
+ BlockStats! ch = GetBlockStats(b);
+ UpdateIncommingPaths(ch);
+ if (ch.incomming_paths > 0.0) {
+ s.incomming_paths += ch.incomming_paths;
+ count++;
+ }
+ }
+ if (count > 1) {
+ s.incomming_paths *= CommandLineOptions.Clo.VcsPathJoinMult;
+ }
+ }
+ }
+
+ void ComputeBlockSetsHelper(Block! b, bool allow_small)
+ {
+ if (keep_at_all.ContainsKey(b)) return;
+ keep_at_all[b] = true;
+
+ if (allow_small) {
+ foreach (Block! ch in Exits(b)) {
+ if (b == split_block && assumized_branches.Contains(ch)) continue;
+ ComputeBlockSetsHelper(ch, allow_small);
+ }
+ } else {
+ foreach (Block! ch in GetBlockStats(b).virtual_successors) {
+ if (b == split_block && assumized_branches.Contains(ch)) continue;
+ ComputeBlockSetsHelper(ch, allow_small);
+ }
+ }
+ }
+
+ void ComputeBlockSets(bool allow_small)
+ {
+ protected_from_assert_to_assume.Clear();
+ keep_at_all.Clear();
+
+ Debug.Assert(split_block == null || GetBlockStats(split_block).big_block);
+ Debug.Assert(GetBlockStats(blocks[0]).big_block);
+
+ if (assert_to_assume) {
+ foreach (Block! b in allow_small ? blocks : big_blocks) {
+ if (ComputeReachableNodes(b).ContainsKey((!)split_block)) {
+ keep_at_all[b] = true;
+ }
+ }
+
+ foreach (Block! b in assumized_branches) {
+ foreach (Block! r in ComputeReachableNodes(b).Keys) {
+ if (allow_small || GetBlockStats(r).big_block) {
+ keep_at_all[r] = true;
+ protected_from_assert_to_assume[r] = true;
+ }
+ }
+ }
+ } else {
+ ComputeBlockSetsHelper(blocks[0], allow_small);
+ }
+ }
+
+ bool ShouldAssumize(Block! b)
+ {
+ return assert_to_assume && !protected_from_assert_to_assume.ContainsKey(b);
+ }
+
+ double DoComputeScore(bool aa)
+ {
+ assert_to_assume = aa;
+ ComputeBlockSets(false);
+
+ foreach (Block! b in big_blocks) {
+ GetBlockStats(b).incomming_paths = -1.0;
+ }
+
+ GetBlockStats(blocks[0]).incomming_paths = 1.0;
+
+ double cost = 0.0;
+ foreach (Block! b in big_blocks) {
+ if (keep_at_all.ContainsKey(b)) {
+ BlockStats s = GetBlockStats(b);
+ UpdateIncommingPaths(s);
+ double local = s.assertion_cost;
+ if (ShouldAssumize(b)) {
+ local = (s.assertion_cost + s.assumption_cost) * CommandLineOptions.Clo.VcsAssumeMult;
+ } else {
+ local = s.assumption_cost * CommandLineOptions.Clo.VcsAssumeMult + s.assertion_cost;
+ }
+ local = local + local * s.incomming_paths * CommandLineOptions.Clo.VcsPathCostMult;
+ cost += local;
+ }
+ }
+
+ return cost;
+ }
+
+ CmdSeq! SliceCmds(Block! b)
+ {
+ CmdSeq! seq = b.Cmds;
+ if (!doing_slice && !ShouldAssumize(b)) return seq;
+ CmdSeq! res = new CmdSeq();
+ foreach (Cmd! c in seq) {
+ AssertCmd a = c as AssertCmd;
+ Cmd! the_new = c;
+ bool swap = false;
+ if (a != null) {
+ if (doing_slice) {
+ double cost = AssertionCost(a);
+ bool first = (slice_limit - cost) >= 0 || slice_initial_limit == slice_limit;
+ slice_limit -= cost;
+ swap = slice_pos == first;
+ } else if (assert_to_assume) {
+ swap = true;
+ } else {
+ assert false;
+ }
+
+ if (swap) {
+ the_new = AssertTurnedIntoAssume(a);
+ }
+ }
+ res.Add(the_new);
+ }
+ return res;
+ }
+
+ Block! CloneBlock(Block! b)
+ {
+ Block res;
+ if (copies.TryGetValue(b, out res)) {
+ return (!)res;
+ }
+ res = new Block(b.tok, b.Label, SliceCmds(b), b.TransferCmd);
+ GotoCmd gt = b.TransferCmd as GotoCmd;
+ copies[b] = res;
+ if (gt != null) {
+ GotoCmd newGoto = new GotoCmd(gt.tok, new StringSeq(), new BlockSeq());
+ res.TransferCmd = newGoto;
+ int pos = 0;
+ foreach (Block! ch in (!)gt.labelTargets) {
+ assert doing_slice ||
+ (!assert_to_assume ==> (keep_at_all.ContainsKey(ch) || assumized_branches.Contains(ch)));
+ if (doing_slice ||
+ ((b != split_block || assumized_branches.Contains(ch) == assert_to_assume) &&
+ keep_at_all.ContainsKey(ch))) {
+ newGoto.AddTarget(CloneBlock(ch));
+ }
+ pos++;
+ }
+ }
+ return res;
+ }
+
+ Split! DoSplit()
+ {
+ copies.Clear();
+ CloneBlock(blocks[0]);
+ List<Block!> newBlocks = new List<Block!>();
+ Hashtable newGotoCmdOrigins = new Hashtable();
+ foreach (Block! b in blocks) {
+ Block tmp;
+ if (copies.TryGetValue(b, out tmp)) {
+ newBlocks.Add((!)tmp);
+ if (gotoCmdOrigins.ContainsKey(b)) {
+ newGotoCmdOrigins[tmp] = gotoCmdOrigins[b];
+ }
+
+ foreach (Block! p in b.Predecessors) {
+ Block tmp2;
+ if (copies.TryGetValue(p, out tmp2)) {
+ tmp.Predecessors.Add(tmp2);
+ }
+ }
+ }
+ }
+
+ return new Split(newBlocks, newGotoCmdOrigins, parent, impl);
+ }
+
+ Split! SplitAt(int idx)
+ {
+ assert_to_assume = idx == 0;
+ doing_slice = false;
+ ComputeBlockSets(true);
+
+ return DoSplit();
+ }
+
+ Split! SliceAsserts(double limit, bool pos)
+ {
+ slice_pos = pos;
+ slice_limit = limit;
+ slice_initial_limit = limit;
+ doing_slice = true;
+ Split! r = DoSplit();
+
+ /*
+ Console.WriteLine("split {0} / {1} -->", limit, pos);
+ List<Block!> tmp = impl.Blocks;
+ impl.Blocks = r.blocks;
+ EmitImpl(impl, false);
+ impl.Blocks = tmp;
+ */
+
+ return r;
+ }
+
+ void Print()
+ {
+ List<Block!> tmp = impl.Blocks;
+ impl.Blocks = blocks;
+ EmitImpl(impl, false);
+ impl.Blocks = tmp;
+ }
+
+ public Counterexample! ToCounterexample()
+ {
+ BlockSeq trace = new BlockSeq();
+ foreach (Block! b in blocks) {
+ trace.Add(b);
+ }
+ foreach (Block! b in blocks) {
+ foreach (Cmd! c in b.Cmds) {
+ if (c is AssertCmd) {
+ return AssertCmdToCounterexample((AssertCmd)c, (!)b.TransferCmd, trace, null, new Dictionary<Incarnation, Absy!>());
+ }
+ }
+ }
+ assume false;
+ }
+
+ public static List<Split!>! DoSplit(Split! initial, double max_cost, int max)
+ {
+ List<Split!> res = new List<Split!>();
+ res.Add(initial);
+
+ while (res.Count < max) {
+ Split best = null;
+ int best_idx = 0, pos = 0;
+ foreach (Split! s in res) {
+ s.ComputeBestSplit(); // TODO check total_cost first
+ if (s.total_cost > max_cost &&
+ (best == null || best.total_cost < s.total_cost) &&
+ (s.assertion_count > 1 || s.split_block != null)) {
+ best = s;
+ best_idx = pos;
+ }
+ pos++;
+ }
+
+ if (best == null) break; // no split found
+
+ Split! s0, s1;
+
+ bool split_stats = CommandLineOptions.Clo.TraceVerify;
+
+ if (split_stats) {
+ Console.WriteLine("{0} {1} -->", best.split_block == null ? "SLICE" : ("SPLIT@" + best.split_block.Label), best.Stats);
+ if (best.split_block != null) {
+ GotoCmd g = best.split_block.TransferCmd as GotoCmd;
+ if (g != null) {
+ Console.Write(" exits: ");
+ foreach (Block! b in (!)g.labelTargets) {
+ Console.Write("{0} ", b.Label);
+ }
+ Console.WriteLine("");
+ Console.Write(" assumized: ");
+ foreach (Block! b in best.assumized_branches) {
+ Console.Write("{0} ", b.Label);
+ }
+ Console.WriteLine("");
+ }
+ }
+ }
+
+ if (best.split_block != null) {
+ s0 = best.SplitAt(0);
+ s1 = best.SplitAt(1);
+ } else {
+ best.split_block = null;
+ s0 = best.SliceAsserts(best.assertion_cost / 2, true);
+ s1 = best.SliceAsserts(best.assertion_cost / 2, false);
+ }
+
+ if (true) {
+ List<Block!> ss = new List<Block!>();
+ ss.Add(s0.blocks[0]);
+ ss.Add(s1.blocks[0]);
+ try {
+ best.SoundnessCheck(new Dictionary<PureCollections.Tuple!, bool>(), best.blocks[0], ss);
+ } catch (System.Exception e) {
+ Console.WriteLine(e);
+ best.DumpDot(-1);
+ s0.DumpDot(-2);
+ s1.DumpDot(-3);
+ assert false;
+ }
+ }
+
+ if (split_stats) {
+ s0.ComputeBestSplit();
+ s1.ComputeBestSplit();
+ Console.WriteLine(" --> {0}", s0.Stats);
+ Console.WriteLine(" --> {0}", s1.Stats);
+ }
+
+ if (CommandLineOptions.Clo.TraceVerify) {
+ best.Print();
+ }
+
+ res[best_idx] = s0;
+ res.Add(s1);
+ }
+
+ return res;
+ }
+
+ public Checker! Checker
+ {
+ get {
+ assert checker != null;
+ return checker;
+ }
+ }
+
+ public WaitHandle ProverDone
+ {
+ get {
+ assert checker != null;
+ return checker.ProverDone;
+ }
+ }
+
+ public void ReadOutcome(ref Outcome cur_outcome, out bool prover_failed)
+ throws UnexpectedProverOutputException;
+ {
+ ProverInterface.Outcome outcome = ((!)checker).ReadOutcome();
+
+ if (CommandLineOptions.Clo.Trace && splitNo >= 0) {
+ System.Console.WriteLine(" --> split #{0} done, [{1} s] {2}", splitNo, checker.ProverRunTime.TotalSeconds, outcome);
+ }
+
+ if (CommandLineOptions.Clo.VcsDumpSplits) {
+ DumpDot(splitNo);
+ }
+
+ prover_failed = false;
+
+ switch (outcome) {
+ case ProverInterface.Outcome.Valid:
+ return;
+ case ProverInterface.Outcome.Invalid:
+ cur_outcome = Outcome.Errors;
+ return;
+ case ProverInterface.Outcome.OutOfMemory:
+ prover_failed = true;
+ if (cur_outcome != Outcome.Errors && cur_outcome != Outcome.Inconclusive)
+ cur_outcome = Outcome.OutOfMemory;
+ return;
+ case ProverInterface.Outcome.TimeOut:
+ prover_failed = true;
+ if (cur_outcome != Outcome.Errors && cur_outcome != Outcome.Inconclusive)
+ cur_outcome = Outcome.TimedOut;
+ return;
+ case ProverInterface.Outcome.Undetermined:
+ prover_failed = true;
+ if (cur_outcome != Outcome.Errors)
+ cur_outcome = Outcome.Inconclusive;
+ return;
+ default:
+ assert false;
+ }
+ }
+
+ public void BeginCheck(VerifierCallback! callback, int no, int timeout)
+ {
+ splitNo = no;
+
+ impl.Blocks = blocks;
+
+ checker = parent.FindCheckerFor(impl, timeout);
+
+ Hashtable/*<int, Absy!>*/! label2absy;
+ VCExpr! vc = parent.GenerateVC(impl, null, out label2absy, checker);
+
+ if (CommandLineOptions.Clo.vcVariety == CommandLineOptions.VCVariety.Local) {
+ reporter = new ErrorReporterLocal(gotoCmdOrigins, label2absy, impl.Blocks, parent.incarnationOriginMap, callback, parent.implName2LazyInliningInfo, (DeclFreeProverContext!) this.Checker.TheoremProver.Context, parent.program);
+ } else {
+ reporter = new ErrorReporter(gotoCmdOrigins, label2absy, impl.Blocks, parent.incarnationOriginMap, callback, parent.implName2LazyInliningInfo, (DeclFreeProverContext!) this.Checker.TheoremProver.Context, parent.program);
+ }
+
+ if (CommandLineOptions.Clo.TraceVerify && no >= 0)
+ {
+ Console.WriteLine("-- after split #{0}", no);
+ Print();
+ }
+
+ string! desc = (!) impl.Name;
+ if (no >= 0)
+ desc += "_split" + no;
+ checker.BeginCheck(desc, vc, reporter);
+ }
+
+ private void SoundnessCheck(Dictionary<PureCollections.Tuple!, bool>! cache, Block! orig, List<Block!>! copies)
+ {
+ {
+ PureCollections.Tuple t = new PureCollections.Tuple(new PureCollections.Capacity(1 + copies.Count));
+ int i = 0;
+ t[i++] = orig;
+ foreach (Block! b in copies) {
+ t[i++] = b;
+ }
+ if (cache.ContainsKey(t)) { return; }
+ cache[t] = true;
+ }
+
+ for (int i = 0; i < orig.Cmds.Length; ++i) {
+ Cmd cmd = orig.Cmds[i];
+ if (cmd is AssertCmd) {
+ int found = 0;
+ foreach (Block! c in copies) {
+ if (c.Cmds[i] == cmd) {
+ found++;
+ }
+ }
+ if (found == 0) {
+ throw new System.Exception(string.Format("missing assertion: {0}({1})", cmd.tok.filename, cmd.tok.line));
+ }
+ }
+ }
+
+ foreach (Block! exit in Exits(orig)) {
+ List<Block!>! newcopies = new List<Block!>();
+ foreach (Block! c in copies) {
+ foreach (Block! cexit in Exits(c)) {
+ if (cexit.Label == exit.Label) {
+ newcopies.Add(cexit);
+ }
+ }
+ }
+ if (newcopies.Count == 0) {
+ throw new System.Exception("missing exit " + exit.Label);
+ }
+ SoundnessCheck(cache, exit, newcopies);
+ }
+ }
+ }
+ #endregion
+
+
+ protected VCExpr! GenerateVC(Implementation! impl, Variable controlFlowVariable, out Hashtable/*<int, Absy!>*/! label2absy, Checker! ch)
+ {
+ TypecheckingContext tc = new TypecheckingContext(null);
+ impl.Typecheck(tc);
+
+ label2absy = new Hashtable/*<int, Absy!>*/();
+ VCExpr! vc;
+ switch (CommandLineOptions.Clo.vcVariety) {
+ case CommandLineOptions.VCVariety.Structured:
+ vc = VCViaStructuredProgram(impl, label2absy, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.Block:
+ vc = FlatBlockVC(impl, label2absy, false, false, false, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.BlockReach:
+ vc = FlatBlockVC(impl, label2absy, false, true, false, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.Local:
+ vc = FlatBlockVC(impl, label2absy, true, false, false, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.BlockNested:
+ vc = NestedBlockVC(impl, label2absy, false, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.BlockNestedReach:
+ vc = NestedBlockVC(impl, label2absy, true, ch.TheoremProver.Context);
+ break;
+ case CommandLineOptions.VCVariety.Dag:
+ if (((!)CommandLineOptions.Clo.TheProverFactory).SupportsDags) {
+ vc = DagVC((!)impl.Blocks[0], label2absy, new Hashtable/*<Block, VCExpr!>*/(), ch.TheoremProver.Context);
+ } else {
+ vc = LetVC((!)impl.Blocks[0], controlFlowVariable, label2absy, ch.TheoremProver.Context);
+ }
+ break;
+ case CommandLineOptions.VCVariety.Doomed:
+ vc = FlatBlockVC(impl, label2absy, false, false, true, ch.TheoremProver.Context);
+ break;
+ default:
+ assert false; // unexpected enumeration value
+ }
+ return vc;
+ }
+
+ void CheckIntAttributeOnImpl(Implementation! impl, string! name, ref int val)
+ {
+ if (!((!)impl.Proc).CheckIntAttribute(name, ref val) || !impl.CheckIntAttribute(name, ref val)) {
+ Console.WriteLine("ignoring ill-formed {:{0} ...} attribute on {1}, parameter should be an int", name, impl.Name);
+ }
+ }
+
+ public override Outcome VerifyImplementation(Implementation! impl, Program! program, VerifierCallback! callback)
+ throws UnexpectedProverOutputException;
+ {
+ if (impl.SkipVerification) {
+ return Outcome.Inconclusive; // not sure about this one
+ }
+
+ if (CommandLineOptions.Clo.StratifiedInlining > 0) {
+ return StratifiedVerifyImplementation(impl, program, callback);
+ }
+
+ callback.OnProgress("VCgen", 0, 0, 0.0);
+
+ ConvertCFG2DAG(impl, program);
+
+ SmokeTester smoke_tester = null;
+ if (CommandLineOptions.Clo.SoundnessSmokeTest) {
+ smoke_tester = new SmokeTester(this, impl, program, callback);
+ smoke_tester.Copy();
+ }
+
+ Hashtable/*TransferCmd->ReturnCmd*/ gotoCmdOrigins = PassifyImpl(impl, program);
+
+ double max_vc_cost = CommandLineOptions.Clo.VcsMaxCost;
+ int tmp_max_vc_cost = -1, max_splits = CommandLineOptions.Clo.VcsMaxSplits,
+ max_kg_splits = CommandLineOptions.Clo.VcsMaxKeepGoingSplits;
+ CheckIntAttributeOnImpl(impl, "vcs_max_cost", ref tmp_max_vc_cost);
+ CheckIntAttributeOnImpl(impl, "vcs_max_splits", ref max_splits);
+ CheckIntAttributeOnImpl(impl, "vcs_max_keep_going_splits", ref max_kg_splits);
+ if (tmp_max_vc_cost >= 0) {
+ max_vc_cost = tmp_max_vc_cost;
+ }
+
+ Outcome outcome = Outcome.Correct;
+
+ int cores = CommandLineOptions.Clo.VcsCores;
+ Stack<Split!> work = new Stack<Split!>();
+ List<Split!> currently_running = new List<Split!>();
+ ResetPredecessors(impl.Blocks);
+ work.Push(new Split(impl.Blocks, gotoCmdOrigins, this, impl));
+
+ bool keep_going = max_kg_splits > 1;
+ int total = 0;
+ int no = max_splits == 1 && !keep_going ? -1 : 0;
+ bool first_round = true;
+ bool do_splitting = keep_going || max_splits > 1;
+ double remaining_cost = 0.0, proven_cost = 0.0;
+
+ if (do_splitting) {
+ remaining_cost = work.Peek().Cost;
+ }
+
+ while (work.Count > 0 || currently_running.Count > 0) {
+ bool prover_failed = false;
+ Split! s;
+
+ if (work.Count > 0 && currently_running.Count < cores) {
+ s = work.Pop();
+
+ if (first_round && max_splits > 1) {
+ prover_failed = true;
+ remaining_cost -= s.Cost;
+ } else {
+ if (CommandLineOptions.Clo.Trace && no >= 0) {
+ System.Console.WriteLine(" checking split {1}/{2}, {3:0.00}%, {0} ...",
+ s.Stats, no + 1, total, 100 * proven_cost / (proven_cost + remaining_cost));
+ }
+ callback.OnProgress("VCprove", no < 0 ? 0 : no, total, proven_cost / (remaining_cost + proven_cost));
+
+ s.BeginCheck(callback, no,
+ (keep_going && s.LastChance) ? CommandLineOptions.Clo.VcsFinalAssertTimeout :
+ keep_going ? CommandLineOptions.Clo.VcsKeepGoingTimeout :
+ CommandLineOptions.Clo.ProverKillTime);
+
+ no++;
+
+ currently_running.Add(s);
+ }
+ } else {
+ WaitHandle[] handles = new WaitHandle[currently_running.Count];
+ for (int i = 0; i < currently_running.Count; ++i) {
+ handles[i] = currently_running[i].ProverDone;
+ }
+ int index = WaitHandle.WaitAny(handles);
+ s = currently_running[index];
+ currently_running.RemoveAt(index);
+
+ if (do_splitting) {
+ remaining_cost -= s.Cost;
+ }
+
+ s.ReadOutcome(ref outcome, out prover_failed);
+
+ if (do_splitting) {
+ if (prover_failed) {
+ // even if the prover fails, we have learned something, i.e., it is
+ // annoying to watch Boogie say Timeout, 0.00% a couple of times
+ proven_cost += s.Cost / 100;
+ } else {
+ proven_cost += s.Cost;
+ }
+ }
+ callback.OnProgress("VCprove", no < 0 ? 0 : no, total, proven_cost / (remaining_cost + proven_cost));
+
+ if (prover_failed && !first_round && s.LastChance) {
+ string! msg = "some timeout";
+ if (s.reporter != null && s.reporter.resourceExceededMessage != null) {
+ msg = s.reporter.resourceExceededMessage;
+ }
+ callback.OnCounterexample(s.ToCounterexample(), msg);
+ outcome = Outcome.Errors;
+ break;
+ }
+
+ assert prover_failed || outcome == Outcome.Correct || outcome == Outcome.Errors;
+ }
+
+ if (prover_failed) {
+ int splits = first_round && max_splits > 1 ? max_splits : max_kg_splits;
+
+ if (splits > 1) {
+ List<Split!> tmp = Split.DoSplit(s, max_vc_cost, splits);
+ max_vc_cost = 1.0; // for future
+ first_round = false;
+ //tmp.Sort(new Comparison<Split!>(Split.Compare));
+ foreach (Split! a in tmp) {
+ work.Push(a);
+ total++;
+ remaining_cost += a.Cost;
+ }
+ if (outcome != Outcome.Errors) {
+ outcome = Outcome.Correct;
+ }
+ } else {
+ assert outcome != Outcome.Correct;
+ if (outcome == Outcome.TimedOut) {
+ string! msg = "some timeout";
+ if (s.reporter != null && s.reporter.resourceExceededMessage != null) {
+ msg = s.reporter.resourceExceededMessage;
+ }
+ callback.OnTimeout(msg);
+ } else if (outcome == Outcome.OutOfMemory) {
+ string! msg = "out of memory";
+ if (s.reporter != null && s.reporter.resourceExceededMessage != null) {
+ msg = s.reporter.resourceExceededMessage;
+ }
+ callback.OnOutOfMemory(msg);
+ }
+
+ break;
+ }
+ }
+ }
+
+ if (outcome == Outcome.Correct && smoke_tester != null) {
+ smoke_tester.Test();
+ }
+
+ callback.OnProgress("done", 0, 0, 1.0);
+
+ return outcome;
+ }
+
+ public override Outcome StratifiedVerifyImplementation(Implementation! impl, Program! program, VerifierCallback! callback)
+ throws UnexpectedProverOutputException;
+ {
+ // This flag control the nature of queries made by StratifiedVerifyImplementation
+ // true: incremental search; false: in-place inlining
+ bool incrementalSearch = true;
+
+ // Get the checker
+ Checker! checker = FindCheckerFor(null, CommandLineOptions.Clo.ProverKillTime);
+
+ // Run live variable analysis
+ if(CommandLineOptions.Clo.LiveVariableAnalysis == 2) {
+ Microsoft.Boogie.InterProcGenKill.ComputeLiveVars(impl, program);
+ }
+
+ // Build VCs for all procedures
+ assert implName2StratifiedInliningInfo != null;
+ foreach(StratifiedInliningInfo! info in implName2StratifiedInliningInfo.Values)
+ {
+ GenerateVCForStratifiedInlining(program, info, checker);
+ }
+
+ // Get the VC of the current procedure
+ VCExpr! vc;
+ StratifiedInliningErrorReporter! reporter;
+ Hashtable/*<int, Absy!>*/! mainLabel2absy;
+ GetVC(impl, program, callback, out vc, out mainLabel2absy, out reporter);
+
+ // Find all procedure calls in vc and put labels on them
+ FCallHandler calls = new FCallHandler(checker.VCExprGen, implName2StratifiedInliningInfo, mainLabel2absy);
+ calls.setCurrProcAsMain();
+ vc = calls.Mutate(vc, true);
+ reporter.SetCandidateHandler(calls);
+
+ Outcome ret = Outcome.Correct;
+
+ int expansionCount = 0;
+ int total_axioms_pushed = 0;
+
+ // Do eager inlining
+ for(int i = 1; i < CommandLineOptions.Clo.StratifiedInlining && calls.currCandidates.Count > 0; i ++)
+ {
+ List<int>! toExpand = new List<int>();
+ foreach(int id in calls.currCandidates) {
+ toExpand.Add(id);
+ }
+ expansionCount += toExpand.Count;
+ if(incrementalSearch)
+ {
+ total_axioms_pushed +=
+ DoExpansion(toExpand, calls, checker);
+ } else
+ {
+ vc = DoExpansionAndInline(vc, toExpand, calls, checker);
+ }
+ }
+
+ int cnt = 0;
+ while(cnt < 500) {
+ cnt ++;
+
+ // Push "false"
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Underapprox mode begin ;;;;;;;;;;");
+
+ int prev_axioms_pushed = checker.TheoremProver.NumAxiomsPushed();
+
+ foreach(int id in calls.currCandidates) {
+ VCExprNAry! vce = calls.id2Candidate[id];
+ VCExpr! falseExpr = checker.VCExprGen.Eq(vce, VCExpressionGenerator.False);
+ checker.TheoremProver.PushVCExpression(falseExpr);
+ }
+ int axioms_pushed = checker.TheoremProver.NumAxiomsPushed();
+
+ // Note: axioms_pushed may not be the same as calls.currCandidates.Count
+ // because PushVCExpression pushes other stuff too (which always seems
+ // to be TRUE)
+
+ reporter.underapproximationMode = true;
+
+ // Check!
+ //Console.Write("Checking with preds == false: "); Console.Out.Flush();
+ ret = CheckVC(vc, reporter, checker, impl.Name);
+ //Console.WriteLine(ret.ToString());
+
+ // Pop
+ for(int i = 0; i < axioms_pushed - prev_axioms_pushed; i++) {
+ checker.TheoremProver.Pop();
+ }
+
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Underapprox mode end ;;;;;;;;;;");
+
+ if(ret == Outcome.Errors) {
+ break;
+ }
+
+ // If we didn't underapproximate, then we're done
+ if(calls.currCandidates.Count == 0) {
+ break;
+ }
+
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Overapprox mode begin ;;;;;;;;;;");
+ // Push "true" (No-op)
+ // Check
+ reporter.underapproximationMode = false;
+
+ //Console.Write("Checking with preds == true: "); Console.Out.Flush();
+ ret = CheckVC(vc, reporter, checker, impl.Name);
+ //Console.WriteLine(ret.ToString());
+
+ if(ret == Outcome.Correct) {
+ break;
+ }
+
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Overapprox mode end ;;;;;;;;;;");
+
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Expansion begin ;;;;;;;;;;");
+
+ // Look at the errors to see what to inline
+ assert reporter.candidatesToExpand.Count != 0;
+
+ expansionCount += reporter.candidatesToExpand.Count;
+
+ if(incrementalSearch)
+ {
+ total_axioms_pushed +=
+ DoExpansion(reporter.candidatesToExpand, calls, checker);
+ } else
+ {
+ vc = DoExpansionAndInline(vc, reporter.candidatesToExpand, calls, checker);
+ }
+
+ checker.TheoremProver.LogComment(";;;;;;;;;;;; Expansion end ;;;;;;;;;;");
+ }
+
+ // Pop off everything that we pushed so that there are no side effects from
+ // this call to VerifyImplementation
+ for(int i = 0; i < total_axioms_pushed; i++) {
+ checker.TheoremProver.Pop();
+ }
+
+ if(cnt == 500)
+ {
+ checker.TheoremProver.LogComment("Stratified Inlining: timeout");
+ }
+
+ checker.TheoremProver.LogComment(string.Format("Stratified Inlining: Calls to Z3: {0}", 2*cnt));
+ checker.TheoremProver.LogComment(string.Format("Stratified Inlining: Expansions performed: {0}", expansionCount));
+ checker.TheoremProver.LogComment(string.Format("Stratified Inlining: Candidates left: {0}", calls.currCandidates.Count));
+
+ return ret;
+ }
+
+ // A counter for adding new variables
+ static int newVarCnt = 0;
+
+ // Does on-demand inlining -- pushes procedure bodies on the theorem prover stack.
+ // Returns the number of axioms pushed.
+ private int DoExpansion(List<int>! candidates,
+ FCallHandler! calls, Checker! checker)
+ throws UnexpectedProverOutputException;
+ {
+ int old_axioms_pushed = checker.TheoremProver.NumAxiomsPushed();
+ VCExpr! exprToPush = VCExpressionGenerator.True;
+ foreach(int id in candidates) {
+ VCExprNAry! expr = calls.id2Candidate[id];
+ string procName = ((!)(expr.Op as VCExprBoogieFunctionOp)).Func.Name;
+ if(!implName2StratifiedInliningInfo.ContainsKey(procName)) continue;
+
+ //Console.WriteLine("Expanding: {0}", expr.ToString());
+
+ StratifiedInliningInfo info = implName2StratifiedInliningInfo[procName];
+ VCExpr! expansion = (!)info.vcexpr;
+
+ // Instantiate the "forall" variables
+ Dictionary<VCExprVar!, VCExpr!>! substForallDict = new Dictionary<VCExprVar!, VCExpr!>();
+ assert info.interfaceExprVars.Count == expr.Length;
+ for(int i = 0; i < info.interfaceExprVars.Count; i++) {
+ substForallDict.Add(info.interfaceExprVars[i], expr[i]);
+ }
+ VCExprSubstitution substForall = new VCExprSubstitution(substForallDict, new Dictionary<TypeVariable!, Microsoft.Boogie.Type!>());
+
+ SubstitutingVCExprVisitor! subst = new SubstitutingVCExprVisitor(checker.VCExprGen);
+ expansion = subst.Mutate(expansion, substForall);
+
+ // Instantiate and declare the "exists" variables
+ Dictionary<VCExprVar!, VCExpr!>! substExistsDict = new Dictionary<VCExprVar!, VCExpr!>();
+ for(int i = 0; i < info.privateVars.Count; i++) {
+ VCExprVar! v = info.privateVars[i];
+ string newName = v.Name + "_si_" + newVarCnt.ToString();
+ newVarCnt ++;
+ checker.TheoremProver.Context.DeclareConstant(new Constant(Token.NoToken, new TypedIdent(Token.NoToken, newName, v.Type)), false, null);
+ substExistsDict.Add(v, checker.VCExprGen.Variable(newName, v.Type));
+ }
+ VCExprSubstitution substExists = new VCExprSubstitution(substExistsDict, new Dictionary<TypeVariable!, Microsoft.Boogie.Type!>());
+
+ subst = new SubstitutingVCExprVisitor(checker.VCExprGen);
+ expansion = subst.Mutate(expansion, substExists);
+
+ if(!calls.currCandidates.Contains(id)) {
+ Console.WriteLine("Don't know what we just expanded");
+ }
+
+ calls.currCandidates.Remove(id);
+
+ // Record the new set of candidates and rename absy labels
+ calls.currInlineCount = id;
+ calls.setCurrProc(procName);
+ expansion = calls.Mutate(expansion, true);
+
+ expansion = checker.VCExprGen.Eq(expr, expansion);
+ exprToPush = checker.VCExprGen.And(exprToPush, expansion);
+ //checker.TheoremProver.PushVCExpression(expansion);
+
+ }
+ checker.TheoremProver.PushVCExpression(exprToPush);
+
+ int axioms_pushed = checker.TheoremProver.NumAxiomsPushed() - old_axioms_pushed;
+ checker.TheoremProver.FlushAxiomsToTheoremProver();
+ return axioms_pushed;
+ }
+
+ // Does on-demand inlining -- pushes procedure bodies on the theorem prover stack.
+ // Returns the number of axioms pushed.
+ private VCExpr! DoExpansionAndInline(
+ VCExpr! mainVC, List<int>! candidates,
+ FCallHandler! calls, Checker! checker)
+ throws UnexpectedProverOutputException;
+ {
+ FCallInliner! inliner = new FCallInliner(checker.VCExprGen);
+ foreach(int id in candidates) {
+ VCExprNAry! expr = calls.id2Candidate[id];
+
+ string procName = ((!)(expr.Op as VCExprBoogieFunctionOp)).Func.Name;
+ if(!implName2StratifiedInliningInfo.ContainsKey(procName)) continue;
+
+ StratifiedInliningInfo info = implName2StratifiedInliningInfo[procName];
+ VCExpr! expansion = (!)info.vcexpr;
+
+ // Instantiate the "forall" variables
+ Dictionary<VCExprVar!, VCExpr!>! substForallDict = new Dictionary<VCExprVar!, VCExpr!>();
+ assert info.interfaceExprVars.Count == expr.Length;
+ for(int i = 0; i < info.interfaceExprVars.Count; i++) {
+ substForallDict.Add(info.interfaceExprVars[i], expr[i]);
+ }
+ VCExprSubstitution substForall = new VCExprSubstitution(substForallDict, new Dictionary<TypeVariable!, Microsoft.Boogie.Type!>());
+
+ SubstitutingVCExprVisitor! subst = new SubstitutingVCExprVisitor(checker.VCExprGen);
+ expansion = subst.Mutate(expansion, substForall);
+
+ // Instantiate and declare the "exists" variables
+ Dictionary<VCExprVar!, VCExpr!>! substExistsDict = new Dictionary<VCExprVar!, VCExpr!>();
+ for(int i = 0; i < info.privateVars.Count; i++) {
+ VCExprVar! v = info.privateVars[i];
+ string newName = v.Name + "_si_" + newVarCnt.ToString();
+ newVarCnt ++;
+ checker.TheoremProver.Context.DeclareConstant(new Constant(Token.NoToken, new TypedIdent(Token.NoToken, newName, v.Type)), false, null);
+ substExistsDict.Add(v, checker.VCExprGen.Variable(newName, v.Type));
+ }
+ VCExprSubstitution substExists = new VCExprSubstitution(substExistsDict, new Dictionary<TypeVariable!, Microsoft.Boogie.Type!>());
+
+ subst = new SubstitutingVCExprVisitor(checker.VCExprGen);
+ expansion = subst.Mutate(expansion, substExists);
+
+ if(!calls.currCandidates.Contains(id)) {
+ Console.WriteLine("Don't know what we just expanded");
+ }
+
+ calls.currCandidates.Remove(id);
+
+ // Record the new set of candidates and rename absy labels
+ calls.currInlineCount = id;
+ calls.setCurrProc(procName);
+ expansion = calls.Mutate(expansion, true);
+
+ inliner.subst.Add(id, expansion);
+
+ }
+
+ return inliner.Mutate(mainVC, true);
+ }
+
+ // Return the VC for the impl (don't pass it to the theorem prover).
+ // GetVC is a cheap imitation of VerifyImplementatio, except that the VC is not passed to the theorem prover.
+ private void GetVC(Implementation! impl, Program! program, VerifierCallback! callback, out VCExpr! vc, out Hashtable/*<int, Absy!>*/! label2absy, out StratifiedInliningErrorReporter! reporter)
+ {
+ ConvertCFG2DAG(impl, program);
+ Hashtable/*TransferCmd->ReturnCmd*/ gotoCmdOrigins = PassifyImpl(impl, program);
+ Checker! checker = FindCheckerFor(impl, CommandLineOptions.Clo.ProverKillTime);
+
+ vc = GenerateVC(impl, null, out label2absy, checker);
+
+ /*
+ ErrorReporter errReporter;
+ if (CommandLineOptions.Clo.vcVariety == CommandLineOptions.VCVariety.Local) {
+ errReporter = new ErrorReporterLocal(gotoCmdOrigins, label2absy, impl.Blocks, incarnationOriginMap, callback, implName2LazyInliningInfo, (DeclFreeProverContext!) checker.TheoremProver.Context, program);
+ } else {
+ errReporter = new ErrorReporter(gotoCmdOrigins, label2absy, impl.Blocks, incarnationOriginMap, callback, implName2LazyInliningInfo, (DeclFreeProverContext!) checker.TheoremProver.Context, program);
+ }
+ */
+
+ reporter = new StratifiedInliningErrorReporter(
+ (!)implName2StratifiedInliningInfo, checker.TheoremProver, callback,
+ (DeclFreeProverContext)checker.TheoremProver.Context, gotoCmdOrigins, program, impl);
+
+ }
+
+ private Outcome CheckVC(VCExpr! vc, StratifiedInliningErrorReporter! reporter, Checker! checker, string! implName)
+ throws UnexpectedProverOutputException;
+ {
+ checker.TheoremProver.FlushAxiomsToTheoremProver();
+ checker.BeginCheck(implName, vc, reporter);
+ checker.ProverDone.WaitOne();
+
+ ProverInterface.Outcome outcome = (checker).ReadOutcome();
+
+ //checker.BeginCheck(implName, vc, reporter);
+ //checker.ProverDone.WaitOne();
+ //outcome = (checker).ReadOutcome();
+
+ switch (outcome) {
+ case ProverInterface.Outcome.Valid:
+ return Outcome.Correct;
+ case ProverInterface.Outcome.Invalid:
+ return Outcome.Errors;
+ case ProverInterface.Outcome.OutOfMemory:
+ return Outcome.OutOfMemory;
+ case ProverInterface.Outcome.TimeOut:
+ return Outcome.TimedOut;
+ case ProverInterface.Outcome.Undetermined:
+ return Outcome.Inconclusive;
+ default:
+ assert false;
+ }
+
+ }
+
+ /*
+ // Collects all function calls in the VCExpr
+ public class FCallCollector : TraversingVCExprVisitor<bool, bool> {
+ Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo;
+ public List<VCExprNAry!>! fcalls;
+
+ public FCallCollector(Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo) {
+ this.implName2StratifiedInliningInfo = implName2StratifiedInliningInfo;
+ fcalls = new List<VCExprNAry!>();
+ }
+
+ protected override bool StandardResult(VCExpr! node, bool arg) {
+ VCExprNAry vnary = node as VCExprNAry;
+ if(vnary == null) return true;
+ VCExprBoogieFunctionOp bop = vnary.Op as VCExprBoogieFunctionOp;
+ if(bop == null) return true;
+ if(implName2StratifiedInliningInfo.ContainsKey(bop.Func.Name)) {
+ fcalls.Add(vnary);
+ }
+ return true;
+ }
+
+ }
+ */
+
+ // This class is used to traverse VCs and do the following:
+ // -- collect the set of FunctionCall nodes and label them with a unique string
+ // -- Rename all other labels (so that calling this on the same VC results in
+ // VCs with different labels each time)
+ public class FCallHandler : MutatingVCExprVisitor<bool> {
+ Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo;
+ public readonly Hashtable/*<int, Absy!>*/! mainLabel2absy;
+ public Dictionary<NAryExpr!, int>! boogieExpr2Id;
+ public Dictionary<int, VCExprNAry!>! id2Candidate;
+ public Dictionary<VCExprNAry!, int>! candidate2Id;
+ public Dictionary<string!, int>! label2Id;
+ public Microsoft.SpecSharp.Collections.Set<int> currCandidates;
+
+ // Name of the procedure who's VC we're mutating
+ string currProc;
+
+ // The 0^th candidate is main
+ static int candidateCount = 1;
+ public int currInlineCount;
+
+ public FCallHandler(VCExpressionGenerator! gen,
+ Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo,
+ Hashtable/*<int, Absy!>*/! mainLabel2absy)
+ : base(gen)
+ {
+ this.implName2StratifiedInliningInfo = implName2StratifiedInliningInfo;
+ this.mainLabel2absy = mainLabel2absy;
+ id2Candidate = new Dictionary<int, VCExprNAry!>();
+ candidate2Id = new Dictionary<VCExprNAry!, int>();
+ boogieExpr2Id = new Dictionary<NAryExpr!, int>();
+ label2Id = new Dictionary<string!, int>();
+ currCandidates = new Microsoft.SpecSharp.Collections.Set<int>();
+ currInlineCount = 0;
+ currProc = null;
+ }
+
+ public void Clear()
+ {
+ currCandidates = new Microsoft.SpecSharp.Collections.Set<int>();
+ }
+
+ private int GetId(VCExprNAry! vc)
+ {
+ if(candidate2Id.ContainsKey(vc))
+ return candidate2Id[vc];
+
+
+ int id = candidateCount;
+ candidate2Id[vc] = id;
+ id2Candidate[id] = vc;
+
+ candidateCount ++;
+ currCandidates.Add(id);
+
+ return id;
+ }
+
+ private string! GetLabel(int id)
+ {
+ string! ret = "si_fcall_" + id.ToString();
+ if(!label2Id.ContainsKey(ret))
+ label2Id[ret] = id;
+
+ return ret;
+ }
+
+ public int GetId(string! label)
+ {
+ if(!label2Id.ContainsKey(label)) return -1;
+ return label2Id[label];
+ }
+
+ public string! RenameAbsyLabel(string !label)
+ requires label.Length >= 1;
+ {
+ // Remove the sign from the label
+ string! nosign = label.Substring(1);
+ return "si_inline_" + currInlineCount.ToString() + "_" + nosign;
+ }
+
+ public string ParseRenamedAbsyLabel(string! label)
+ {
+ string! prefix = RenameAbsyLabel("+");
+ if(!label.StartsWith(prefix))
+ return null;
+ return label.Substring(prefix.Length);
+ }
+
+ public void setCurrProc(string! name)
+ {
+ currProc = name;
+ assert implName2StratifiedInliningInfo.ContainsKey(name);
+ }
+
+ public void setCurrProcAsMain()
+ {
+ currProc = "";
+ }
+
+ private Hashtable/*<int,absy>*/! getLabel2absy()
+ {
+ assert currProc != null;
+ if(currProc == "") {
+ return mainLabel2absy;
+ }
+ return (!)implName2StratifiedInliningInfo[currProc].label2absy;
+ }
+
+ // Finds labels and changes them:
+ // si_fcall_id: if "id" corresponds to a tracked procedure call, then
+ // si_fcall_candidateId
+ // si_fcall_id: if "id" does not corresponds to a tracked procedure call, then
+ // delete
+ // num: si_inline_num
+ //
+ protected override VCExpr! UpdateModifiedNode(VCExprNAry! originalNode,
+ List<VCExpr!>! newSubExprs,
+ // has any of the subexpressions changed?
+ bool changed,
+ bool arg)
+ {
+ VCExpr! ret;
+ if (changed)
+ ret = Gen.Function(originalNode.Op,
+ newSubExprs, originalNode.TypeArguments);
+ else
+ ret = originalNode;
+
+ VCExprLabelOp lop = originalNode.Op as VCExprLabelOp;
+ if(lop == null) return ret;
+ if(!(ret is VCExprNAry!)) return ret;
+
+ VCExprNAry! retnary = (VCExprNAry!)ret;
+ string! prefix = "si_fcall_"; // from Wlp.ssc::Cmd(...)
+ if(lop.label.Substring(1).StartsWith(prefix)) {
+ int id = Int32.Parse(lop.label.Substring(prefix.Length + 1));
+ Hashtable! label2absy = getLabel2absy();
+ Absy cmd = label2absy[id] as Absy;
+ //label2absy.Remove(id);
+
+ assert cmd != null;
+ AssumeCmd acmd = cmd as AssumeCmd;
+ assert acmd != null;
+ NAryExpr naryExpr = acmd.Expr as NAryExpr;
+ assert naryExpr != null;
+
+ string! calleeName = naryExpr.Fun.FunctionName;
+
+ VCExprNAry callExpr = retnary[0] as VCExprNAry;
+ assert callExpr != null;
+
+ if(implName2StratifiedInliningInfo.ContainsKey(calleeName)) {
+ int candidateId = GetId(callExpr);
+ boogieExpr2Id[naryExpr] = candidateId;
+ string! label = GetLabel(candidateId);
+ return Gen.LabelPos(label, callExpr);
+ } else {
+ return callExpr;
+ }
+ }
+
+ // Else, rename label
+ string! newLabel = RenameAbsyLabel(lop.label);
+ if(lop.pos) {
+ return Gen.LabelPos(newLabel, retnary[0]);
+ } else {
+ return Gen.LabelNeg(newLabel, retnary[0]);
+ }
+
+ }
+
+ } // end FCallHandler
+
+
+ public class FCallInliner : MutatingVCExprVisitor<bool> {
+ public Dictionary<int, VCExpr!>! subst;
+
+ public FCallInliner(VCExpressionGenerator! gen)
+ : base(gen)
+ {
+ subst = new Dictionary<int, VCExpr!>();
+ }
+
+ public void Clear()
+ {
+ subst = new Dictionary<int, VCExpr!>();
+ }
+
+ protected override VCExpr! UpdateModifiedNode(VCExprNAry! originalNode,
+ List<VCExpr!>! newSubExprs,
+ // has any of the subexpressions changed?
+ bool changed,
+ bool arg)
+ {
+ VCExpr! ret;
+ if (changed)
+ ret = Gen.Function(originalNode.Op,
+ newSubExprs, originalNode.TypeArguments);
+ else
+ ret = originalNode;
+
+ VCExprLabelOp lop = originalNode.Op as VCExprLabelOp;
+ if(lop == null) return ret;
+ if(!(ret is VCExprNAry!)) return ret;
+
+ string! prefix = "si_fcall_"; // from FCallHandler::GetLabel
+ if(lop.label.Substring(1).StartsWith(prefix)) {
+ int id = Int32.Parse(lop.label.Substring(prefix.Length + 1));
+ if(subst.ContainsKey(id)) {
+ return subst[id];
+ }
+ }
+ return ret;
+ }
+
+ } // end FCallInliner
+
+ public class ErrorReporter : ProverInterface.ErrorHandler {
+ Hashtable/*TransferCmd->ReturnCmd*/! gotoCmdOrigins;
+ Hashtable/*<int, Absy!>*/! label2absy;
+ List<Block!>! blocks;
+ protected Dictionary<Incarnation, Absy!>! incarnationOriginMap;
+ protected VerifierCallback! callback;
+ internal string? resourceExceededMessage;
+ static System.IO.TextWriter? modelWriter;
+
+ public static TextWriter! ModelWriter {
+ get {
+ if (ErrorReporter.modelWriter == null)
+ ErrorReporter.modelWriter = CommandLineOptions.Clo.PrintErrorModelFile == null ? Console.Out : new StreamWriter(CommandLineOptions.Clo.PrintErrorModelFile, false);
+ return ErrorReporter.modelWriter;
+ }
+ }
+
+ Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo;
+ DeclFreeProverContext! context;
+ Program! program;
+
+ public ErrorReporter(Hashtable/*TransferCmd->ReturnCmd*/! gotoCmdOrigins,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ List<Block!>! blocks,
+ Dictionary<Incarnation, Absy!>! incarnationOriginMap,
+ VerifierCallback! callback,
+ Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo,
+ DeclFreeProverContext! context,
+ Program! program)
+ {
+ this.gotoCmdOrigins = gotoCmdOrigins;
+ this.label2absy = label2absy;
+ this.blocks = blocks;
+ this.incarnationOriginMap = incarnationOriginMap;
+ this.callback = callback;
+
+ this.implName2LazyInliningInfo = implName2LazyInliningInfo;
+ this.context = context;
+ this.program = program;
+ // base();
+ }
+
+ public override void OnModel(IList<string!>! labels, ErrorModel errModel) {
+ if (CommandLineOptions.Clo.PrintErrorModel >= 1 && errModel != null) {
+ errModel.Print(ErrorReporter.ModelWriter);
+ ErrorReporter.ModelWriter.Flush();
+ }
+ Hashtable traceNodes = new Hashtable();
+ foreach (string! s in labels) {
+ Absy! absy = Label2Absy(s);
+ if (traceNodes.ContainsKey(absy))
+ System.Console.WriteLine("Warning: duplicate label: " + s + " read while tracing nodes");
+ else
+ traceNodes.Add(absy, null);
+ }
+
+ BlockSeq! trace = new BlockSeq();
+ Block! entryBlock = (!) this.blocks[0];
+ assert traceNodes.Contains(entryBlock);
+ trace.Add(entryBlock);
+
+ Counterexample newCounterexample = TraceCounterexample(entryBlock, traceNodes, trace, errModel, incarnationOriginMap, implName2LazyInliningInfo, context, program, new Dictionary<Absy!, CalleeCounterexampleInfo!>());
+
+ if (newCounterexample == null) return;
+
+ #region Map passive program errors back to original program errors
+ ReturnCounterexample returnExample = newCounterexample as ReturnCounterexample;
+ if (returnExample != null)
+ {
+ foreach (Block! b in returnExample.Trace) {
+ assume b.TransferCmd != null;
+ ReturnCmd cmd = (ReturnCmd) gotoCmdOrigins[b.TransferCmd];
+ if (cmd != null)
+ {
+ returnExample.FailingReturn = cmd;
+ break;
+ }
+ }
+ }
+ #endregion
+ callback.OnCounterexample(newCounterexample, null);
+ }
+
+ public override Absy! Label2Absy(string! label)
+ {
+ int id = int.Parse(label);
+ return (Absy!) label2absy[id];
+ }
+
+ public override void OnResourceExceeded(string! msg)
+ {
+ resourceExceededMessage = msg;
+ }
+
+ public override void OnProverWarning(string! msg)
+ {
+ callback.OnWarning(msg);
+ }
+ }
+
+ public class ErrorReporterLocal : ErrorReporter {
+ public ErrorReporterLocal(Hashtable/*TransferCmd->ReturnCmd*/! gotoCmdOrigins,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ List<Block!>! blocks,
+ Dictionary<Incarnation, Absy!>! incarnationOriginMap,
+ VerifierCallback! callback,
+ Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo,
+ DeclFreeProverContext! context,
+ Program! program)
+ {
+ base(gotoCmdOrigins, label2absy, blocks, incarnationOriginMap, callback, implName2LazyInliningInfo, context, program); // here for aesthetic purposes
+ }
+
+ public override void OnModel(IList<string!>! labels, ErrorModel errModel) {
+ // We ignore the error model here for enhanced error message purposes.
+ // It is only printed to the command line.
+ if (CommandLineOptions.Clo.PrintErrorModel >= 1 && errModel != null) {
+ if (CommandLineOptions.Clo.PrintErrorModelFile != null) {
+ errModel.Print(ErrorReporter.ModelWriter);
+ ErrorReporter.ModelWriter.Flush();
+ }
+ }
+ List<Block!> traceNodes = new List<Block!>();
+ List<AssertCmd!> assertNodes = new List<AssertCmd!>();
+ foreach (string! s in labels) {
+ Absy node = Label2Absy(s);
+ if (node is Block) {
+ Block b = (Block)node;
+ traceNodes.Add(b);
+ } else {
+ AssertCmd a = (AssertCmd)node;
+ assertNodes.Add(a);
+ }
+ }
+ assert assertNodes.Count > 0;
+ assert traceNodes.Count == assertNodes.Count;
+
+ foreach (AssertCmd a in assertNodes) {
+ // find the corresponding Block (assertNodes.Count is likely to be 1, or small in any case, so just do a linear search here)
+ foreach (Block b in traceNodes) {
+ if (b.Cmds.Has(a)) {
+ BlockSeq trace = new BlockSeq();
+ trace.Add(b);
+ Counterexample newCounterexample = AssertCmdToCounterexample(a, (!)b.TransferCmd, trace, errModel, incarnationOriginMap);
+ callback.OnCounterexample(newCounterexample, null);
+ goto NEXT_ASSERT;
+ }
+ }
+ assert false; // there was no block that contains the assert
+ NEXT_ASSERT: {}
+ }
+ }
+ }
+
+ public class StratifiedInliningErrorReporter : ProverInterface.ErrorHandler {
+ Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo;
+ ProverInterface! theoremProver;
+ VerifierCallback! callback;
+ FCallHandler calls;
+ Program! program;
+ Implementation! mainImpl;
+ DeclFreeProverContext! context;
+ Hashtable/*TransferCmd->ReturnCmd*/ gotoCmdOrigins;
+
+ public bool underapproximationMode;
+ public List<int>! candidatesToExpand;
+
+ public StratifiedInliningErrorReporter(Dictionary<string!, StratifiedInliningInfo!>! implName2StratifiedInliningInfo,
+ ProverInterface! theoremProver, VerifierCallback! callback, DeclFreeProverContext! context,
+ Hashtable/*TransferCmd->ReturnCmd*/ gotoCmdOrigins,
+ Program! program, Implementation! mainImpl) {
+ this.implName2StratifiedInliningInfo = implName2StratifiedInliningInfo;
+ this.theoremProver = theoremProver;
+ this.callback = callback;
+ this.context = context;
+ this.program = program;
+ this.mainImpl = mainImpl;
+ this.underapproximationMode = false;
+ this.calls = null;
+ this.candidatesToExpand = new List<int>();
+ this.gotoCmdOrigins = gotoCmdOrigins;
+ }
+
+ public void SetCandidateHandler(FCallHandler! calls)
+ {
+ this.calls = calls;
+ }
+
+ public override void OnModel(IList<string!>! labels, ErrorModel errModel) {
+ if(underapproximationMode) {
+ if(errModel == null) return;
+ GenerateTraceMain(labels, errModel);
+ return;
+ }
+
+ assert calls != null;
+ assert errModel != null;
+
+ candidatesToExpand = new List<int>();
+ foreach(string! lab in labels)
+ {
+ int id = calls.GetId(lab);
+ if(id < 0) continue;
+ if(!calls.currCandidates.Contains(id)) continue;
+ candidatesToExpand.Add(id);
+ }
+
+ }
+
+ // Construct the interprocedural trace
+ private void GenerateTraceMain(IList<string!>! labels, ErrorModel! errModel) {
+ if (CommandLineOptions.Clo.PrintErrorModel >= 1 && errModel != null) {
+ errModel.Print(ErrorReporter.ModelWriter);
+ ErrorReporter.ModelWriter.Flush();
+ }
+
+ Counterexample newCounterexample =
+ GenerateTrace(labels, errModel, 0, mainImpl);
+
+ if(newCounterexample == null) return;
+
+ #region Map passive program errors back to original program errors
+ ReturnCounterexample returnExample = newCounterexample as ReturnCounterexample;
+ if (returnExample != null && gotoCmdOrigins != null)
+ {
+ foreach (Block! b in returnExample.Trace) {
+ assume b.TransferCmd != null;
+ ReturnCmd cmd = (ReturnCmd) gotoCmdOrigins[b.TransferCmd];
+ if (cmd != null)
+ {
+ returnExample.FailingReturn = cmd;
+ break;
+ }
+ }
+ }
+ #endregion
+
+ callback.OnCounterexample(newCounterexample, null);
+ }
+
+ private Counterexample GenerateTrace(IList<string!>! labels, ErrorModel! errModel,
+ int candidateId, Implementation! procImpl) {
+
+ Hashtable traceNodes = new Hashtable();
+ string! procPrefix = "si_inline_" + candidateId.ToString() + "_";
+
+ foreach (string! s in labels) {
+ if(!s.StartsWith(procPrefix))
+ continue;
+
+ Absy! absy;
+
+ if(candidateId == 0) {
+ absy = Label2Absy(s.Substring(procPrefix.Length));
+ } else {
+ absy = Label2Absy(procImpl.Name, s.Substring(procPrefix.Length));
+ }
+
+ if (traceNodes.ContainsKey(absy))
+ System.Console.WriteLine("Warning: duplicate label: " + s + " read while tracing nodes");
+ else
+ traceNodes.Add(absy, null);
+ }
+
+ BlockSeq! trace = new BlockSeq();
+ Block! entryBlock = (!) procImpl.Blocks[0];
+ assert traceNodes.Contains(entryBlock);
+ trace.Add(entryBlock);
+
+ Dictionary<Absy!, CalleeCounterexampleInfo!>! calleeCounterexamples = new Dictionary<Absy!, CalleeCounterexampleInfo!>();
+ Counterexample newCounterexample = GenerateTraceRec(labels, errModel, entryBlock, traceNodes, trace, calleeCounterexamples);
+
+ return newCounterexample;
+
+ }
+
+ private Counterexample GenerateTraceRec(
+ IList<string!>! labels, ErrorModel! errModel,
+ Block! b, Hashtable! traceNodes, BlockSeq! trace,
+ Dictionary<Absy!, CalleeCounterexampleInfo!>! calleeCounterexamples)
+ {
+ // After translation, all potential errors come from asserts.
+ CmdSeq! cmds = b.Cmds;
+ TransferCmd! transferCmd = (!)b.TransferCmd;
+ for (int i = 0; i < cmds.Length; i++)
+ {
+ Cmd! cmd = (!) cmds[i];
+
+ // Skip if 'cmd' not contained in the trace or not an assert
+ if (cmd is AssertCmd && traceNodes.Contains(cmd))
+ {
+ Counterexample! newCounterexample = AssertCmdToCounterexample((AssertCmd)cmd, transferCmd, trace, errModel, new Dictionary<Incarnation, Absy!>());
+ newCounterexample.AddCalleeCounterexample(calleeCounterexamples);
+ return newCounterexample;
+ }
+
+ // Counterexample generation for inlined procedures
+ AssumeCmd assumeCmd = cmd as AssumeCmd;
+ if (assumeCmd == null) continue;
+ NAryExpr naryExpr = assumeCmd.Expr as NAryExpr;
+ if (naryExpr == null) continue;
+ string! calleeName = naryExpr.Fun.FunctionName;
+ if (!implName2StratifiedInliningInfo.ContainsKey(calleeName)) continue;
+
+ assert calls != null;
+ int calleeId = calls.boogieExpr2Id[naryExpr];
+
+ calleeCounterexamples[assumeCmd] =
+ new CalleeCounterexampleInfo(
+ (!)GenerateTrace(labels, errModel, calleeId, implName2StratifiedInliningInfo[calleeName].impl),
+ new List<object!>());
+
+ }
+
+ GotoCmd gotoCmd = transferCmd as GotoCmd;
+ if (gotoCmd != null)
+ {
+ foreach (Block! bb in (!)gotoCmd.labelTargets)
+ {
+ if (traceNodes.Contains(bb)){
+ trace.Add(bb);
+ return GenerateTraceRec(labels, errModel, bb, traceNodes, trace, calleeCounterexamples);
+ }
+ }
+ }
+
+ return null;
+
+ }
+
+ public override Absy! Label2Absy(string! label)
+ {
+ int id = int.Parse(label);
+ assert calls != null;
+ return (Absy!) calls.mainLabel2absy[id];
+ }
+
+ public Absy! Label2Absy(string! procName, string! label)
+ {
+ int id = int.Parse(label);
+ Hashtable! l2a = (!)implName2StratifiedInliningInfo[procName].label2absy;
+ return (Absy!) l2a[id];
+ }
+
+ public override void OnResourceExceeded(string! msg)
+ {
+ //resourceExceededMessage = msg;
+ }
+
+ public override void OnProverWarning(string! msg)
+ {
+ callback.OnWarning(msg);
+ }
+ }
+
+ protected void ConvertCFG2DAG(Implementation! impl, Program! program)
+ {
+ impl.PruneUnreachableBlocks(); // This is needed for VCVariety.BlockNested, and is otherwise just an optimization
+
+ current_impl = impl;
+ variable2SequenceNumber = new Hashtable/*Variable -> int*/();
+ incarnationOriginMap = new Dictionary<Incarnation, Absy!>();
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("original implementation");
+ EmitImpl(impl, false);
+ }
+ #endregion
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after desugaring sugared commands like procedure calls");
+ EmitImpl(impl, true);
+ }
+ #endregion
+
+ ComputePredecessors(impl.Blocks);
+
+ #region Convert program CFG into a DAG
+
+ #region Use the graph library to figure out where the (natural) loops are
+
+ #region Create the graph by adding the source node and each edge
+ Graph<Block>! g = GraphFromImpl(impl);
+ #endregion
+
+ g.ComputeLoops(); // this is the call that does all of the processing
+ if (!g.Reducible)
+ {
+ throw new VCGenException("Irreducible flow graphs are unsupported.");
+ }
+
+ #endregion
+
+ #region Cut the backedges, push assert/assume statements from loop header into predecessors, change them all into assume statements at top of loop, introduce havoc statements
+ foreach (Block! header in (!) g.Headers)
+ {
+ IDictionary<Block!,object> backEdgeNodes = new Dictionary<Block!,object>();
+ foreach (Block! b in (!) g.BackEdgeNodes(header)) { backEdgeNodes.Add(b, null); }
+
+ #region Find the (possibly empty) prefix of assert commands in the header, replace each assert with an assume of the same condition
+ CmdSeq prefixOfPredicateCmdsInit = new CmdSeq();
+ CmdSeq prefixOfPredicateCmdsMaintained = new CmdSeq();
+ for (int i = 0, n = header.Cmds.Length; i < n; i++)
+ {
+ PredicateCmd a = header.Cmds[i] as PredicateCmd;
+ if (a != null)
+ {
+ if (a is AssertCmd) {
+ Bpl.AssertCmd c = (AssertCmd) a;
+ Bpl.AssertCmd b = new Bpl.LoopInitAssertCmd(c.tok, c.Expr);
+ b.ErrorData = c.ErrorData;
+ prefixOfPredicateCmdsInit.Add(b);
+ b = new Bpl.LoopInvMaintainedAssertCmd(c.tok, c.Expr);
+ b.ErrorData = c.ErrorData;
+ prefixOfPredicateCmdsMaintained.Add(b);
+ header.Cmds[i] = new AssumeCmd(c.tok,c.Expr);
+ } else {
+ assert a is AssumeCmd;
+ if (Bpl.CommandLineOptions.Clo.AlwaysAssumeFreeLoopInvariants) {
+ // Usually, "free" stuff, like free loop invariants (and the assume statements
+ // that stand for such loop invariants) are ignored on the checking side. This
+ // command-line option changes that behavior to always assume the conditions.
+ prefixOfPredicateCmdsInit.Add(a);
+ prefixOfPredicateCmdsMaintained.Add(a);
+ }
+ }
+ }
+ else if ( header.Cmds[i] is CommentCmd )
+ {
+ // ignore
+ }
+ else
+ {
+ break; // stop when an assignment statement (or any other non-predicate cmd) is encountered
+ }
+ }
+ #endregion
+
+ #region Copy the prefix of predicate commands into each predecessor. Do this *before* cutting the backedge!!
+ for ( int predIndex = 0, n = header.Predecessors.Length; predIndex < n; predIndex++ )
+ {
+ Block! pred = (!)header.Predecessors[predIndex];
+
+ // Create a block between header and pred for the predicate commands if pred has more than one successor
+ GotoCmd gotocmd = (GotoCmd!)pred.TransferCmd;
+ assert gotocmd.labelNames != null; // if "pred" is really a predecessor, it may be a GotoCmd with at least one label
+ if (gotocmd.labelNames.Length > 1)
+ {
+ Block! newBlock = CreateBlockBetween(predIndex, header);
+ impl.Blocks.Add(newBlock);
+
+ // if pred is a back edge node, then now newBlock is the back edge node
+ if (backEdgeNodes.ContainsKey(pred))
+ {
+ backEdgeNodes.Remove(pred);
+ backEdgeNodes.Add(newBlock,null);
+ }
+
+ pred = newBlock;
+ }
+ // Add the predicate commands
+ if (backEdgeNodes.ContainsKey(pred)){
+ pred.Cmds.AddRange(prefixOfPredicateCmdsMaintained);
+ }
+ else {
+ pred.Cmds.AddRange(prefixOfPredicateCmdsInit);
+ }
+ }
+ #endregion
+
+ #region Cut the back edge
+ foreach (Block! backEdgeNode in (!)backEdgeNodes.Keys)
+ {
+ Debug.Assert(backEdgeNode.TransferCmd is GotoCmd,"An node was identified as the source for a backedge, but it does not have a goto command.");
+ GotoCmd gtc = backEdgeNode.TransferCmd as GotoCmd;
+ if (gtc != null && gtc.labelTargets != null && gtc.labelTargets.Length > 1 )
+ {
+ // then remove the backedge by removing the target block from the list of gotos
+ BlockSeq remainingTargets = new BlockSeq();
+ StringSeq remainingLabels = new StringSeq();
+ assume gtc.labelNames != null;
+ for (int i = 0, n = gtc.labelTargets.Length; i < n; i++)
+ {
+ if ( gtc.labelTargets[i] != header )
+ {
+ remainingTargets.Add(gtc.labelTargets[i]);
+ remainingLabels.Add(gtc.labelNames[i]);
+ }
+ }
+ gtc.labelTargets = remainingTargets;
+ gtc.labelNames = remainingLabels;
+ }
+ else
+ {
+ // This backedge is the only out-going edge from this node.
+ // Add an "assume false" statement to the end of the statements
+ // inside of the block and change the goto command to a return command.
+ AssumeCmd ac = new AssumeCmd(Token.NoToken,Expr.False);
+ backEdgeNode.Cmds.Add(ac);
+ backEdgeNode.TransferCmd = new ReturnCmd(Token.NoToken);
+ }
+ #region Remove the backedge node from the list of predecessor nodes in the header
+ BlockSeq newPreds = new BlockSeq();
+ foreach ( Block p in header.Predecessors )
+ {
+ if ( p != backEdgeNode )
+ newPreds.Add(p);
+ }
+ header.Predecessors = newPreds;
+ #endregion
+ }
+ #endregion
+
+ #region Collect all variables that are assigned to in all of the natural loops for which this is the header
+ VariableSeq varsToHavoc = new VariableSeq();
+ foreach (Block! backEdgeNode in (!) g.BackEdgeNodes(header))
+ {
+ foreach ( Block! b in g.NaturalLoops(header,backEdgeNode) )
+ {
+ foreach ( Cmd! c in b.Cmds )
+ {
+ c.AddAssignedVariables(varsToHavoc);
+ }
+ }
+ }
+ IdentifierExprSeq havocExprs = new IdentifierExprSeq();
+ foreach ( Variable! v in varsToHavoc )
+ {
+ IdentifierExpr ie = new IdentifierExpr(Token.NoToken, v);
+ if(!havocExprs.Has(ie))
+ havocExprs.Add(ie);
+ }
+ // pass the token of the enclosing loop header to the HavocCmd so we can reconstruct
+ // the source location for this later on
+ HavocCmd hc = new HavocCmd(header.tok,havocExprs);
+ CmdSeq newCmds = new CmdSeq();
+ newCmds.Add(hc);
+ foreach ( Cmd c in header.Cmds )
+ {
+ newCmds.Add(c);
+ }
+ header.Cmds = newCmds;
+ #endregion
+ }
+ #endregion
+ #endregion Convert program CFG into a DAG
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after conversion into a DAG");
+ EmitImpl(impl, true);
+ }
+ #endregion
+ }
+
+ protected Hashtable/*TransferCmd->ReturnCmd*/! PassifyImpl(Implementation! impl, Program! program)
+ {
+ Hashtable/*TransferCmd->ReturnCmd*/ gotoCmdOrigins = new Hashtable/*TransferCmd->ReturnCmd*/();
+ Block exitBlock = GenerateUnifiedExit(impl, gotoCmdOrigins);
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after creating a unified exit block");
+ EmitImpl(impl, true);
+ }
+ #endregion
+
+ #region Insert pre- and post-conditions and where clauses as assume and assert statements
+ {
+ CmdSeq cc = new CmdSeq();
+ // where clauses of global variables
+ foreach (Declaration d in program.TopLevelDeclarations) {
+ GlobalVariable gvar = d as GlobalVariable;
+ if (gvar != null && gvar.TypedIdent.WhereExpr != null) {
+ Cmd c = new AssumeCmd(gvar.tok, gvar.TypedIdent.WhereExpr);
+ cc.Add(c);
+ }
+ }
+ // where clauses of in- and out-parameters
+ cc.AddRange(GetParamWhereClauses(impl));
+ // where clauses of local variables
+ foreach (Variable! lvar in impl.LocVars) {
+ if (lvar.TypedIdent.WhereExpr != null) {
+ Cmd c = new AssumeCmd(lvar.tok, lvar.TypedIdent.WhereExpr);
+ cc.Add(c);
+ }
+ }
+
+ // add cc and the preconditions to new blocks preceding impl.Blocks[0]
+ InjectPreconditions(impl, cc);
+
+ // append postconditions, starting in exitBlock and continuing into other blocks, if needed
+ exitBlock = InjectPostConditions(impl, exitBlock, gotoCmdOrigins);
+ }
+ #endregion
+
+ #region Support for lazy inlining
+ if (implName2LazyInliningInfo != null && implName2LazyInliningInfo.ContainsKey(impl.Name))
+ {
+ Expr! assertExpr = implName2LazyInliningInfo[impl.Name].assertExpr;
+ exitBlock.Cmds.Add(new AssertCmd(Token.NoToken, assertExpr));
+ }
+ #endregion
+
+ #region Support for lazy inlining
+ if (implName2StratifiedInliningInfo != null && implName2StratifiedInliningInfo.ContainsKey(impl.Name))
+ {
+ Expr! assertExpr = implName2StratifiedInliningInfo[impl.Name].assertExpr;
+ exitBlock.Cmds.Add(new AssertCmd(Token.NoToken, assertExpr));
+ }
+ #endregion
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after inserting pre- and post-conditions");
+ EmitImpl(impl, true);
+ }
+ #endregion
+
+ AddBlocksBetween(impl);
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after adding empty blocks as needed to catch join assumptions");
+ EmitImpl(impl, true);
+ }
+ #endregion
+
+ if (CommandLineOptions.Clo.LiveVariableAnalysis > 0) {
+ Microsoft.Boogie.LiveVariableAnalysis.ComputeLiveVariables(impl);
+ }
+
+ Hashtable exitIncarnationMap = Convert2PassiveCmd(impl);
+ if (implName2LazyInliningInfo != null && implName2LazyInliningInfo.ContainsKey(impl.Name))
+ {
+ LazyInliningInfo! info = implName2LazyInliningInfo[impl.Name];
+ info.exitIncarnationMap = exitIncarnationMap;
+ info.incarnationOriginMap = this.incarnationOriginMap;
+ }
+ if (implName2StratifiedInliningInfo != null && implName2StratifiedInliningInfo.ContainsKey(impl.Name))
+ {
+ StratifiedInliningInfo! info = implName2StratifiedInliningInfo[impl.Name];
+ info.exitIncarnationMap = exitIncarnationMap;
+ info.incarnationOriginMap = this.incarnationOriginMap;
+ }
+
+ if (CommandLineOptions.Clo.LiveVariableAnalysis == 1) {
+ Microsoft.Boogie.LiveVariableAnalysis.ClearLiveVariables(impl);
+ }
+ // TODO: fix
+ //else if (CommandLineOptions.Clo.LiveVariableAnalysis == 2) {
+ // Microsoft.Boogie.InterProcGenKill.ClearLiveVariables(impl, program);
+ //}
+
+ #region Peep-hole optimizations
+ if (CommandLineOptions.Clo.RemoveEmptyBlocks){
+ #region Get rid of empty blocks
+ {
+ Block! entryBlock = (!) impl.Blocks[0];
+ RemoveEmptyBlocks(entryBlock);
+ impl.PruneUnreachableBlocks();
+ }
+ #endregion Get rid of empty blocks
+
+ #region Debug Tracing
+ if (CommandLineOptions.Clo.TraceVerify)
+ {
+ Console.WriteLine("after peep-hole optimizations");
+ EmitImpl(impl, true);
+ }
+ #endregion
+ }
+ #endregion Peep-hole optimizations
+
+ if (CommandLineOptions.Clo.ExpandLambdas)
+ {
+ List<Expr!>! axioms;
+ List<Function!>! functions;
+ LambdaHelper.Desugar(impl, out axioms, out functions);
+ // TODO: do something with functions (Z3 currently doesn't need them)
+
+ if (axioms.Count > 0) {
+ CmdSeq cmds = new CmdSeq();
+ foreach (Expr! ax in axioms) {
+ cmds.Add(new AssumeCmd(ax.tok, ax));
+ }
+ Block! entryBlock = (!) impl.Blocks[0];
+ cmds.AddRange(entryBlock.Cmds);
+ entryBlock.Cmds = cmds;
+ }
+ }
+
+
+
+// #region Constant Folding
+// #endregion
+// #region Debug Tracing
+// if (CommandLineOptions.Clo.TraceVerify)
+// {
+// Console.WriteLine("after constant folding");
+// EmitImpl(impl, true);
+// }
+// #endregion
+
+ return gotoCmdOrigins;
+ }
+
+ private static Counterexample! LazyCounterexample(
+ ErrorModel! errModel,
+ Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo,
+ DeclFreeProverContext! context,
+ Program! program,
+ string! implName, List<int>! values)
+ {
+ VCExprTranslator! vcExprTranslator = (!)context.exprTranslator;
+ Boogie2VCExprTranslator! boogieExprTranslator = context.BoogieExprTranslator;
+ LazyInliningInfo! info = implName2LazyInliningInfo[implName];
+ BlockSeq! trace = new BlockSeq();
+ Block! b = ((!) info.impl).Blocks[0];
+ trace.Add(b);
+ VCExprVar! cfcVar = boogieExprTranslator.LookupVariable(info.controlFlowVariable);
+ string! cfcName = vcExprTranslator.Lookup(cfcVar);
+ int cfcPartition = errModel.LookupSkolemFunctionAt(cfcName + "!" + info.uniqueId, values);
+ int cfcValue = errModel.LookupPartitionValue(cfcPartition);
+
+ Dictionary<Absy!, CalleeCounterexampleInfo!> calleeCounterexamples = new Dictionary<Absy!, CalleeCounterexampleInfo!>();
+ while (true) {
+ CmdSeq! cmds = b.Cmds;
+ TransferCmd! transferCmd = (!)b.TransferCmd;
+ for (int i = 0; i < cmds.Length; i++)
+ {
+ Cmd! cmd = (!) cmds[i];
+ AssertCmd assertCmd = cmd as AssertCmd;
+ if (assertCmd != null && errModel.LookupControlFlowFunctionAt(cfcValue, assertCmd.UniqueId) == 0)
+ {
+ Counterexample newCounterexample;
+ newCounterexample = AssertCmdToCounterexample(assertCmd, transferCmd, trace, errModel, (!)info.incarnationOriginMap);
+ newCounterexample.AddCalleeCounterexample(calleeCounterexamples);
+ return newCounterexample;
+ }
+
+ AssumeCmd assumeCmd = cmd as AssumeCmd;
+ if (assumeCmd == null) continue;
+ NAryExpr naryExpr = assumeCmd.Expr as NAryExpr;
+ if (naryExpr == null) continue;
+ string! calleeName = naryExpr.Fun.FunctionName;
+ if (!implName2LazyInliningInfo.ContainsKey(calleeName)) continue;
+
+ List<int>! args = new List<int>();
+ foreach (Expr! expr in naryExpr.Args)
+ {
+ VCExprVar exprVar;
+ string name;
+ LiteralExpr litExpr = expr as LiteralExpr;
+ if (litExpr != null)
+ {
+ args.Add(errModel.valueToPartition[litExpr.Val]);
+ continue;
+ }
+
+ IdentifierExpr idExpr = expr as IdentifierExpr;
+ assert idExpr != null;
+ Variable! var = (!)idExpr.Decl;
+
+ if (var is Constant)
+ {
+ exprVar = boogieExprTranslator.LookupVariable(var);
+ name = vcExprTranslator.Lookup(exprVar);
+ args.Add(errModel.identifierToPartition[name]);
+ continue;
+ }
+
+ int index = 0;
+ List<GlobalVariable!> globalVars = program.GlobalVariables();
+ foreach (Variable! global in globalVars)
+ {
+ if (global == var) break;
+ index++;
+ }
+ if (index < globalVars.Count)
+ {
+ args.Add(values[index]);
+ continue;
+ }
+
+ foreach (Variable! input in info.impl.InParams)
+ {
+ if (input == var) break;
+ index++;
+ }
+ if (index < globalVars.Count + info.impl.InParams.Length)
+ {
+ args.Add(values[index]);
+ continue;
+ }
+
+ foreach (Variable! output in info.impl.OutParams)
+ {
+ if (output == var) break;
+ index++;
+ }
+ if (index < globalVars.Count + info.impl.InParams.Length + info.impl.OutParams.Length)
+ {
+ args.Add(values[index]);
+ continue;
+ }
+
+ exprVar = boogieExprTranslator.LookupVariable(var);
+ name = vcExprTranslator.Lookup(exprVar);
+ args.Add(errModel.LookupSkolemFunctionAt(name + "!" + info.uniqueId, values));
+ }
+ calleeCounterexamples[assumeCmd] =
+ new CalleeCounterexampleInfo(
+ LazyCounterexample(errModel, implName2LazyInliningInfo, context, program, calleeName, args),
+ errModel.PartitionsToValues(args));
+ }
+
+ GotoCmd gotoCmd = transferCmd as GotoCmd;
+ if (gotoCmd == null) break;
+ int nextBlockId = errModel.LookupControlFlowFunctionAt(cfcValue, b.UniqueId);
+ b = (Block!) ((!)info.label2absy)[nextBlockId];
+ trace.Add(b);
+ }
+ assert false;
+ }
+
+ static Counterexample TraceCounterexample(Block! b, BlockSeq! trace, ErrorModel errModel, Dictionary<Incarnation, Absy!>! incarnationOriginMap)
+ {
+ // After translation, all potential errors come from asserts.
+
+ return null;
+ }
+
+ static Counterexample TraceCounterexample(
+ Block! b, Hashtable! traceNodes, BlockSeq! trace, ErrorModel errModel,
+ Dictionary<Incarnation, Absy!>! incarnationOriginMap,
+ Dictionary<string!, LazyInliningInfo!>! implName2LazyInliningInfo,
+ DeclFreeProverContext! context, Program! program,
+ Dictionary<Absy!, CalleeCounterexampleInfo!>! calleeCounterexamples)
+ {
+ // After translation, all potential errors come from asserts.
+ CmdSeq! cmds = b.Cmds;
+ TransferCmd! transferCmd = (!)b.TransferCmd;
+ for (int i = 0; i < cmds.Length; i++)
+ {
+ Cmd! cmd = (!) cmds[i];
+
+ // Skip if 'cmd' not contained in the trace or not an assert
+ if (cmd is AssertCmd && traceNodes.Contains(cmd))
+ {
+ Counterexample! newCounterexample = AssertCmdToCounterexample((AssertCmd)cmd, transferCmd, trace, errModel, incarnationOriginMap);
+ newCounterexample.AddCalleeCounterexample(calleeCounterexamples);
+ return newCounterexample;
+ }
+
+ #region Counterexample generation for lazily inlined procedures
+ if (errModel == null) continue;
+ AssumeCmd assumeCmd = cmd as AssumeCmd;
+ if (assumeCmd == null) continue;
+ NAryExpr naryExpr = assumeCmd.Expr as NAryExpr;
+ if (naryExpr == null) continue;
+ string! calleeName = naryExpr.Fun.FunctionName;
+ if (!implName2LazyInliningInfo.ContainsKey(calleeName)) continue;
+ VCExprTranslator! vcExprTranslator = (!)context.exprTranslator;
+ Boogie2VCExprTranslator! boogieExprTranslator = context.BoogieExprTranslator;
+ List<int>! args = new List<int>();
+ foreach (Expr! expr in naryExpr.Args)
+ {
+ LiteralExpr litExpr = expr as LiteralExpr;
+ if (litExpr != null)
+ {
+ args.Add(errModel.valueToPartition[litExpr.Val]);
+ continue;
+ }
+
+ IdentifierExpr idExpr = expr as IdentifierExpr;
+ assert idExpr != null;
+ assert idExpr.Decl != null;
+ VCExprVar! var = boogieExprTranslator.LookupVariable(idExpr.Decl);
+ string! name = vcExprTranslator.Lookup(var);
+ args.Add(errModel.identifierToPartition[name]);
+ }
+ calleeCounterexamples[assumeCmd] =
+ new CalleeCounterexampleInfo(
+ LazyCounterexample(errModel, implName2LazyInliningInfo, context, program, calleeName, args),
+ errModel.PartitionsToValues(args));
+ #endregion
+ }
+
+ GotoCmd gotoCmd = transferCmd as GotoCmd;
+ if (gotoCmd != null)
+ {
+ foreach (Block! bb in (!)gotoCmd.labelTargets)
+ {
+ if (traceNodes.Contains(bb)){
+ trace.Add(bb);
+ return TraceCounterexample(bb, traceNodes, trace, errModel, incarnationOriginMap, implName2LazyInliningInfo, context, program, calleeCounterexamples);
+ }
+ }
+ }
+
+ return null;
+
+ // Debug.Fail("Could not find failing node.");
+ // throw new Microsoft.Contracts.AssertException();
+ }
+
+
+ static void /*return printable error!*/ ApplyEnhancedErrorPrintingStrategy (Bpl.Expr! expr, Hashtable /*Variable -> Expr*/! incarnationMap, MiningStrategy errorDataEnhanced, ErrorModel! errModel, Dictionary<Expr!, object>! exprToPrintableValue, List<string!>! relatedInformation, bool printInternalStateDumpOnce, Dictionary<Incarnation, Absy!>! incarnationOriginMap) {
+ if (errorDataEnhanced is ListOfMiningStrategies) {
+ ListOfMiningStrategies loms = (ListOfMiningStrategies) errorDataEnhanced;
+ List<MiningStrategy>! l = loms.msList;
+ for (int i = 0; i < l.Count; i++) {
+ MiningStrategy ms = l[i];
+ if (ms != null) {
+ ApplyEnhancedErrorPrintingStrategy(expr, incarnationMap, l[i], errModel, exprToPrintableValue, relatedInformation, false, incarnationOriginMap);
+ }
+ }
+ }
+ else if (errorDataEnhanced is EEDTemplate /*EDEverySubExpr*/) {
+ EEDTemplate eedT = (EEDTemplate) errorDataEnhanced;
+ string reason = eedT.reason;
+ List<Bpl.Expr!> listOfExprs = eedT.exprList;
+ if (listOfExprs != null) {
+ List<string> holeFillers = new List<string>();
+ for (int i = 0; i < listOfExprs.Count; i++) {
+ bool alreadySet = false;
+ foreach (KeyValuePair<Bpl.Expr!, object> kvp in exprToPrintableValue) {
+ Bpl.Expr! e = kvp.Key;
+ Bpl.Expr! f = listOfExprs[i];
+ // the strings are compared instead of the actual expressions because
+ // the expressions might not be identical, but their print-out strings will be
+ if (e.ToString() == f.ToString()) {
+ object o = kvp.Value;
+ if (o != null) {
+ holeFillers.Add(o.ToString());
+ alreadySet = true;
+ break;
+ }
+ }
+ }
+ if (!alreadySet) {
+ // no information about that Expression found, so put in <unknown>
+ holeFillers.Add("<unknown>");
+ }
+ }
+ reason = FormatReasonString(reason, holeFillers);
+ }
+ if (reason != null) {
+ relatedInformation.Add("(related information): "+reason);
+ }
+ } else {
+ // define new templates here!
+ }
+
+ if (printInternalStateDumpOnce) {
+ ComputeAndTreatHeapSuccessions(incarnationMap, errModel, incarnationOriginMap, relatedInformation);
+
+ // default action: print all values!
+ foreach (KeyValuePair<Bpl.Expr!, object> kvp in exprToPrintableValue) {
+ object o = kvp.Value;
+ if (o != null) {
+ // We do not want to print LiteralExprs because that gives things like 0 == 0.
+ // If both arguments to the string.Format are the same it is also useless,
+ // as that would print e.g. $a == $a.
+ if (!(kvp.Key is LiteralExpr)&& kvp.Key.ToString() != o.ToString()) {
+ string boogieExpr;
+ // check whether we are handling BPL or SSC input
+ if (CommandLineOptions.Clo.RunningBoogieOnSsc) {
+ boogieExpr = Helpers.PrettyPrintBplExpr(kvp.Key);
+ } else {
+ boogieExpr = kvp.Key.ToString();
+ }
+ relatedInformation.Add("(internal state dump): "+string.Format("{0} == {1}", boogieExpr, o));
+ }
+ }
+ }
+ }
+ }
+
+ static void ComputeAndTreatHeapSuccessions(System.Collections.Hashtable! incarnationMap, ErrorModel! errModel, Dictionary<Incarnation, Absy!>! incarnationOriginMap, List<string!>! relatedInformation) {
+ List<int> heapSuccList = ComputeHeapSuccessions(incarnationMap, errModel);
+ TreatHeapSuccessions(heapSuccList, incarnationMap, errModel, incarnationOriginMap, relatedInformation);
+ }
+
+ static List<int> ComputeHeapSuccessions(System.Collections.Hashtable! incarnationMap, ErrorModel! errModel) {
+ // find the heap variable
+ Variable heap = null;
+ ICollection ic = incarnationMap.Keys;
+ foreach (object o in ic) {
+ if (o is GlobalVariable) {
+ GlobalVariable gv = (GlobalVariable) o;
+ if (gv.Name == "$Heap") {
+ heap = gv;
+ }
+ }
+ }
+ List<int> heapIdSuccession = new List<int>();
+ if (heap == null) {
+ // without knowing the name of the current heap we cannot create a heap succession!
+ } else {
+ object oHeap = incarnationMap[heap];
+ if (oHeap != null) {
+ string currentHeap = oHeap.ToString();
+ int currentHeapId;
+ if (errModel.identifierToPartition.TryGetValue(currentHeap, out currentHeapId)) {
+ while (currentHeapId != -1) {
+ if (!heapIdSuccession.Contains(currentHeapId)) {
+ heapIdSuccession.Add(currentHeapId);
+ currentHeapId = ComputePredecessorHeapId(currentHeapId, errModel);
+ } else {
+ // looping behavior, just stop here and do not add this value (again!)
+ break;
+ }
+ }
+ }
+ }
+ }
+ if (heapIdSuccession.Count > 0) {
+ int heapId = heapIdSuccession[heapIdSuccession.Count-1];
+ List<string!> strl = errModel.partitionToIdentifiers[heapId];
+ if (strl != null && strl.Contains("$Heap")) {
+ // we have a proper succession of heaps that starts with $Heap
+ return heapIdSuccession;
+ } else {
+ // no proper heap succession, not starting with $Heap!
+ return null;
+ }
+ } else {
+ // no heap succession found because either the $Heap does not have a current incarnation
+ // or because (unlikely!) the model is somehow messed up
+ return null;
+ }
+ }
+
+ static int ComputePredecessorHeapId(int id, ErrorModel! errModel) {
+ //check "$HeapSucc" and "store2" functions:
+ List<int> heapSuccPredIdList = new List<int>();
+ List<List<int>> heapSuccFunc;
+ errModel.definedFunctions.TryGetValue("$HeapSucc", out heapSuccFunc);
+ if (heapSuccFunc != null) {
+ foreach (List<int> heapSuccFuncDef in heapSuccFunc) {
+ // do not look at the else case of the function def, so check .Count
+ if (heapSuccFuncDef != null && heapSuccFuncDef.Count == 3 && heapSuccFuncDef[1] == id) {
+ // make sure each predecessor is put into the list at most once
+ if (!heapSuccPredIdList.Contains(heapSuccFuncDef[0])) {
+ heapSuccPredIdList.Add(heapSuccFuncDef[0]);
+ }
+ }
+ }
+ }
+ List<int> store2PredIdList = new List<int>();;
+ List<List<int>> store2Func;
+ errModel.definedFunctions.TryGetValue("store2", out store2Func);
+ if (store2Func != null) {
+ foreach (List<int> store2FuncDef in store2Func) {
+ // do not look at the else case of the function def, so check .Count
+ if (store2FuncDef != null && store2FuncDef.Count == 5 && store2FuncDef[4] == id) {
+ // make sure each predecessor is put into the list at most once
+ if (!store2PredIdList.Contains(store2FuncDef[0])) {
+ store2PredIdList.Add(store2FuncDef[0]);
+ }
+ }
+ }
+ }
+ if (heapSuccPredIdList.Count + store2PredIdList.Count > 0) {
+ if (store2PredIdList.Count == 1) {
+ return store2PredIdList[0];
+ } else if (store2PredIdList.Count == 0) {
+ if (heapSuccPredIdList.Count == 1) {
+ return heapSuccPredIdList[0];
+ } else { //(heapSuccPredIdList.Count > 1)
+ if (heapSuccPredIdList.Count == 2) {
+ // if one of the 2 is a self-loop, take the other!
+ if (heapSuccPredIdList[0] == id) {
+ return heapSuccPredIdList[1];
+ } else if (heapSuccPredIdList[1] == id) {
+ return heapSuccPredIdList[0];
+ } else {
+ //no self-loop, two different predecessors, cannot choose
+ return -1;
+ }
+ } else {
+ // at least 3 different predecessors available, one of them could be a self-loop, but
+ // we cannot choose between the other 2 (or more) candidates
+ return -1;
+ }
+ }
+ } else {
+ // more than one result in the succession coming from store2, no way
+ // to decide which is right, end here
+ return -1;
+ }
+ } else {
+ // no predecessor found
+ return -1;
+ }
+ }
+
+ static void TreatHeapSuccessions (List<int> heapSuccessionList, System.Collections.Hashtable! incarnationMap, ErrorModel! errModel, Dictionary<Incarnation, Absy!>! incarnationOriginMap, List<string!>! relatedInformation) {
+ if (heapSuccessionList == null) {
+ // empty list of heap successions, nothing we can do!
+ return;
+ }
+ // primarily look for $o and $f (with skolem-id stuff) and then look where they were last changed!
+ // find the o and f variables
+ Variable dollarO = null;
+ Variable dollarF = null;
+ ICollection ic = incarnationMap.Keys;
+ foreach (object o in ic) {
+ if (o is BoundVariable) {
+ BoundVariable bv = (BoundVariable) o;
+ if (bv.Name == "$o") {
+ dollarO = bv;
+ }
+ else if (bv.Name == "$f") {
+ dollarF = bv;
+ }
+ }
+ }
+ if (dollarO == null || dollarF == null) {
+ // without knowing the name of the current incarnation of $Heap, $o and $f we don't do anything here
+ } else {
+ object objO = incarnationMap[dollarO];
+ object objF = incarnationMap[dollarF];
+ if (objO != null && objF != null) {
+ int zidO = errModel.identifierToPartition[objO.ToString()];
+ int zidF = errModel.identifierToPartition[objF.ToString()];
+
+ List<List<int>> select2Func = null;
+ if (errModel.definedFunctions.TryGetValue("select2", out select2Func) && select2Func != null) {
+ // check for all changes to $o.$f!
+ List<int> heapsChangedOFZid = new List<int>();
+ int oldValueZid = -1;
+ int newValueZid = -1;
+
+ for (int i = 0; i < heapSuccessionList.Count; i++) {
+ bool foundValue = false;
+ foreach (List<int> f in select2Func) {
+ if (f != null && f.Count == 4 && f[0] == heapSuccessionList[i] && f[1] == zidO && f[2] == zidF) {
+ newValueZid = f[3];
+ foundValue = true;
+ break;
+ }
+ }
+ if (!foundValue) {
+ // get default of the function once Leo&Nikolaj have changed it so the default is type correct
+ // for now treat it as a -1 !
+ // the last element of select2Func is the else case, it has only 1 element, so grab that:
+ // newValueZid = (select2Func[select2Func.Count-1])[0];
+ newValueZid = -1;
+ }
+
+ if (oldValueZid != newValueZid) {
+ // there was a change here, record that in the list:
+ if (oldValueZid != -1) {
+ // don't record a change at the "initial" location, which refers to the $Heap in
+ // its current incarnation, and is marked by the oldValueZid being uninitialized
+ heapsChangedOFZid.Add(heapSuccessionList[i-1]);
+ }
+ oldValueZid = newValueZid;
+ }
+ }
+
+ foreach (int id in heapsChangedOFZid) {
+ //get the heap name out of the errModel for this zid:
+ List<string!> l = errModel.partitionToIdentifiers[id];
+ List<string!> heaps = new List<string!>();
+ if (l!=null) {
+ foreach (string s in l) {
+ if (s.StartsWith("$Heap")) {
+ heaps.Add(s);
+ }
+ }
+ }
+ // easy case first:
+ if (heaps.Count == 1) {
+ string heapName = heaps[0];
+ // we have a string with the name of the heap, but we need to get the
+ // source location out of a map that uses Incarnations!
+
+ ICollection incOrgMKeys = incarnationOriginMap.Keys;
+ foreach (Incarnation inc in incOrgMKeys) {
+ if (inc!= null) {
+ if (inc.Name == heapName) {
+ Absy source = null;
+ incarnationOriginMap.TryGetValue(inc, out source);
+ if (source != null) {
+ if (source is Block) {
+ Block b = (Block) source;
+ string fileName = b.tok.filename;
+ if (fileName != null) {
+ fileName = fileName.Substring(fileName.LastIndexOf('\\') + 1);
+ }
+ relatedInformation.Add("(related information): Changed $o.$f here: " + fileName + "(" + b.tok.line + "," + b.tok.col + ")");
+ } else if (source is Cmd) {
+ Cmd c = (Cmd) source;
+ string fileName = c.tok.filename;
+ if (fileName != null) {
+ fileName = fileName.Substring(fileName.LastIndexOf('\\') + 1);
+ }
+ relatedInformation.Add("(related information) Changed $o.$f here: " + fileName + "(" + c.tok.line + "," + c.tok.col + ")");
+ } else {
+ assert false;
+ }
+ }
+ }
+ }
+ }
+ } else {
+ // more involved! best use some of the above code and try to synchronize joint parts
+ // here there is more than one "$Heap@i" in the partition, check if they all agree on one
+ // source location or maybe if some of them are joins (i.e. blocks) that should be ignored
+ }
+
+ }
+ }
+ }
+ }
+ }
+
+ static string FormatReasonString (string reason, List<string> holeFillers) {
+ if (holeFillers != null) {
+ // in case all elements of holeFillers are "<unknown>" we can not say anything useful
+ // so just say nothing and return null
+ bool allUnknown = true;
+ foreach (string s in holeFillers) {
+ if (s != "<unknown>") {
+ allUnknown = false;
+ break;
+ }
+ }
+ if (allUnknown) {
+ return null;
+ }
+ string[] a = holeFillers.ToArray();
+ reason = string.Format(reason, a);
+ }
+ return reason;
+ }
+
+ static object ValueFromZID (ErrorModel! errModel, int id) {
+ return ValueFromZID(errModel, id, null);
+ }
+
+ static object ValueFromZID (ErrorModel! errModel, int id, string searchForAlternate) {
+ object o = errModel.partitionToValue[id];
+ if (o != null) {
+ return o;
+ } else {
+ // more elaborate scheme to find something better, as in: look at the identifiers that
+ // this partition maps to, or similar things!
+
+ //treatment for 'null':
+ int idForNull = -1;
+ if (errModel.valueToPartition.TryGetValue("nullObject", out idForNull) && idForNull == id) {
+ return "nullObject";
+ }
+
+ string returnStr = null;
+
+ // "good identifiers" if there is no value found are 'unique consts' or
+ // '$in' parameters; '$in' parameters are treated, unclear how to get 'unique const' info
+ List<string!> identifiers = errModel.partitionToIdentifiers[id];
+ if (identifiers != null) {
+ foreach (string s in identifiers) {
+ //$in parameters are (more) interesting than other identifiers, return the
+ // first one found
+ if (s.EndsWith("$in")) {
+ returnStr = s;
+ break;
+ }
+ }
+ }
+
+ // try to get mappings from one identifier to another if there are exactly
+ // two identifiers in the partition, where one of them is the identifier for which
+ // we search for alternate encodings (third parameter of the method) [or an incarnation
+ // of such an identifier]
+ if (returnStr == null && searchForAlternate != null && identifiers != null && identifiers.Count == 2) {
+ if (identifiers[0] == searchForAlternate || identifiers[0].StartsWith(searchForAlternate + ".sk.")) {
+ returnStr = identifiers[1];
+ } else if (identifiers[1] == searchForAlternate || identifiers[1].StartsWith(searchForAlternate + ".sk.")) {
+ returnStr = identifiers[0];
+ }
+ }
+
+ if (returnStr != null) {
+ return Helpers.BeautifyBplString(returnStr);
+ }
+
+ return null;
+ }
+ }
+
+ static int TreatInterpretedFunction(string! functionName, List<int>! zargs, ErrorModel! errModel) {
+ if (zargs.Count != 2) {
+ //all interpreted functions are binary, so there have to be exactly two arguments
+ return -1;
+ }
+ else {
+ object arg0 = ValueFromZID(errModel, zargs[0]);
+ object arg1 = ValueFromZID(errModel, zargs[1]);
+ if (arg0 is BigNum && arg1 is BigNum) {
+ BigNum arg0i = (BigNum)arg0;
+ BigNum arg1i = (BigNum)arg1;
+ BigNum result;
+ if (functionName == "+") {
+ result = arg0i + arg1i;
+ } else if (functionName == "-") {
+ result = arg0i - arg1i;
+ } else /*if (functionName == "*")*/ {
+ result = arg0i * arg1i;
+ }
+ int returnId = -1;
+ if (errModel.valueToPartition.TryGetValue(result, out returnId)) {
+ return returnId;
+ } else {
+ return -1;
+ }
+ }
+ else {
+ //both arguments need to be integers for this to work!
+ return -1;
+ }
+ }
+ }
+
+ static int TreatFunction (string! functionName, List<int>! zargs, bool undefined, ErrorModel! errModel) {
+ List<List<int>> functionDef;
+ if ((!errModel.definedFunctions.TryGetValue(functionName, out functionDef) && functionName != "+" && functionName != "-" && functionName != "*") || undefined) {
+ // no fitting function found or one of the arguments is undefined
+ return -1;
+ } else {
+ if (functionName == "+" || functionName == "-" || functionName == "*") {
+ return TreatInterpretedFunction(functionName, zargs, errModel);
+ }
+ assert functionDef != null;
+ foreach (List<int> pWiseF in functionDef) {
+ assert pWiseF != null;
+ // else case in the function definition:
+ if (pWiseF.Count == 1) {
+ return pWiseF[0];
+ }
+ // number of arguments is exactly the right number
+ assert zargs.Count == pWiseF.Count - 1;
+ if (forall{int i in (0: zargs.Count); zargs[i] == pWiseF[i]}) {
+ return pWiseF[pWiseF.Count - 1];
+ }
+ }
+ // all functions should have an 'else ->' case defined, therefore this should be
+ // unreachable code!
+ assert false;
+ }
+ }
+
+ //returned int is zID
+ static int GetValuesFromModel (Bpl.Expr! expr, Hashtable /*Variable -> Expr*/! incarnationMap, ErrorModel! errModel, Dictionary<Bpl.Expr!, object>! exprToPrintableValue)
+ modifies exprToPrintableValue.*;
+ {
+ // call GetValuesFromModel on all proper subexpressions, returning their value,
+ // so they only have to be computed once!
+ if (expr is LiteralExpr) {
+ // nothing needs to be added to the exprToPrintableValue map, because e.g. 0 -> 0 is not interesting
+ object o = ((LiteralExpr) expr).Val;
+ if (o == null) {
+ o = "nullObject";
+ }
+ int idForExprVal;
+ if (errModel.valueToPartition.TryGetValue(o, out idForExprVal)) {
+ return idForExprVal;
+ } else {
+ return -1;
+ }
+ }
+ else if (expr is IdentifierExpr) {
+ // if the expression expr is in the incarnation map, then use its incarnation,
+ // otherwise just use the actual expression
+ string s = ((IdentifierExpr) expr).Name;
+ object o = null;
+ Variable v = ((IdentifierExpr) expr).Decl;
+ if (v != null && incarnationMap.ContainsKey(v)) {
+ if (incarnationMap[v] is IdentifierExpr!) {
+ s = ((IdentifierExpr!) incarnationMap[v]).Name;
+ } else if (incarnationMap[v] is LiteralExpr!) {
+ o = ((LiteralExpr!) incarnationMap[v]).Val;
+ }
+ }
+ // if o is not null, then we got a LiteralExpression, that needs separate treatment
+ if (o == null) {
+ // if the expression (respectively its incarnation) is mapped to some partition
+ // then return that id, else return the error code -1
+ if (errModel.identifierToPartition.ContainsKey(s)) {
+ int i = errModel.identifierToPartition[s];
+ // if the key is already in the map we can assume that it is the same map we would
+ // get now and thus just ignore it
+ if (!exprToPrintableValue.ContainsKey(expr)) {
+ exprToPrintableValue.Add(expr, ValueFromZID(errModel, i, ((IdentifierExpr) expr).Name));
+ }
+ return i;
+ } else {
+ return -1;
+ }
+ } else if (errModel.valueToPartition.ContainsKey(o)) {
+ int i = errModel.valueToPartition[o];
+ if (!exprToPrintableValue.ContainsKey(expr))
+ exprToPrintableValue.Add(expr, ValueFromZID(errModel, i));
+ return i;
+ } else {
+ return -1;
+ }
+ }
+ else if (expr is Bpl.NAryExpr) {
+ Bpl.NAryExpr e = (Bpl.NAryExpr)expr;
+ List<int> zargs = new List<int>();
+ bool undefined = false;
+ // do the recursion first
+ foreach (Expr argument in ((NAryExpr) expr).Args) {
+ int zid = -1;
+ if (argument != null) {
+ zid = GetValuesFromModel(argument, incarnationMap, errModel, exprToPrintableValue);
+ }
+ // if one of the arguments is 'undefined' then return -1 ('noZid') for this
+ // but make sure the recursion is complete first1
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+ }
+ IAppliable! fun = e.Fun;
+ string functionName = fun.FunctionName; // PR: convert to select1, select2, etc in case of a map?
+ // same as IndexedExpr:
+ int id = TreatFunction(functionName, zargs, undefined, errModel);
+ if (id != -1 && !exprToPrintableValue.ContainsKey(expr)) {
+ exprToPrintableValue.Add(expr, ValueFromZID(errModel, id));
+ }
+ return id;
+ }
+ else if (expr is Bpl.OldExpr) {
+ //Bpl.OldExpr e = (Bpl.OldExpr)expr;
+ // We do not know which heap is the old heap and what the latest state change was,
+ // therefore we cannot return anything useful here!
+ return -1;
+ }
+ else if (expr is Bpl.QuantifierExpr) {
+ Bpl.QuantifierExpr q = (Bpl.QuantifierExpr)expr;
+ for (int i = 0; i < q.Dummies.Length; i++) {
+ Bpl.Variable v = q.Dummies[i];
+ if (v != null) {
+ // add to the incarnation map a connection between the bound variable v
+ // of the quantifier and its skolemized incarnation, if available,
+ // i.e., search through the list of identifiers in the model and look for
+ // v.sk.(q.SkolemId), only pick those that are directly associated to a value
+ // DISCLAIMER: of course it is very well possible that one of these incarnations
+ // could be used without actually having a value, but it seems better to pick those
+ // with a value, that is they are more likely to contribute useful information to
+ // the output
+ List<Bpl.IdentifierExpr!> quantVarIncarnationList = new List<Bpl.IdentifierExpr!>();
+ List<int> incarnationZidList = new List<int>();
+ int numberOfNonNullValueIncarnations = 0;
+ for (int j = 0; j < errModel.partitionToIdentifiers.Count; j++){
+ List<string!> pti = errModel.partitionToIdentifiers[j];
+ if (pti != null) {
+ for (int k = 0; k < pti.Count; k++) {
+ // look for v.sk.(q.SkolemId)
+ // if there is more than one look at if there is exactly one with a non-null value
+ // associated, see above explanation
+ if (pti[k].StartsWith(v + ".sk." + q.SkolemId) &&
+ errModel.partitionToValue[errModel.identifierToPartition[pti[k]]] != null) {
+ quantVarIncarnationList.Add(new Bpl.IdentifierExpr(Bpl.Token.NoToken, pti[k], new Bpl.UnresolvedTypeIdentifier(Token.NoToken, "TName")));
+ incarnationZidList.Add(j);
+ if (errModel.partitionToValue[errModel.identifierToPartition[pti[k]]] != null) {
+ numberOfNonNullValueIncarnations++;
+ }
+ }
+ }
+ }
+ }
+ // only one such variable found, associate it with v
+ if (quantVarIncarnationList.Count == 1) {
+ incarnationMap[v] = quantVarIncarnationList[0];
+ } else if (quantVarIncarnationList.Count > 1 && numberOfNonNullValueIncarnations == 1) {
+ // if there are multiple candidate incarnations and exactly one of them has a value
+ // we can pick that one; otherwise it is not clear how to pick one out of multiple
+ // incarnations without a value or out of multiple incarnations with a value associated
+ for (int n = 0; n < incarnationZidList.Count; n++) {
+ if (errModel.partitionToValue[incarnationZidList[n]] != null) {
+ // quantVarIncarnationList and incarnationZidList are indexed in lockstep, so if
+ // for the associated zid the partitionToValue map is non-null then that is the one
+ // thus distinguished incarnation we want to put into the incarnationMap
+ incarnationMap[v] = quantVarIncarnationList[n];
+ break;
+ }
+ }
+ }
+ }
+ }
+ // generate the value of the body but do not return that outside
+ GetValuesFromModel(q.Body, incarnationMap, errModel, exprToPrintableValue);
+ // the quantifier cannot contribute any one value to the rest of the
+ // expression, thus just return -1
+ return -1;
+ }
+ else if (expr is Bpl.BvExtractExpr) {
+ Bpl.BvExtractExpr ex = (Bpl.BvExtractExpr) expr;
+ Bpl.Expr e0 = ex.Bitvector;
+ Bpl.Expr e1 = new LiteralExpr(Token.NoToken, BigNum.FromInt(ex.Start));
+ Bpl.Expr e2 = new LiteralExpr(Token.NoToken, BigNum.FromInt(ex.End));
+ string functionName = "$bv_extract";
+ List<int> zargs = new List<int>();
+ bool undefined = false;
+
+ int zid = -1;
+ zid = GetValuesFromModel(e0, incarnationMap, errModel, exprToPrintableValue);
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+
+ zid = -1;
+ zid = GetValuesFromModel(e1, incarnationMap, errModel, exprToPrintableValue);
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+
+ zid = -1;
+ zid = GetValuesFromModel(e2, incarnationMap, errModel, exprToPrintableValue);
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+
+ //same as NAryExpr:
+ int id = TreatFunction(functionName, zargs, undefined, errModel);
+ if (id != -1 && !exprToPrintableValue.ContainsKey(expr)) {
+ exprToPrintableValue.Add(expr, ValueFromZID(errModel, id));
+ }
+ return id;
+ }
+ else if (expr is Bpl.BvConcatExpr) {
+ // see comment above
+ Bpl.BvConcatExpr bvc = (Bpl.BvConcatExpr) expr;
+ string functionName = "$bv_concat";
+ List<int> zargs = new List<int>();
+ bool undefined = false;
+
+ int zid = -1;
+ zid = GetValuesFromModel(bvc.E0, incarnationMap, errModel, exprToPrintableValue);
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+
+ zid = -1;
+ zid = GetValuesFromModel(bvc.E0, incarnationMap, errModel, exprToPrintableValue);
+ if (zid == -1) {
+ undefined = true;
+ }
+ zargs.Add(zid);
+
+ //same as NAryExpr:
+ int id = TreatFunction(functionName, zargs, undefined, errModel);
+ if (id != -1 && !exprToPrintableValue.ContainsKey(expr)) {
+ exprToPrintableValue.Add(expr, ValueFromZID(errModel, id));
+ }
+ return id;
+ }
+ else {
+ assert false; // unexpected Bpl.Expr
+ }
+ return -1;
+ }
+
+ static Counterexample! AssertCmdToCounterexample (AssertCmd! cmd, TransferCmd! transferCmd, BlockSeq! trace, ErrorModel errModel, Dictionary<Incarnation, Absy!>! incarnationOriginMap) {
+ List<string!>! relatedInformation = new List<string!>();
+ if (CommandLineOptions.Clo.EnhancedErrorMessages == 1) {
+ if (cmd.OrigExpr != null && cmd.IncarnationMap != null && errModel != null) {
+
+ // get all possible information first
+ Dictionary<Expr!, object> exprToPrintableValue = new Dictionary<Expr!, object>();
+ GetValuesFromModel(cmd.OrigExpr, cmd.IncarnationMap, errModel, exprToPrintableValue);
+ // then apply the strategies
+ ApplyEnhancedErrorPrintingStrategy(cmd.OrigExpr, cmd.IncarnationMap, cmd.ErrorDataEnhanced, errModel, exprToPrintableValue, relatedInformation, true, incarnationOriginMap);
+ }
+ }
+
+ // See if it is a special assert inserted in translation
+ if (cmd is AssertRequiresCmd)
+ {
+ AssertRequiresCmd! assertCmd = (AssertRequiresCmd)cmd;
+ CallCounterexample cc = new CallCounterexample(trace, assertCmd.Call, assertCmd.Requires);
+ cc.relatedInformation = relatedInformation;
+ return cc;
+ }
+ else if (cmd is AssertEnsuresCmd)
+ {
+ AssertEnsuresCmd! assertCmd = (AssertEnsuresCmd)cmd;
+ ReturnCounterexample rc = new ReturnCounterexample(trace, transferCmd, assertCmd.Ensures);
+ rc.relatedInformation = relatedInformation;
+ return rc;
+ }
+ else
+ {
+ AssertCounterexample ac = new AssertCounterexample(trace, (AssertCmd)cmd);
+ ac.relatedInformation = relatedInformation;
+ return ac;
+ }
+ }
+
+// static void EmitImpl(Implementation! impl, bool printDesugarings) {
+// int oldPrintUnstructured = CommandLineOptions.Clo.PrintUnstructured;
+// CommandLineOptions.Clo.PrintUnstructured = 2; // print only the unstructured program
+// bool oldPrintDesugaringSetting = CommandLineOptions.Clo.PrintDesugarings;
+// CommandLineOptions.Clo.PrintDesugarings = printDesugarings;
+// impl.Emit(new TokenTextWriter("<console>", Console.Out, false), 0);
+// CommandLineOptions.Clo.PrintDesugarings = oldPrintDesugaringSetting;
+// CommandLineOptions.Clo.PrintUnstructured = oldPrintUnstructured;
+// }
+
+ static VCExpr! LetVC(Block! startBlock,
+ Variable controlFlowVariable,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ ProverContext! proverCtxt)
+ {
+ Hashtable/*<Block, LetVariable!>*/! blockVariables = new Hashtable/*<Block, LetVariable!!>*/();
+ List<VCExprLetBinding!>! bindings = new List<VCExprLetBinding!>();
+ VCExpr startCorrect = LetVC(startBlock, controlFlowVariable, label2absy, blockVariables, bindings, proverCtxt);
+ return proverCtxt.ExprGen.Let(bindings, startCorrect);
+ }
+
+ static VCExpr! LetVC(Block! block,
+ Variable controlFlowVariable,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ Hashtable/*<Block, VCExprVar!>*/! blockVariables,
+ List<VCExprLetBinding!>! bindings,
+ ProverContext! proverCtxt)
+ {
+ VCExpressionGenerator! gen = proverCtxt.ExprGen;
+ VCExprVar v = (VCExprVar)blockVariables[block];
+ if (v == null) {
+ /*
+ * For block A (= block), generate:
+ * LET_binding A_correct = wp(A_body, (/\ S \in Successors(A) :: S_correct))
+ * with the side effect of adding the let bindings to "bindings" for any
+ * successor not yet visited.
+ */
+ VCExpr SuccCorrect;
+ GotoCmd gotocmd = block.TransferCmd as GotoCmd;
+ if (gotocmd == null) {
+ SuccCorrect = VCExpressionGenerator.True;
+ } else {
+ assert gotocmd.labelTargets != null;
+ List<VCExpr!> SuccCorrectVars = new List<VCExpr!>(gotocmd.labelTargets.Length);
+ foreach (Block! successor in gotocmd.labelTargets) {
+ VCExpr s = LetVC(successor, controlFlowVariable, label2absy, blockVariables, bindings, proverCtxt);
+ if (controlFlowVariable != null)
+ {
+ VCExprVar controlFlowVariableExpr = proverCtxt.BoogieExprTranslator.LookupVariable(controlFlowVariable);
+ VCExpr controlFlowFunctionAppl = gen.ControlFlowFunctionApplication(controlFlowVariableExpr, gen.Integer(BigNum.FromInt(block.UniqueId)));
+ VCExpr controlTransferExpr = gen.Eq(controlFlowFunctionAppl, gen.Integer(BigNum.FromInt(successor.UniqueId)));
+ s = gen.Implies(controlTransferExpr, s);
+ }
+ SuccCorrectVars.Add(s);
+ }
+ SuccCorrect = gen.NAry(VCExpressionGenerator.AndOp, SuccCorrectVars);
+ }
+
+
+ VCContext context = new VCContext(label2absy, proverCtxt, controlFlowVariable);
+ VCExpr vc = Wlp.Block(block, SuccCorrect, context);
+
+ v = gen.Variable(block.Label + "_correct", Bpl.Type.Bool);
+ bindings.Add(gen.LetBinding(v, vc));
+ blockVariables.Add(block, v);
+ }
+ return v;
+ }
+
+ static VCExpr! DagVC(Block! block,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ Hashtable/*<Block, VCExpr!>*/! blockEquations,
+ ProverContext! proverCtxt)
+ {
+ VCExpressionGenerator! gen = proverCtxt.ExprGen;
+ VCExpr vc = (VCExpr)blockEquations[block];
+ if (vc != null) {
+ return vc;
+ }
+
+ /*
+ * For block A (= block), generate:
+ * wp(A_body, (/\ S \in Successors(A) :: DagVC(S)))
+ */
+ VCExpr SuccCorrect = null;
+ GotoCmd gotocmd = block.TransferCmd as GotoCmd;
+ if (gotocmd != null)
+ {
+ foreach (Block! successor in (!)gotocmd.labelTargets) {
+ VCExpr c = DagVC(successor, label2absy, blockEquations, proverCtxt);
+ SuccCorrect = SuccCorrect == null ? c : gen.And(SuccCorrect, c);
+ }
+ }
+ if (SuccCorrect == null) {
+ SuccCorrect = VCExpressionGenerator.True;
+ }
+
+ VCContext context = new VCContext(label2absy, proverCtxt);
+ vc = Wlp.Block(block, SuccCorrect, context);
+
+ // gen.MarkAsSharedFormula(vc); PR: don't know yet what to do with this guy
+
+ blockEquations.Add(block, vc);
+ return vc;
+ }
+
+ static VCExpr! FlatBlockVC(Implementation! impl,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ bool local, bool reach, bool doomed,
+ ProverContext! proverCtxt)
+ requires local ==> !reach; // "reach" must be false for local
+ {
+ VCExpressionGenerator! gen = proverCtxt.ExprGen;
+ Hashtable/* Block --> VCExprVar */ BlkCorrect = BlockVariableMap(impl.Blocks, "_correct", gen);
+ Hashtable/* Block --> VCExprVar */ BlkReached = reach ? BlockVariableMap(impl.Blocks, "_reached", gen) : null;
+
+ List<Block!> blocks = impl.Blocks;
+ // block sorting is now done on the VCExpr
+ // if (!local && ((!)CommandLineOptions.Clo.TheProverFactory).NeedsBlockSorting) {
+ // blocks = SortBlocks(blocks);
+ // }
+
+ VCExpr proofObligation;
+ if (!local) {
+ proofObligation = (VCExprVar!)BlkCorrect[impl.Blocks[0]];
+ } else {
+ List<VCExpr!> conjuncts = new List<VCExpr!>(blocks.Count);
+ foreach (Block! b in blocks) {
+ VCExpr v = (VCExprVar!)BlkCorrect[b];
+ conjuncts.Add(v);
+ }
+ proofObligation = gen.NAry(VCExpressionGenerator.AndOp, conjuncts);
+ }
+
+ VCContext! context = new VCContext(label2absy, proverCtxt);
+
+ List<VCExprLetBinding!> programSemantics = new List<VCExprLetBinding!>(blocks.Count);
+ foreach (Block! b in blocks) {
+ /*
+ * In block mode,
+ * For a return block A, generate:
+ * A_correct <== wp(A_body, true) [post-condition has been translated into an assert]
+ * For all other blocks, generate:
+ * A_correct <== wp(A_body, (/\ S \in Successors(A) :: S_correct))
+ *
+ * In doomed mode, proceed as in block mode, except for a return block A, generate:
+ * A_correct <== wp(A_body, false) [post-condition has been translated into an assert]
+ *
+ * In block reach mode, the wp(A_body,...) in the equations above change to:
+ * A_reached ==> wp(A_body,...)
+ * and the conjunction above changes to:
+ * (/\ S \in Successors(A) :: S_correct \/ (\/ T \in Successors(A) && T != S :: T_reached))
+ *
+ * In local mode, generate:
+ * A_correct <== wp(A_body, true)
+ */
+ VCExpr! SuccCorrect;
+ if (local) {
+ SuccCorrect = VCExpressionGenerator.True;
+ } else {
+ SuccCorrect = SuccessorsCorrect(b, BlkCorrect, BlkReached, doomed, gen);
+ }
+
+ VCExpr wlp = Wlp.Block(b, SuccCorrect, context);
+ if (BlkReached != null) {
+ wlp = gen.Implies((VCExprVar!)BlkReached[b], wlp);
+ }
+
+ VCExprVar okVar = (VCExprVar!)BlkCorrect[b];
+ VCExprLetBinding binding = gen.LetBinding(okVar, wlp);
+ programSemantics.Add(binding);
+ }
+
+ return gen.Let(programSemantics, proofObligation);
+ }
+
+ private static Hashtable/* Block --> VCExprVar */! BlockVariableMap(List<Block!>! blocks, string! suffix,
+ Microsoft.Boogie.VCExpressionGenerator! gen)
+ {
+ Hashtable/* Block --> VCExprVar */ map = new Hashtable/* Block --> (Let)Variable */();
+ foreach (Block! b in blocks)
+ {
+ VCExprVar! v = gen.Variable(b.Label+suffix, Bpl.Type.Bool);
+ map.Add(b, v);
+ }
+ return map;
+ }
+
+ private static VCExpr! SuccessorsCorrect(
+ Block! b,
+ Hashtable/* Block --> VCExprVar */! BlkCorrect,
+ Hashtable/* Block --> VCExprVar */ BlkReached,
+ bool doomed,
+ Microsoft.Boogie.VCExpressionGenerator! gen)
+ {
+ VCExpr SuccCorrect = null;
+ GotoCmd gotocmd = b.TransferCmd as GotoCmd;
+ if (gotocmd != null)
+ {
+ foreach (Block! successor in (!)gotocmd.labelTargets)
+ {
+ // c := S_correct
+ VCExpr c = (VCExprVar!)BlkCorrect[successor];
+ if (BlkReached != null)
+ {
+ // c := S_correct \/ Sibling0_reached \/ Sibling1_reached \/ ...;
+ foreach (Block! successorSibling in gotocmd.labelTargets)
+ {
+ if (successorSibling != successor)
+ {
+ c = gen.Or(c, (VCExprVar!)BlkReached[successorSibling]);
+ }
+ }
+ }
+ SuccCorrect = SuccCorrect == null ? c : gen.And(SuccCorrect, c);
+ }
+ }
+ if (SuccCorrect == null) {
+ return VCExpressionGenerator.True;
+ } else if (doomed) {
+ return VCExpressionGenerator.False;
+ } else {
+ return SuccCorrect;
+ }
+ }
+
+ static VCExpr! NestedBlockVC(Implementation! impl,
+ Hashtable/*<int, Absy!>*/! label2absy,
+ bool reach,
+ ProverContext! proverCtxt)
+ requires impl.Blocks.Count != 0;
+ {
+ VCExpressionGenerator! gen = proverCtxt.ExprGen;
+ Graph<Block>! g = GraphFromImpl(impl);
+
+ Hashtable/* Block --> VCExprVar */ BlkCorrect = BlockVariableMap(impl.Blocks, "_correct", gen);
+ Hashtable/* Block --> VCExprVar */ BlkReached = reach ? BlockVariableMap(impl.Blocks, "_reached", gen) : null;
+
+ Block! startBlock = (!) impl.Blocks[0];
+ VCExpr proofObligation = (VCExprVar!)BlkCorrect[startBlock];
+
+ VCContext! context = new VCContext(label2absy, proverCtxt);
+
+ Hashtable/*Block->int*/ totalOrder = new Hashtable/*Block->int*/();
+ {
+ List<Block!> blocks = impl.Blocks;
+ // block sorting is now done on the VCExpr
+ // if (((!)CommandLineOptions.Clo.TheProverFactory).NeedsBlockSorting) {
+ // blocks = SortBlocks(blocks);
+ // }
+ int i = 0;
+ foreach (Block b in blocks) {
+ totalOrder[b] = i;
+ i++;
+ }
+ }
+
+ VCExprLetBinding programSemantics = NestedBlockEquation((!)impl.Blocks[0], BlkCorrect, BlkReached, totalOrder, context, g, gen);
+ List<VCExprLetBinding!> ps = new List<VCExprLetBinding!>(1);
+ ps.Add(programSemantics);
+
+ return gen.Let(ps, proofObligation);
+ }
+
+ private static VCExprLetBinding! NestedBlockEquation(Block! b,
+ Hashtable/*Block-->VCExprVar*/! BlkCorrect,
+ Hashtable/*Block-->VCExprVar*/ BlkReached,
+ Hashtable/*Block->int*/! totalOrder,
+ VCContext! context,
+ Graph<Block>! g,
+ Microsoft.Boogie.VCExpressionGenerator! gen)
+ {
+ /*
+ * For a block b, return:
+ * LET_BINDING b_correct = wp(b_body, X)
+ * where X is:
+ * LET (THOSE d \in DirectDominates(b) :: BlockEquation(d))
+ * IN (/\ s \in Successors(b) :: s_correct)
+ *
+ * When the VC-expression generator does not support LET expresions, this
+ * will eventually turn into:
+ * b_correct <== wp(b_body, X)
+ * where X is:
+ * (/\ s \in Successors(b) :: s_correct)
+ * <==
+ * (/\ d \in DirectDominatees(b) :: BlockEquation(d))
+ *
+ * In both cases above, if BlkReached is non-null, then the wp expression
+ * is instead:
+ * b_reached ==> wp(b_body, X)
+ */
+
+ VCExpr! SuccCorrect = SuccessorsCorrect(b, BlkCorrect, null, false, gen);
+
+ List<VCExprLetBinding!> bindings = new List<VCExprLetBinding!>();
+ foreach (Block! dominee in GetSortedBlocksImmediatelyDominatedBy(g, b, totalOrder))
+ {
+ VCExprLetBinding c = NestedBlockEquation(dominee, BlkCorrect, BlkReached, totalOrder, context, g, gen);
+ bindings.Add(c);
+ }
+
+ VCExpr X = gen.Let(bindings, SuccCorrect);
+ VCExpr wlp = Wlp.Block(b, X, context);
+ if (BlkReached != null) {
+ wlp = gen.Implies((VCExprVar!)BlkReached[b], wlp);
+ }
+ VCExprVar okVar = (VCExprVar!)BlkCorrect[b];
+ return gen.LetBinding(okVar, wlp);
+ }
+
+ /// <summary>
+ /// Returns a list of g.ImmediatelyDominatedBy(b), but in a sorted order, hoping to steer around
+ /// the nondeterminism problems we've been seeing by using just this call.
+ /// </summary>
+ static List<Block!>! GetSortedBlocksImmediatelyDominatedBy(Graph<Block>! g, Block! b, Hashtable/*Block->int*/! totalOrder) {
+ List<Block!> list = new List<Block!>();
+ foreach (Block! dominee in g.ImmediatelyDominatedBy(b)) {
+ list.Add(dominee);
+ }
+ list.Sort(new Comparison<Block!>(delegate (Block! x, Block! y) {return (int)(!)totalOrder[x] - (int)(!)totalOrder[y];} ));
+ return list;
+ }
+
+ static VCExpr! VCViaStructuredProgram
+ (Implementation! impl, Hashtable/*<int, Absy!>*/! label2absy,
+ ProverContext! proverCtxt)
+ {
+ #region Convert block structure back to a "regular expression"
+ RE! r = DAG2RE.Transform((!)impl.Blocks[0]);
+ #endregion
+
+ VCContext! ctxt = new VCContext(label2absy, proverCtxt);
+ #region Send wlp(program,true) to Simplify
+ return Wlp.RegExpr(r, VCExpressionGenerator.True, ctxt);
+ #endregion
+ }
+
+ /// <summary>
+ /// Remove the empty blocks reachable from the block.
+ /// It changes the visiting state of the blocks, so that if you want to visit again the blocks, you have to reset them...
+ /// </summary>
+ static BlockSeq! RemoveEmptyBlocks(Block! b)
+ {
+ assert b.TraversingStatus == Block.VisitState.ToVisit;
+ Block renameInfo;
+ BlockSeq retVal = removeEmptyBlocksWorker(b, true, out renameInfo);
+ if (renameInfo != null && !b.tok.IsValid) {
+ bool onlyAssumes = true;
+ foreach (Cmd c in b.Cmds) {
+ if (!(c is AssumeCmd)) {
+ onlyAssumes = false;
+ break;
+ }
+ }
+ if (onlyAssumes) {
+ b.tok = renameInfo.tok;
+ b.Label = renameInfo.Label;
+ }
+ }
+ return retVal;
+ }
+
+ /// <summary>
+ /// For every not-yet-visited block n reachable from b, change n's successors to skip empty nodes.
+ /// Return the *set* of blocks reachable from b without passing through a nonempty block.
+ /// The target of any backedge is counted as a nonempty block.
+ /// If renameInfoForStartBlock is non-null, it denotes an empty block with location information, and that
+ /// information would be appropriate to display
+ /// </summary>
+ private static BlockSeq! removeEmptyBlocksWorker(Block! b, bool startNode, out Block renameInfoForStartBlock)
+ ensures renameInfoForStartBlock != null ==> renameInfoForStartBlock.tok.IsValid;
+ // ensures: b in result ==> renameInfoForStartBlock == null;
+ {
+ renameInfoForStartBlock = null;
+ BlockSeq bs = new BlockSeq();
+ GotoCmd gtc = b.TransferCmd as GotoCmd;
+
+ // b has no successors
+ if (gtc == null || gtc.labelTargets == null || gtc.labelTargets.Length == 0)
+ {
+ if (b.Cmds.Length != 0){ // only empty blocks are removed...
+ bs.Add(b);
+ } else if (b.tok.IsValid) {
+ renameInfoForStartBlock = b;
+ }
+ return bs;
+ }
+ else if (b.TraversingStatus == Block.VisitState.ToVisit) // if b has some successors and we have not seen it so far...
+ {
+ b.TraversingStatus = Block.VisitState.BeingVisited;
+
+ // Before recursing down to successors, make a sobering observation:
+ // If b has no commands and is not the start node, then it will see
+ // extinction (because it will not be included in the "return setOfSuccessors"
+ // statement below). In that case, if b has a location, then the location
+ // information would be lost. Hence, make an attempt to save the location
+ // by pushing the location onto b's successor. This can be done if (0) b has
+ // exactly one successor, (1) that successor has no location of its own, and
+ // (2) that successor has no other predecessors.
+ if (b.Cmds.Length == 0 && !startNode) {
+ // b is about to become extinct; try to save its name and location, if possible
+ if (b.tok.IsValid && gtc.labelTargets.Length == 1) {
+ Block succ = (!)gtc.labelTargets[0];
+ if (!succ.tok.IsValid && succ.Predecessors.Length == 1) {
+ succ.tok = b.tok;
+ succ.Label = b.Label;
+ }
+ }
+ }
+
+ // recursively call this method on each successor
+ // merge result into a *set* of blocks
+ Dictionary<Block,bool> mergedSuccessors = new Dictionary<Block,bool>();
+ int m = 0; // in the following loop, set renameInfoForStartBlock to the value that all recursive calls agree on, if possible; otherwise, null
+ foreach (Block! dest in gtc.labelTargets){
+ Block renameInfo;
+ BlockSeq! ys = removeEmptyBlocksWorker(dest, false, out renameInfo);
+ if (m == 0) {
+ renameInfoForStartBlock = renameInfo;
+ } else if (renameInfoForStartBlock != renameInfo) {
+ renameInfoForStartBlock = null;
+ }
+ foreach (Block successor in ys){
+ if (!mergedSuccessors.ContainsKey(successor))
+ mergedSuccessors.Add(successor,true);
+ }
+ m++;
+ }
+ b.TraversingStatus = Block.VisitState.AlreadyVisited;
+
+ BlockSeq setOfSuccessors = new BlockSeq();
+ foreach (Block d in mergedSuccessors.Keys)
+ setOfSuccessors.Add(d);
+ if (b.Cmds.Length == 0 && !startNode) {
+ // b is about to become extinct
+ if (b.tok.IsValid) {
+ renameInfoForStartBlock = b;
+ }
+ return setOfSuccessors;
+ }
+ // otherwise, update the list of successors of b to be the blocks in setOfSuccessors
+ gtc.labelTargets = setOfSuccessors;
+ gtc.labelNames = new StringSeq();
+ foreach (Block! d in setOfSuccessors)
+ gtc.labelNames.Add(d.Label);
+ if (!startNode) {
+ renameInfoForStartBlock = null;
+ }
+ return new BlockSeq(b);
+ }
+ else // b has some successors, but we are already visiting it, or we have already visited it...
+ {
+ return new BlockSeq(b);
+ }
+ }
+
+ static Graph<Block>! GraphFromImpl(Implementation! impl) {
+ Graph<Block>! g = new Graph<Block>();
+ g.AddSource((!)impl.Blocks[0]); // there is always at least one node in the graph
+ foreach (Block! b in impl.Blocks)
+ {
+ GotoCmd gtc = b.TransferCmd as GotoCmd;
+ if (gtc != null)
+ {
+ foreach (Block! dest in (!)gtc.labelTargets)
+ {
+ g.AddEdge(b,dest);
+ }
+ }
+ }
+ return g;
+ }
+
+
+ static void DumpMap(Hashtable /*Variable->Expr*/! map) {
+ foreach (DictionaryEntry de in map) {
+ Variable! v = (Variable!)de.Key;
+ Expr! e = (Expr!)de.Value;
+ Console.Write(" ");
+ v.Emit(new TokenTextWriter("<console>", Console.Out, false), 0);
+ Console.Write(" --> ");
+ e.Emit(new TokenTextWriter("<console>", Console.Out, false));
+ Console.WriteLine();
+ }
+ }
+ }
+}