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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
// See the LICENSE file in the project root for more information.
#nullable disable
using System.Collections.Generic;
using System.Collections.Immutable;
using System.Diagnostics;
using System.Threading;
using Microsoft.CodeAnalysis.PooledObjects;
using Roslyn.Utilities;
namespace Microsoft.CodeAnalysis.FlowAnalysis
{
internal static class CustomDataFlowAnalysis<TBlockAnalysisData>
{
/// <summary>
/// Runs dataflow analysis for the given <paramref name="analyzer"/> on the given <paramref name="controlFlowGraph"/>.
/// </summary>
/// <param name="controlFlowGraph">Control flow graph on which to execute analysis.</param>
/// <param name="analyzer">Dataflow analyzer.</param>
/// <returns>Block analysis data at the end of the exit block.</returns>
/// <remarks>
/// Algorithm for this CFG walker has been forked from <see cref="ControlFlowGraphBuilder"/>'s internal
/// implementation for basic block reachability computation: "MarkReachableBlocks",
/// we should keep them in sync as much as possible.
/// </remarks>
public static TBlockAnalysisData Run(ControlFlowGraph controlFlowGraph, DataFlowAnalyzer<TBlockAnalysisData> analyzer, CancellationToken cancellationToken)
{
cancellationToken.ThrowIfCancellationRequested();
var blocks = controlFlowGraph.Blocks;
var continueDispatchAfterFinally = PooledDictionary<ControlFlowRegion, bool>.GetInstance();
var dispatchedExceptionsFromRegions = PooledHashSet<ControlFlowRegion>.GetInstance();
var firstBlockOrdinal = 0;
var lastBlockOrdinal = blocks.Length - 1;
var unreachableBlocksToVisit = ArrayBuilder<BasicBlock>.GetInstance();
if (analyzer.AnalyzeUnreachableBlocks)
{
for (var i = firstBlockOrdinal; i <= lastBlockOrdinal; i++)
{
if (!blocks[i].IsReachable)
{
unreachableBlocksToVisit.Add(blocks[i]);
}
}
}
var initialAnalysisData = analyzer.GetCurrentAnalysisData(blocks[0]);
var result = RunCore(blocks, analyzer, firstBlockOrdinal, lastBlockOrdinal,
initialAnalysisData,
unreachableBlocksToVisit,
outOfRangeBlocksToVisit: null,
continueDispatchAfterFinally,
dispatchedExceptionsFromRegions,
cancellationToken);
Debug.Assert(unreachableBlocksToVisit.Count == 0);
unreachableBlocksToVisit.Free();
continueDispatchAfterFinally.Free();
dispatchedExceptionsFromRegions.Free();
return result;
}
private static TBlockAnalysisData RunCore(
ImmutableArray<BasicBlock> blocks,
DataFlowAnalyzer<TBlockAnalysisData> analyzer,
int firstBlockOrdinal,
int lastBlockOrdinal,
TBlockAnalysisData initialAnalysisData,
ArrayBuilder<BasicBlock> unreachableBlocksToVisit,
SortedSet<int> outOfRangeBlocksToVisit,
PooledDictionary<ControlFlowRegion, bool> continueDispatchAfterFinally,
PooledHashSet<ControlFlowRegion> dispatchedExceptionsFromRegions,
CancellationToken cancellationToken)
{
var toVisit = new SortedSet<int>();
var firstBlock = blocks[firstBlockOrdinal];
analyzer.SetCurrentAnalysisData(firstBlock, initialAnalysisData, cancellationToken);
toVisit.Add(firstBlock.Ordinal);
var processedBlocks = PooledHashSet<BasicBlock>.GetInstance();
TBlockAnalysisData resultAnalysisData = default;
do
{
cancellationToken.ThrowIfCancellationRequested();
BasicBlock current;
if (toVisit.Count > 0)
{
var min = toVisit.Min;
toVisit.Remove(min);
current = blocks[min];
}
else
{
int index;
current = null;
for (index = 0; index < unreachableBlocksToVisit.Count; index++)
{
var unreachableBlock = unreachableBlocksToVisit[index];
if (unreachableBlock.Ordinal >= firstBlockOrdinal && unreachableBlock.Ordinal <= lastBlockOrdinal)
{
current = unreachableBlock;
break;
}
}
if (current == null)
{
continue;
}
unreachableBlocksToVisit.RemoveAt(index);
if (processedBlocks.Contains(current))
{
// Already processed from a branch from another unreachable block.
continue;
}
analyzer.SetCurrentAnalysisData(current, analyzer.GetEmptyAnalysisData(), cancellationToken);
}
if (current.Ordinal < firstBlockOrdinal || current.Ordinal > lastBlockOrdinal)
{
outOfRangeBlocksToVisit.Add(current.Ordinal);
continue;
}
if (current.Ordinal == current.EnclosingRegion.FirstBlockOrdinal)
{
// We are revisiting first block of a region, so we need to again dispatch exceptions from region.
dispatchedExceptionsFromRegions.Remove(current.EnclosingRegion);
}
var fallThroughAnalysisData = analyzer.AnalyzeBlock(current, cancellationToken);
var fallThroughSuccessorIsReachable = true;
if (current.ConditionKind != ControlFlowConditionKind.None)
{
TBlockAnalysisData conditionalSuccessorAnalysisData;
(fallThroughAnalysisData, conditionalSuccessorAnalysisData) = analyzer.AnalyzeConditionalBranch(current, fallThroughAnalysisData, cancellationToken);
var conditionalSuccesorIsReachable = true;
if (current.BranchValue.ConstantValue.HasValue && current.BranchValue.ConstantValue.Value is bool constant)
{
if (constant == (current.ConditionKind == ControlFlowConditionKind.WhenTrue))
{
fallThroughSuccessorIsReachable = false;
}
else
{
conditionalSuccesorIsReachable = false;
}
}
if (conditionalSuccesorIsReachable || analyzer.AnalyzeUnreachableBlocks)
{
FollowBranch(current, current.ConditionalSuccessor, conditionalSuccessorAnalysisData);
}
}
else
{
fallThroughAnalysisData = analyzer.AnalyzeNonConditionalBranch(current, fallThroughAnalysisData, cancellationToken);
}
if (fallThroughSuccessorIsReachable || analyzer.AnalyzeUnreachableBlocks)
{
var branch = current.FallThroughSuccessor;
FollowBranch(current, branch, fallThroughAnalysisData);
if (current.EnclosingRegion.Kind == ControlFlowRegionKind.Finally &&
current.Ordinal == lastBlockOrdinal)
{
continueDispatchAfterFinally[current.EnclosingRegion] = branch.Semantics != ControlFlowBranchSemantics.Throw &&
branch.Semantics != ControlFlowBranchSemantics.Rethrow &&
current.FallThroughSuccessor.Semantics == ControlFlowBranchSemantics.StructuredExceptionHandling;
}
}
if (current.Ordinal == lastBlockOrdinal)
{
resultAnalysisData = fallThroughAnalysisData;
}
// We are using very simple approach:
// If try block is reachable, we should dispatch an exception from it, even if it is empty.
// To simplify implementation, we dispatch exception from every reachable basic block and rely
// on dispatchedExceptionsFromRegions cache to avoid doing duplicate work.
DispatchException(current.EnclosingRegion);
processedBlocks.Add(current);
}
while (toVisit.Count != 0 || unreachableBlocksToVisit.Count != 0);
return resultAnalysisData;
// Local functions.
void FollowBranch(BasicBlock current, ControlFlowBranch branch, TBlockAnalysisData currentAnalsisData)
{
if (branch == null)
{
return;
}
switch (branch.Semantics)
{
case ControlFlowBranchSemantics.None:
case ControlFlowBranchSemantics.ProgramTermination:
case ControlFlowBranchSemantics.StructuredExceptionHandling:
case ControlFlowBranchSemantics.Error:
Debug.Assert(branch.Destination == null);
return;
case ControlFlowBranchSemantics.Throw:
case ControlFlowBranchSemantics.Rethrow:
Debug.Assert(branch.Destination == null);
StepThroughFinally(current.EnclosingRegion, destinationOrdinal: lastBlockOrdinal, ref currentAnalsisData);
return;
case ControlFlowBranchSemantics.Regular:
case ControlFlowBranchSemantics.Return:
Debug.Assert(branch.Destination != null);
if (StepThroughFinally(current.EnclosingRegion, branch.Destination.Ordinal, ref currentAnalsisData))
{
var destination = branch.Destination;
var currentDestinationData = analyzer.GetCurrentAnalysisData(destination);
var mergedAnalysisData = analyzer.Merge(currentDestinationData, currentAnalsisData, cancellationToken);
// We need to analyze the destination block if both the following conditions are met:
// 1. Either the current block is reachable both destination and current are non-reachable
// 2. Either the new analysis data for destination has changed or destination block hasn't
// been processed.
if ((current.IsReachable || !destination.IsReachable) &&
(!analyzer.IsEqual(currentDestinationData, mergedAnalysisData) || !processedBlocks.Contains(destination)))
{
analyzer.SetCurrentAnalysisData(destination, mergedAnalysisData, cancellationToken);
toVisit.Add(branch.Destination.Ordinal);
}
}
return;
default:
throw ExceptionUtilities.UnexpectedValue(branch.Semantics);
}
}
// Returns whether we should proceed to the destination after finallies were taken care of.
bool StepThroughFinally(ControlFlowRegion region, int destinationOrdinal, ref TBlockAnalysisData currentAnalysisData)
{
while (!region.ContainsBlock(destinationOrdinal))
{
Debug.Assert(region.Kind != ControlFlowRegionKind.Root);
var enclosing = region.EnclosingRegion;
if (region.Kind == ControlFlowRegionKind.Try && enclosing.Kind == ControlFlowRegionKind.TryAndFinally)
{
Debug.Assert(enclosing.NestedRegions[0] == region);
Debug.Assert(enclosing.NestedRegions[1].Kind == ControlFlowRegionKind.Finally);
if (!StepThroughSingleFinally(enclosing.NestedRegions[1], ref currentAnalysisData))
{
// The point that continues dispatch is not reachable. Cancel the dispatch.
return false;
}
}
region = enclosing;
}
return true;
}
// Returns whether we should proceed with dispatch after finally was taken care of.
bool StepThroughSingleFinally(ControlFlowRegion @finally, ref TBlockAnalysisData currentAnalysisData)
{
Debug.Assert(@finally.Kind == ControlFlowRegionKind.Finally);
var previousAnalysisData = analyzer.GetCurrentAnalysisData(blocks[@finally.FirstBlockOrdinal]);
var mergedAnalysisData = analyzer.Merge(previousAnalysisData, currentAnalysisData, cancellationToken);
if (!analyzer.IsEqual(previousAnalysisData, mergedAnalysisData))
{
// For simplicity, we do a complete walk of the finally/filter region in isolation
// to make sure that the resume dispatch point is reachable from its beginning.
// It could also be reachable through invalid branches into the finally and we don't want to consider
// these cases for regular finally handling.
currentAnalysisData = RunCore(blocks,
analyzer,
@finally.FirstBlockOrdinal,
@finally.LastBlockOrdinal,
mergedAnalysisData,
unreachableBlocksToVisit,
outOfRangeBlocksToVisit: toVisit,
continueDispatchAfterFinally,
dispatchedExceptionsFromRegions,
cancellationToken);
}
if (!continueDispatchAfterFinally.TryGetValue(@finally, out var dispatch))
{
dispatch = false;
continueDispatchAfterFinally.Add(@finally, false);
}
return dispatch;
}
void DispatchException(ControlFlowRegion fromRegion)
{
do
{
if (!dispatchedExceptionsFromRegions.Add(fromRegion))
{
return;
}
var enclosing = fromRegion.Kind == ControlFlowRegionKind.Root ? null : fromRegion.EnclosingRegion;
if (fromRegion.Kind == ControlFlowRegionKind.Try)
{
switch (enclosing.Kind)
{
case ControlFlowRegionKind.TryAndFinally:
Debug.Assert(enclosing.NestedRegions[0] == fromRegion);
Debug.Assert(enclosing.NestedRegions[1].Kind == ControlFlowRegionKind.Finally);
var currentAnalysisData = analyzer.GetCurrentAnalysisData(blocks[fromRegion.FirstBlockOrdinal]);
if (!StepThroughSingleFinally(enclosing.NestedRegions[1], ref currentAnalysisData))
{
// The point that continues dispatch is not reachable. Cancel the dispatch.
return;
}
break;
case ControlFlowRegionKind.TryAndCatch:
Debug.Assert(enclosing.NestedRegions[0] == fromRegion);
DispatchExceptionThroughCatches(enclosing, startAt: 1);
break;
default:
throw ExceptionUtilities.UnexpectedValue(enclosing.Kind);
}
}
else if (fromRegion.Kind == ControlFlowRegionKind.Filter)
{
// If filter throws, dispatch is resumed at the next catch with an original exception
Debug.Assert(enclosing.Kind == ControlFlowRegionKind.FilterAndHandler);
var tryAndCatch = enclosing.EnclosingRegion;
Debug.Assert(tryAndCatch.Kind == ControlFlowRegionKind.TryAndCatch);
var index = tryAndCatch.NestedRegions.IndexOf(enclosing, startIndex: 1);
if (index > 0)
{
DispatchExceptionThroughCatches(tryAndCatch, startAt: index + 1);
fromRegion = tryAndCatch;
continue;
}
throw ExceptionUtilities.Unreachable();
}
fromRegion = enclosing;
}
while (fromRegion != null);
}
void DispatchExceptionThroughCatches(ControlFlowRegion tryAndCatch, int startAt)
{
// For simplicity, we do not try to figure out whether a catch clause definitely
// handles all exceptions.
Debug.Assert(tryAndCatch.Kind == ControlFlowRegionKind.TryAndCatch);
Debug.Assert(startAt > 0);
Debug.Assert(startAt <= tryAndCatch.NestedRegions.Length);
for (var i = startAt; i < tryAndCatch.NestedRegions.Length; i++)
{
var @catch = tryAndCatch.NestedRegions[i];
switch (@catch.Kind)
{
case ControlFlowRegionKind.Catch:
toVisit.Add(@catch.FirstBlockOrdinal);
break;
case ControlFlowRegionKind.FilterAndHandler:
var entryBlock = blocks[@catch.FirstBlockOrdinal];
Debug.Assert(@catch.NestedRegions[0].Kind == ControlFlowRegionKind.Filter);
Debug.Assert(entryBlock.Ordinal == @catch.NestedRegions[0].FirstBlockOrdinal);
toVisit.Add(entryBlock.Ordinal);
break;
default:
throw ExceptionUtilities.UnexpectedValue(@catch.Kind);
}
}
}
}
}
}
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