private void handleStepOutOfLoop( @NotNull final Instruction prevInstruction, @NotNull Instruction nextInstruction, @NotNull final int[] loopNumber, @NotNull MultiMap<BranchingInstruction, DfaMemoryState> processedStates, @NotNull MultiMap<BranchingInstruction, DfaMemoryState> incomingStates, @NotNull List<DfaInstructionState> inFlightStates, @NotNull DfaInstructionState[] afterStates, @NotNull StateQueue queue) { if (loopNumber[prevInstruction.getIndex()] == 0 || inSameLoop(prevInstruction, nextInstruction, loopNumber)) { return; } // stepped out of loop. destroy all memory states from the loop, we don't need them anymore // but do not touch yet states being handled right now for (DfaInstructionState state : inFlightStates) { Instruction instruction = state.getInstruction(); if (inSameLoop(prevInstruction, instruction, loopNumber)) { return; } } for (DfaInstructionState state : afterStates) { Instruction instruction = state.getInstruction(); if (inSameLoop(prevInstruction, instruction, loopNumber)) { return; } } // and still in queue if (!queue.processAll( new Processor<DfaInstructionState>() { @Override public boolean process(DfaInstructionState state) { Instruction instruction = state.getInstruction(); return !inSameLoop(prevInstruction, instruction, loopNumber); } })) return; // now remove obsolete memory states final Set<BranchingInstruction> mayRemoveStatesFor = new THashSet<BranchingInstruction>(); for (Instruction instruction : myInstructions) { if (inSameLoop(prevInstruction, instruction, loopNumber) && instruction instanceof BranchingInstruction) { mayRemoveStatesFor.add((BranchingInstruction) instruction); } } for (Instruction instruction : mayRemoveStatesFor) { processedStates.remove((BranchingInstruction) instruction); incomingStates.remove((BranchingInstruction) instruction); } }
@NotNull protected DfaInstructionState[] acceptInstruction( @NotNull InstructionVisitor visitor, @NotNull DfaInstructionState instructionState) { Instruction instruction = instructionState.getInstruction(); PsiElement closure = DfaUtil.getClosureInside(instruction); if (closure instanceof PsiClass) { registerNestedClosures(instructionState, (PsiClass) closure); } else if (closure instanceof PsiLambdaExpression) { registerNestedClosures(instructionState, (PsiLambdaExpression) closure); } return instruction.accept(this, instructionState.getMemoryState(), visitor); }
private void registerNestedClosures( @NotNull DfaInstructionState instructionState, @NotNull PsiLambdaExpression expr) { DfaMemoryState state = instructionState.getMemoryState(); PsiElement body = expr.getBody(); if (body != null) { myNestedClosures.putValue(body, createClosureState(state)); } }
private void registerNestedClosures(DfaInstructionState instructionState, PsiClass nestedClass) { DfaMemoryStateImpl closureState = createClosureState(instructionState.getMemoryState()); for (PsiMethod method : nestedClass.getMethods()) { PsiCodeBlock body = method.getBody(); if (body != null) { myNestedClosures.putValue(body, closureState); } } for (PsiClassInitializer initializer : nestedClass.getInitializers()) { myNestedClosures.putValue(initializer.getBody(), closureState); } for (PsiField field : nestedClass.getFields()) { myNestedClosures.putValue(field, closureState); } }
private DfaInstructionState[] acceptInstruction( InstructionVisitor visitor, DfaInstructionState instructionState) { Instruction instruction = instructionState.getInstruction(); if (instruction instanceof MethodCallInstruction) { PsiCallExpression anchor = ((MethodCallInstruction) instruction).getCallExpression(); if (anchor instanceof PsiNewExpression) { PsiAnonymousClass anonymousClass = ((PsiNewExpression) anchor).getAnonymousClass(); if (anonymousClass != null) { registerNestedClosures(instructionState, anonymousClass); } } } else if (instruction instanceof EmptyInstruction) { PsiElement anchor = ((EmptyInstruction) instruction).getAnchor(); if (anchor instanceof PsiDeclarationStatement) { for (PsiElement element : ((PsiDeclarationStatement) anchor).getDeclaredElements()) { if (element instanceof PsiClass) { registerNestedClosures(instructionState, (PsiClass) element); } } } } return instruction.accept(this, instructionState.getMemoryState(), visitor); }
public final RunnerResult analyzeMethod( @NotNull PsiElement psiBlock, InstructionVisitor visitor, boolean ignoreAssertions, @NotNull Collection<DfaMemoryState> initialStates) { try { prepareAnalysis(psiBlock, initialStates); final ControlFlow flow = createControlFlowAnalyzer().buildControlFlow(psiBlock, ignoreAssertions); if (flow == null) return RunnerResult.NOT_APPLICABLE; int endOffset = flow.getInstructionCount(); myInstructions = flow.getInstructions(); myFields = flow.getFields(); myNestedClosures.clear(); if (LOG.isDebugEnabled()) { LOG.debug("Analyzing code block: " + psiBlock.getText()); for (int i = 0; i < myInstructions.length; i++) { Instruction instruction = myInstructions[i]; LOG.debug(i + ": " + instruction.toString()); } } Integer tooExpensiveHash = psiBlock.getUserData(TOO_EXPENSIVE_HASH); if (tooExpensiveHash != null && tooExpensiveHash == psiBlock.getText().hashCode()) { LOG.debug("Too complex because hasn't changed since being too complex already"); return RunnerResult.TOO_COMPLEX; } final ArrayList<DfaInstructionState> queue = new ArrayList<DfaInstructionState>(); for (final DfaMemoryState initialState : initialStates) { queue.add(new DfaInstructionState(myInstructions[0], initialState)); } long timeLimit = ourTimeLimit; final boolean unitTestMode = ApplicationManager.getApplication().isUnitTestMode(); WorkingTimeMeasurer measurer = new WorkingTimeMeasurer(timeLimit); int count = 0; while (!queue.isEmpty()) { if (count % 50 == 0 && !unitTestMode && measurer.isTimeOver()) { LOG.debug("Too complex because the analysis took too long"); psiBlock.putUserData(TOO_EXPENSIVE_HASH, psiBlock.getText().hashCode()); return RunnerResult.TOO_COMPLEX; } ProgressManager.checkCanceled(); DfaInstructionState instructionState = queue.remove(0); if (LOG.isDebugEnabled()) { LOG.debug(instructionState.toString()); } // System.out.println(instructionState.toString()); Instruction instruction = instructionState.getInstruction(); long distance = instructionState.getDistanceFromStart(); if (instruction instanceof BranchingInstruction) { if (!instruction.setMemoryStateProcessed( instructionState.getMemoryState().createCopy())) { LOG.debug("Too complex because too many different possible states"); return RunnerResult.TOO_COMPLEX; // Too complex :( } } DfaInstructionState[] after = acceptInstruction(visitor, instructionState); for (DfaInstructionState state : after) { Instruction nextInstruction = state.getInstruction(); if ((!(nextInstruction instanceof BranchingInstruction) || !nextInstruction.isMemoryStateProcessed(state.getMemoryState())) && instruction.getIndex() < endOffset) { state.setDistanceFromStart(distance + 1); queue.add(state); } } count++; } psiBlock.putUserData(TOO_EXPENSIVE_HASH, null); LOG.debug("Analysis ok"); return RunnerResult.OK; } catch (ArrayIndexOutOfBoundsException e) { LOG.error(psiBlock.getText(), e); // TODO fix in better times return RunnerResult.ABORTED; } catch (EmptyStackException e) { if (LOG.isDebugEnabled()) { LOG.error(e); // TODO fix in better times } return RunnerResult.ABORTED; } }
@NotNull final RunnerResult analyzeMethod( @NotNull PsiElement psiBlock, @NotNull InstructionVisitor visitor, boolean ignoreAssertions, @NotNull Collection<DfaMemoryState> initialStates) { if (PsiTreeUtil.findChildOfType(psiBlock, OuterLanguageElement.class) != null) return RunnerResult.NOT_APPLICABLE; try { final ControlFlow flow = new ControlFlowAnalyzer(myValueFactory, psiBlock, ignoreAssertions).buildControlFlow(); if (flow == null) return RunnerResult.NOT_APPLICABLE; int[] loopNumber = LoopAnalyzer.calcInLoop(flow); int endOffset = flow.getInstructionCount(); myInstructions = flow.getInstructions(); myNestedClosures.clear(); Set<Instruction> joinInstructions = ContainerUtil.newHashSet(); for (int index = 0; index < myInstructions.length; index++) { Instruction instruction = myInstructions[index]; if (instruction instanceof GotoInstruction) { joinInstructions.add(myInstructions[((GotoInstruction) instruction).getOffset()]); } else if (instruction instanceof ConditionalGotoInstruction) { joinInstructions.add( myInstructions[((ConditionalGotoInstruction) instruction).getOffset()]); } else if (instruction instanceof MethodCallInstruction && !((MethodCallInstruction) instruction).getContracts().isEmpty()) { joinInstructions.add(myInstructions[index + 1]); } } if (LOG.isDebugEnabled()) { LOG.debug("Analyzing code block: " + psiBlock.getText()); for (int i = 0; i < myInstructions.length; i++) { LOG.debug(i + ": " + myInstructions[i]); } } // for (int i = 0; i < myInstructions.length; i++) System.out.println(i + ": " + // myInstructions[i].toString()); Integer tooExpensiveHash = psiBlock.getUserData(TOO_EXPENSIVE_HASH); if (tooExpensiveHash != null && tooExpensiveHash == psiBlock.getText().hashCode()) { LOG.debug("Too complex because hasn't changed since being too complex already"); return RunnerResult.TOO_COMPLEX; } final StateQueue queue = new StateQueue(); for (final DfaMemoryState initialState : initialStates) { queue.offer(new DfaInstructionState(myInstructions[0], initialState)); } MultiMap<BranchingInstruction, DfaMemoryState> processedStates = MultiMap.createSet(); MultiMap<BranchingInstruction, DfaMemoryState> incomingStates = MultiMap.createSet(); long msLimit = shouldCheckTimeLimit() ? Registry.intValue("ide.dfa.time.limit.online") : Registry.intValue("ide.dfa.time.limit.offline"); WorkingTimeMeasurer measurer = new WorkingTimeMeasurer(msLimit * 1000 * 1000); int count = 0; while (!queue.isEmpty()) { List<DfaInstructionState> states = queue.getNextInstructionStates(joinInstructions); for (DfaInstructionState instructionState : states) { if (count++ % 1024 == 0 && measurer.isTimeOver()) { LOG.debug("Too complex because the analysis took too long"); psiBlock.putUserData(TOO_EXPENSIVE_HASH, psiBlock.getText().hashCode()); return RunnerResult.TOO_COMPLEX; } ProgressManager.checkCanceled(); if (LOG.isDebugEnabled()) { LOG.debug(instructionState.toString()); } // System.out.println(instructionState.toString()); Instruction instruction = instructionState.getInstruction(); if (instruction instanceof BranchingInstruction) { BranchingInstruction branching = (BranchingInstruction) instruction; Collection<DfaMemoryState> processed = processedStates.get(branching); if (processed.contains(instructionState.getMemoryState())) { continue; } if (processed.size() > MAX_STATES_PER_BRANCH) { LOG.debug("Too complex because too many different possible states"); return RunnerResult.TOO_COMPLEX; // Too complex :( } if (loopNumber[branching.getIndex()] != 0) { processedStates.putValue(branching, instructionState.getMemoryState().createCopy()); } } DfaInstructionState[] after = acceptInstruction(visitor, instructionState); for (DfaInstructionState state : after) { Instruction nextInstruction = state.getInstruction(); if (nextInstruction.getIndex() >= endOffset) { continue; } handleStepOutOfLoop( instruction, nextInstruction, loopNumber, processedStates, incomingStates, states, after, queue); if (nextInstruction instanceof BranchingInstruction) { BranchingInstruction branching = (BranchingInstruction) nextInstruction; if (processedStates.get(branching).contains(state.getMemoryState()) || incomingStates.get(branching).contains(state.getMemoryState())) { continue; } if (loopNumber[branching.getIndex()] != 0) { incomingStates.putValue(branching, state.getMemoryState().createCopy()); } } queue.offer(state); } } } psiBlock.putUserData(TOO_EXPENSIVE_HASH, null); LOG.debug("Analysis ok"); return RunnerResult.OK; } catch (ArrayIndexOutOfBoundsException e) { LOG.error(psiBlock.getText(), e); return RunnerResult.ABORTED; } catch (EmptyStackException e) { LOG.error(psiBlock.getText(), e); return RunnerResult.ABORTED; } }