| //===- DataFlowAnalysis.cpp -----------------------------------------------===// |
| // |
| // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. |
| // See https://llvm.org/LICENSE.txt for license information. |
| // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception |
| // |
| //===----------------------------------------------------------------------===// |
| |
| #include "mlir/Analysis/DataFlowAnalysis.h" |
| #include "mlir/IR/Operation.h" |
| #include "mlir/Interfaces/CallInterfaces.h" |
| #include "mlir/Interfaces/ControlFlowInterfaces.h" |
| #include "llvm/ADT/SmallPtrSet.h" |
| |
| using namespace mlir; |
| using namespace mlir::detail; |
| |
| namespace { |
| /// This class contains various state used when computing the lattice elements |
| /// of a callable operation. |
| class CallableLatticeState { |
| public: |
| /// Build a lattice state with a given callable region, and a specified number |
| /// of results to be initialized to the default lattice element. |
| CallableLatticeState(ForwardDataFlowAnalysisBase &analysis, |
| Region *callableRegion, unsigned numResults) |
| : callableArguments(callableRegion->getArguments()), |
| resultLatticeElements(numResults) { |
| for (AbstractLatticeElement *&it : resultLatticeElements) |
| it = analysis.createLatticeElement(); |
| } |
| |
| /// Returns the arguments to the callable region. |
| Block::BlockArgListType getCallableArguments() const { |
| return callableArguments; |
| } |
| |
| /// Returns the lattice element for the results of the callable region. |
| auto getResultLatticeElements() { |
| return llvm::make_pointee_range(resultLatticeElements); |
| } |
| |
| /// Add a call to this callable. This is only used if the callable defines a |
| /// symbol. |
| void addSymbolCall(Operation *op) { symbolCalls.push_back(op); } |
| |
| /// Return the calls that reference this callable. This is only used |
| /// if the callable defines a symbol. |
| ArrayRef<Operation *> getSymbolCalls() const { return symbolCalls; } |
| |
| private: |
| /// The arguments of the callable region. |
| Block::BlockArgListType callableArguments; |
| |
| /// The lattice state for each of the results of this region. The return |
| /// values of the callable aren't SSA values, so we need to track them |
| /// separately. |
| SmallVector<AbstractLatticeElement *, 4> resultLatticeElements; |
| |
| /// The calls referencing this callable if this callable defines a symbol. |
| /// This removes the need to recompute symbol references during propagation. |
| /// Value based references are trivial to resolve, so they can be done |
| /// in-place. |
| SmallVector<Operation *, 4> symbolCalls; |
| }; |
| |
| /// This class represents the solver for a forward dataflow analysis. This class |
| /// acts as the propagation engine for computing which lattice elements. |
| class ForwardDataFlowSolver { |
| public: |
| /// Initialize the solver with the given top-level operation. |
| ForwardDataFlowSolver(ForwardDataFlowAnalysisBase &analysis, Operation *op); |
| |
| /// Run the solver until it converges. |
| void solve(); |
| |
| private: |
| /// Initialize the set of symbol defining callables that can have their |
| /// arguments and results tracked. 'op' is the top-level operation that the |
| /// solver is operating on. |
| void initializeSymbolCallables(Operation *op); |
| |
| /// Visit the users of the given IR that reside within executable blocks. |
| template <typename T> |
| void visitUsers(T &value) { |
| for (Operation *user : value.getUsers()) |
| if (isBlockExecutable(user->getBlock())) |
| visitOperation(user); |
| } |
| |
| /// Visit the given operation and compute any necessary lattice state. |
| void visitOperation(Operation *op); |
| |
| /// Visit the given call operation and compute any necessary lattice state. |
| void visitCallOperation(CallOpInterface op); |
| |
| /// Visit the given callable operation and compute any necessary lattice |
| /// state. |
| void visitCallableOperation(Operation *op); |
| |
| /// Visit the given region branch operation, which defines regions, and |
| /// compute any necessary lattice state. This also resolves the lattice state |
| /// of both the operation results and any nested regions. |
| void visitRegionBranchOperation( |
| RegionBranchOpInterface branch, |
| ArrayRef<AbstractLatticeElement *> operandLattices); |
| |
| /// Visit the given set of region successors, computing any necessary lattice |
| /// state. The provided function returns the input operands to the region at |
| /// the given index. If the index is 'None', the input operands correspond to |
| /// the parent operation results. |
| void visitRegionSuccessors( |
| Operation *parentOp, ArrayRef<RegionSuccessor> regionSuccessors, |
| function_ref<OperandRange(Optional<unsigned>)> getInputsForRegion); |
| |
| /// Visit the given terminator operation and compute any necessary lattice |
| /// state. |
| void |
| visitTerminatorOperation(Operation *op, |
| ArrayRef<AbstractLatticeElement *> operandLattices); |
| |
| /// Visit the given terminator operation that exits a callable region. These |
| /// are terminators with no CFG successors. |
| void visitCallableTerminatorOperation( |
| Operation *callable, Operation *terminator, |
| ArrayRef<AbstractLatticeElement *> operandLattices); |
| |
| /// Visit the given block and compute any necessary lattice state. |
| void visitBlock(Block *block); |
| |
| /// Visit argument #'i' of the given block and compute any necessary lattice |
| /// state. |
| void visitBlockArgument(Block *block, int i); |
| |
| /// Mark the entry block of the given region as executable. Returns NoChange |
| /// if the block was already marked executable. If `markPessimisticFixpoint` |
| /// is true, the arguments of the entry block are also marked as having |
| /// reached the pessimistic fixpoint. |
| ChangeResult markEntryBlockExecutable(Region *region, |
| bool markPessimisticFixpoint); |
| |
| /// Mark the given block as executable. Returns NoChange if the block was |
| /// already marked executable. |
| ChangeResult markBlockExecutable(Block *block); |
| |
| /// Returns true if the given block is executable. |
| bool isBlockExecutable(Block *block) const; |
| |
| /// Mark the edge between 'from' and 'to' as executable. |
| void markEdgeExecutable(Block *from, Block *to); |
| |
| /// Return true if the edge between 'from' and 'to' is executable. |
| bool isEdgeExecutable(Block *from, Block *to) const; |
| |
| /// Mark the given value as having reached the pessimistic fixpoint. This |
| /// means that we cannot further refine the state of this value. |
| void markPessimisticFixpoint(Value value); |
| |
| /// Mark all of the given values as having reaching the pessimistic fixpoint. |
| template <typename ValuesT> |
| void markAllPessimisticFixpoint(ValuesT values) { |
| for (auto value : values) |
| markPessimisticFixpoint(value); |
| } |
| template <typename ValuesT> |
| void markAllPessimisticFixpoint(Operation *op, ValuesT values) { |
| markAllPessimisticFixpoint(values); |
| opWorklist.push_back(op); |
| } |
| template <typename ValuesT> |
| void markAllPessimisticFixpointAndVisitUsers(ValuesT values) { |
| for (auto value : values) { |
| AbstractLatticeElement &lattice = analysis.getLatticeElement(value); |
| if (lattice.markPessimisticFixpoint() == ChangeResult::Change) |
| visitUsers(value); |
| } |
| } |
| |
| /// Returns true if the given value was marked as having reached the |
| /// pessimistic fixpoint. |
| bool isAtFixpoint(Value value) const; |
| |
| /// Merge in the given lattice 'from' into the lattice 'to'. 'owner' |
| /// corresponds to the parent operation of the lattice for 'to'. |
| void join(Operation *owner, AbstractLatticeElement &to, |
| const AbstractLatticeElement &from); |
| |
| /// A reference to the dataflow analysis being computed. |
| ForwardDataFlowAnalysisBase &analysis; |
| |
| /// The set of blocks that are known to execute, or are intrinsically live. |
| SmallPtrSet<Block *, 16> executableBlocks; |
| |
| /// The set of control flow edges that are known to execute. |
| DenseSet<std::pair<Block *, Block *>> executableEdges; |
| |
| /// A worklist containing blocks that need to be processed. |
| SmallVector<Block *, 64> blockWorklist; |
| |
| /// A worklist of operations that need to be processed. |
| SmallVector<Operation *, 64> opWorklist; |
| |
| /// The callable operations that have their argument/result state tracked. |
| DenseMap<Operation *, CallableLatticeState> callableLatticeState; |
| |
| /// A map between a call operation and the resolved symbol callable. This |
| /// avoids re-resolving symbol references during propagation. Value based |
| /// callables are trivial to resolve, so they can be done in-place. |
| DenseMap<Operation *, Operation *> callToSymbolCallable; |
| |
| /// A symbol table used for O(1) symbol lookups during simplification. |
| SymbolTableCollection symbolTable; |
| }; |
| } // end anonymous namespace |
| |
| ForwardDataFlowSolver::ForwardDataFlowSolver( |
| ForwardDataFlowAnalysisBase &analysis, Operation *op) |
| : analysis(analysis) { |
| /// Initialize the solver with the regions within this operation. |
| for (Region ®ion : op->getRegions()) { |
| // Mark the entry block as executable. The values passed to these regions |
| // are also invisible, so mark any arguments as reaching the pessimistic |
| // fixpoint. |
| markEntryBlockExecutable(®ion, /*markPessimisticFixpoint=*/true); |
| } |
| initializeSymbolCallables(op); |
| } |
| |
| void ForwardDataFlowSolver::solve() { |
| while (!blockWorklist.empty() || !opWorklist.empty()) { |
| // Process any operations in the op worklist. |
| while (!opWorklist.empty()) |
| visitUsers(*opWorklist.pop_back_val()); |
| |
| // Process any blocks in the block worklist. |
| while (!blockWorklist.empty()) |
| visitBlock(blockWorklist.pop_back_val()); |
| } |
| } |
| |
| void ForwardDataFlowSolver::initializeSymbolCallables(Operation *op) { |
| // Initialize the set of symbol callables that can have their state tracked. |
| // This tracks which symbol callable operations we can propagate within and |
| // out of. |
| auto walkFn = [&](Operation *symTable, bool allUsesVisible) { |
| Region &symbolTableRegion = symTable->getRegion(0); |
| Block *symbolTableBlock = &symbolTableRegion.front(); |
| for (auto callable : symbolTableBlock->getOps<CallableOpInterface>()) { |
| // We won't be able to track external callables. |
| Region *callableRegion = callable.getCallableRegion(); |
| if (!callableRegion) |
| continue; |
| // We only care about symbol defining callables here. |
| auto symbol = dyn_cast<SymbolOpInterface>(callable.getOperation()); |
| if (!symbol) |
| continue; |
| callableLatticeState.try_emplace(callable, analysis, callableRegion, |
| callable.getCallableResults().size()); |
| |
| // If not all of the uses of this symbol are visible, we can't track the |
| // state of the arguments. |
| if (symbol.isPublic() || (!allUsesVisible && symbol.isNested())) { |
| for (Region ®ion : callable->getRegions()) |
| markEntryBlockExecutable(®ion, /*markPessimisticFixpoint=*/true); |
| } |
| } |
| if (callableLatticeState.empty()) |
| return; |
| |
| // After computing the valid callables, walk any symbol uses to check |
| // for non-call references. We won't be able to track the lattice state |
| // for arguments to these callables, as we can't guarantee that we can see |
| // all of its calls. |
| Optional<SymbolTable::UseRange> uses = |
| SymbolTable::getSymbolUses(&symbolTableRegion); |
| if (!uses) { |
| // If we couldn't gather the symbol uses, conservatively assume that |
| // we can't track information for any nested symbols. |
| op->walk([&](CallableOpInterface op) { callableLatticeState.erase(op); }); |
| return; |
| } |
| |
| for (const SymbolTable::SymbolUse &use : *uses) { |
| // If the use is a call, track it to avoid the need to recompute the |
| // reference later. |
| if (auto callOp = dyn_cast<CallOpInterface>(use.getUser())) { |
| Operation *symCallable = callOp.resolveCallable(&symbolTable); |
| auto callableLatticeIt = callableLatticeState.find(symCallable); |
| if (callableLatticeIt != callableLatticeState.end()) { |
| callToSymbolCallable.try_emplace(callOp, symCallable); |
| |
| // We only need to record the call in the lattice if it produces any |
| // values. |
| if (callOp->getNumResults()) |
| callableLatticeIt->second.addSymbolCall(callOp); |
| } |
| continue; |
| } |
| // This use isn't a call, so don't we know all of the callers. |
| auto *symbol = symbolTable.lookupSymbolIn(op, use.getSymbolRef()); |
| auto it = callableLatticeState.find(symbol); |
| if (it != callableLatticeState.end()) { |
| for (Region ®ion : it->first->getRegions()) |
| markEntryBlockExecutable(®ion, /*markPessimisticFixpoint=*/true); |
| } |
| } |
| }; |
| SymbolTable::walkSymbolTables(op, /*allSymUsesVisible=*/!op->getBlock(), |
| walkFn); |
| } |
| |
| void ForwardDataFlowSolver::visitOperation(Operation *op) { |
| // Collect all of the lattice elements feeding into this operation. If any are |
| // not yet resolved, bail out and wait for them to resolve. |
| SmallVector<AbstractLatticeElement *, 8> operandLattices; |
| operandLattices.reserve(op->getNumOperands()); |
| for (Value operand : op->getOperands()) { |
| AbstractLatticeElement *operandLattice = |
| analysis.lookupLatticeElement(operand); |
| if (!operandLattice || operandLattice->isUninitialized()) |
| return; |
| operandLattices.push_back(operandLattice); |
| } |
| |
| // If this is a terminator operation, process any control flow lattice state. |
| if (op->hasTrait<OpTrait::IsTerminator>()) |
| visitTerminatorOperation(op, operandLattices); |
| |
| // Process call operations. The call visitor processes result values, so we |
| // can exit afterwards. |
| if (CallOpInterface call = dyn_cast<CallOpInterface>(op)) |
| return visitCallOperation(call); |
| |
| // Process callable operations. These are specially handled region operations |
| // that track dataflow via calls. |
| if (isa<CallableOpInterface>(op)) { |
| // If this callable has a tracked lattice state, it will be visited by calls |
| // that reference it instead. This way, we don't assume that it is |
| // executable unless there is a proper reference to it. |
| if (callableLatticeState.count(op)) |
| return; |
| return visitCallableOperation(op); |
| } |
| |
| // Process region holding operations. |
| if (op->getNumRegions()) { |
| // Check to see if we can reason about the internal control flow of this |
| // region operation. |
| if (auto branch = dyn_cast<RegionBranchOpInterface>(op)) |
| return visitRegionBranchOperation(branch, operandLattices); |
| |
| // If we can't, conservatively mark all regions as executable. |
| // TODO: Let the `visitOperation` method decide how to propagate |
| // information to the block arguments. |
| for (Region ®ion : op->getRegions()) |
| markEntryBlockExecutable(®ion, /*markPessimisticFixpoint=*/true); |
| } |
| |
| // If this op produces no results, it can't produce any constants. |
| if (op->getNumResults() == 0) |
| return; |
| |
| // If all of the results of this operation are already resolved, bail out |
| // early. |
| auto isAtFixpointFn = [&](Value value) { return isAtFixpoint(value); }; |
| if (llvm::all_of(op->getResults(), isAtFixpointFn)) |
| return; |
| |
| // Visit the current operation. |
| if (analysis.visitOperation(op, operandLattices) == ChangeResult::Change) |
| opWorklist.push_back(op); |
| |
| // `visitOperation` is required to define all of the result lattices. |
| assert(llvm::none_of( |
| op->getResults(), |
| [&](Value value) { |
| return analysis.getLatticeElement(value).isUninitialized(); |
| }) && |
| "expected `visitOperation` to define all result lattices"); |
| } |
| |
| void ForwardDataFlowSolver::visitCallableOperation(Operation *op) { |
| // Mark the regions as executable. If we aren't tracking lattice state for |
| // this callable, mark all of the region arguments as having reached a |
| // fixpoint. |
| bool isTrackingLatticeState = callableLatticeState.count(op); |
| for (Region ®ion : op->getRegions()) |
| markEntryBlockExecutable(®ion, !isTrackingLatticeState); |
| |
| // TODO: Add support for non-symbol callables when necessary. If the callable |
| // has non-call uses we would mark as having reached pessimistic fixpoint, |
| // otherwise allow for propagating the return values out. |
| markAllPessimisticFixpoint(op, op->getResults()); |
| } |
| |
| void ForwardDataFlowSolver::visitCallOperation(CallOpInterface op) { |
| ResultRange callResults = op->getResults(); |
| |
| // Resolve the callable operation for this call. |
| Operation *callableOp = nullptr; |
| if (Value callableValue = op.getCallableForCallee().dyn_cast<Value>()) |
| callableOp = callableValue.getDefiningOp(); |
| else |
| callableOp = callToSymbolCallable.lookup(op); |
| |
| // The callable of this call can't be resolved, mark any results overdefined. |
| if (!callableOp) |
| return markAllPessimisticFixpoint(op, callResults); |
| |
| // If this callable is tracking state, merge the argument operands with the |
| // arguments of the callable. |
| auto callableLatticeIt = callableLatticeState.find(callableOp); |
| if (callableLatticeIt == callableLatticeState.end()) |
| return markAllPessimisticFixpoint(op, callResults); |
| |
| OperandRange callOperands = op.getArgOperands(); |
| auto callableArgs = callableLatticeIt->second.getCallableArguments(); |
| for (auto it : llvm::zip(callOperands, callableArgs)) { |
| BlockArgument callableArg = std::get<1>(it); |
| AbstractLatticeElement &argValue = analysis.getLatticeElement(callableArg); |
| AbstractLatticeElement &operandValue = |
| analysis.getLatticeElement(std::get<0>(it)); |
| if (argValue.join(operandValue) == ChangeResult::Change) |
| visitUsers(callableArg); |
| } |
| |
| // Visit the callable. |
| visitCallableOperation(callableOp); |
| |
| // Merge in the lattice state for the callable results as well. |
| auto callableResults = callableLatticeIt->second.getResultLatticeElements(); |
| for (auto it : llvm::zip(callResults, callableResults)) |
| join(/*owner=*/op, |
| /*to=*/analysis.getLatticeElement(std::get<0>(it)), |
| /*from=*/std::get<1>(it)); |
| } |
| |
| void ForwardDataFlowSolver::visitRegionBranchOperation( |
| RegionBranchOpInterface branch, |
| ArrayRef<AbstractLatticeElement *> operandLattices) { |
| // Check to see which regions are executable. |
| SmallVector<RegionSuccessor, 1> successors; |
| analysis.getSuccessorsForOperands(branch, /*sourceIndex=*/llvm::None, |
| operandLattices, successors); |
| |
| // If the interface identified that no region will be executed. Mark |
| // any results of this operation as overdefined, as we can't reason about |
| // them. |
| // TODO: If we had an interface to detect pass through operands, we could |
| // resolve some results based on the lattice state of the operands. We could |
| // also allow for the parent operation to have itself as a region successor. |
| if (successors.empty()) |
| return markAllPessimisticFixpoint(branch, branch->getResults()); |
| return visitRegionSuccessors( |
| branch, successors, [&](Optional<unsigned> index) { |
| assert(index && "expected valid region index"); |
| return branch.getSuccessorEntryOperands(*index); |
| }); |
| } |
| |
| void ForwardDataFlowSolver::visitRegionSuccessors( |
| Operation *parentOp, ArrayRef<RegionSuccessor> regionSuccessors, |
| function_ref<OperandRange(Optional<unsigned>)> getInputsForRegion) { |
| for (const RegionSuccessor &it : regionSuccessors) { |
| Region *region = it.getSuccessor(); |
| ValueRange succArgs = it.getSuccessorInputs(); |
| |
| // Check to see if this is the parent operation. |
| if (!region) { |
| ResultRange results = parentOp->getResults(); |
| if (llvm::all_of(results, [&](Value res) { return isAtFixpoint(res); })) |
| continue; |
| |
| // Mark the results outside of the input range as having reached the |
| // pessimistic fixpoint. |
| // TODO: This isn't exactly ideal. There may be situations in which a |
| // region operation can provide information for certain results that |
| // aren't part of the control flow. |
| if (succArgs.size() != results.size()) { |
| opWorklist.push_back(parentOp); |
| if (succArgs.empty()) { |
| markAllPessimisticFixpoint(results); |
| continue; |
| } |
| |
| unsigned firstResIdx = succArgs[0].cast<OpResult>().getResultNumber(); |
| markAllPessimisticFixpoint(results.take_front(firstResIdx)); |
| markAllPessimisticFixpoint( |
| results.drop_front(firstResIdx + succArgs.size())); |
| } |
| |
| // Update the lattice for any operation results. |
| OperandRange operands = getInputsForRegion(/*index=*/llvm::None); |
| for (auto it : llvm::zip(succArgs, operands)) |
| join(parentOp, analysis.getLatticeElement(std::get<0>(it)), |
| analysis.getLatticeElement(std::get<1>(it))); |
| continue; |
| } |
| assert(!region->empty() && "expected region to be non-empty"); |
| Block *entryBlock = ®ion->front(); |
| markBlockExecutable(entryBlock); |
| |
| // If all of the arguments have already reached a fixpoint, the arguments |
| // have already been fully resolved. |
| Block::BlockArgListType arguments = entryBlock->getArguments(); |
| if (llvm::all_of(arguments, [&](Value arg) { return isAtFixpoint(arg); })) |
| continue; |
| |
| // Mark any arguments that do not receive inputs as having reached a |
| // pessimistic fixpoint, we won't be able to discern if they are constant. |
| // TODO: This isn't exactly ideal. There may be situations in which a |
| // region operation can provide information for certain results that |
| // aren't part of the control flow. |
| if (succArgs.size() != arguments.size()) { |
| if (succArgs.empty()) { |
| markAllPessimisticFixpoint(arguments); |
| continue; |
| } |
| |
| unsigned firstArgIdx = succArgs[0].cast<BlockArgument>().getArgNumber(); |
| markAllPessimisticFixpointAndVisitUsers( |
| arguments.take_front(firstArgIdx)); |
| markAllPessimisticFixpointAndVisitUsers( |
| arguments.drop_front(firstArgIdx + succArgs.size())); |
| } |
| |
| // Update the lattice of arguments that have inputs from the predecessor. |
| OperandRange succOperands = getInputsForRegion(region->getRegionNumber()); |
| for (auto it : llvm::zip(succArgs, succOperands)) { |
| AbstractLatticeElement &argValue = |
| analysis.getLatticeElement(std::get<0>(it)); |
| AbstractLatticeElement &operandValue = |
| analysis.getLatticeElement(std::get<1>(it)); |
| if (argValue.join(operandValue) == ChangeResult::Change) |
| visitUsers(std::get<0>(it)); |
| } |
| } |
| } |
| |
| void ForwardDataFlowSolver::visitTerminatorOperation( |
| Operation *op, ArrayRef<AbstractLatticeElement *> operandLattices) { |
| // If this operation has no successors, we treat it as an exiting terminator. |
| if (op->getNumSuccessors() == 0) { |
| Region *parentRegion = op->getParentRegion(); |
| Operation *parentOp = parentRegion->getParentOp(); |
| |
| // Check to see if this is a terminator for a callable region. |
| if (isa<CallableOpInterface>(parentOp)) |
| return visitCallableTerminatorOperation(parentOp, op, operandLattices); |
| |
| // Otherwise, check to see if the parent tracks region control flow. |
| auto regionInterface = dyn_cast<RegionBranchOpInterface>(parentOp); |
| if (!regionInterface || !isBlockExecutable(parentOp->getBlock())) |
| return; |
| |
| // Query the set of successors of the current region using the current |
| // optimistic lattice state. |
| SmallVector<RegionSuccessor, 1> regionSuccessors; |
| analysis.getSuccessorsForOperands(regionInterface, |
| parentRegion->getRegionNumber(), |
| operandLattices, regionSuccessors); |
| if (regionSuccessors.empty()) |
| return; |
| |
| // Try to get "region-like" successor operands if possible in order to |
| // propagate the operand states to the successors. |
| if (isRegionReturnLike(op)) { |
| return visitRegionSuccessors( |
| parentOp, regionSuccessors, [&](Optional<unsigned> regionIndex) { |
| // Determine the individual region successor operands for the given |
| // region index (if any). |
| return *getRegionBranchSuccessorOperands(op, regionIndex); |
| }); |
| } |
| |
| // If this terminator is not "region-like", conservatively mark all of the |
| // successor values as having reached the pessimistic fixpoint. |
| for (auto &it : regionSuccessors) { |
| // If the successor is a region, mark the entry block as executable so |
| // that we visit operations defined within. If the successor is the |
| // parent operation, we simply mark the control flow results as having |
| // reached the pessimistic state. |
| if (Region *region = it.getSuccessor()) |
| markEntryBlockExecutable(region, /*markPessimisticFixpoint=*/true); |
| else |
| markAllPessimisticFixpointAndVisitUsers(it.getSuccessorInputs()); |
| } |
| } |
| |
| // Try to resolve to a specific set of successors with the current optimistic |
| // lattice state. |
| Block *block = op->getBlock(); |
| if (auto branch = dyn_cast<BranchOpInterface>(op)) { |
| SmallVector<Block *> successors; |
| if (succeeded(analysis.getSuccessorsForOperands(branch, operandLattices, |
| successors))) { |
| for (Block *succ : successors) |
| markEdgeExecutable(block, succ); |
| return; |
| } |
| } |
| |
| // Otherwise, conservatively treat all edges as executable. |
| for (Block *succ : op->getSuccessors()) |
| markEdgeExecutable(block, succ); |
| } |
| |
| void ForwardDataFlowSolver::visitCallableTerminatorOperation( |
| Operation *callable, Operation *terminator, |
| ArrayRef<AbstractLatticeElement *> operandLattices) { |
| // If there are no exiting values, we have nothing to track. |
| if (terminator->getNumOperands() == 0) |
| return; |
| |
| // If this callable isn't tracking any lattice state there is nothing to do. |
| auto latticeIt = callableLatticeState.find(callable); |
| if (latticeIt == callableLatticeState.end()) |
| return; |
| assert(callable->getNumResults() == 0 && "expected symbol callable"); |
| |
| // If this terminator is not "return-like", conservatively mark all of the |
| // call-site results as having reached the pessimistic fixpoint. |
| auto callableResultLattices = latticeIt->second.getResultLatticeElements(); |
| if (!terminator->hasTrait<OpTrait::ReturnLike>()) { |
| for (auto &it : callableResultLattices) |
| it.markPessimisticFixpoint(); |
| for (Operation *call : latticeIt->second.getSymbolCalls()) |
| markAllPessimisticFixpoint(call, call->getResults()); |
| return; |
| } |
| |
| // Merge the lattice state for terminator operands into the results. |
| ChangeResult result = ChangeResult::NoChange; |
| for (auto it : llvm::zip(operandLattices, callableResultLattices)) |
| result |= std::get<1>(it).join(*std::get<0>(it)); |
| if (result == ChangeResult::NoChange) |
| return; |
| |
| // If any of the result lattices changed, update the callers. |
| for (Operation *call : latticeIt->second.getSymbolCalls()) |
| for (auto it : llvm::zip(call->getResults(), callableResultLattices)) |
| join(call, analysis.getLatticeElement(std::get<0>(it)), std::get<1>(it)); |
| } |
| |
| void ForwardDataFlowSolver::visitBlock(Block *block) { |
| // If the block is not the entry block we need to compute the lattice state |
| // for the block arguments. Entry block argument lattices are computed |
| // elsewhere, such as when visiting the parent operation. |
| if (!block->isEntryBlock()) { |
| for (int i : llvm::seq<int>(0, block->getNumArguments())) |
| visitBlockArgument(block, i); |
| } |
| |
| // Visit all of the operations within the block. |
| for (Operation &op : *block) |
| visitOperation(&op); |
| } |
| |
| void ForwardDataFlowSolver::visitBlockArgument(Block *block, int i) { |
| BlockArgument arg = block->getArgument(i); |
| AbstractLatticeElement &argLattice = analysis.getLatticeElement(arg); |
| if (argLattice.isAtFixpoint()) |
| return; |
| |
| ChangeResult updatedLattice = ChangeResult::NoChange; |
| for (auto it = block->pred_begin(), e = block->pred_end(); it != e; ++it) { |
| Block *pred = *it; |
| |
| // We only care about this predecessor if it is going to execute. |
| if (!isEdgeExecutable(pred, block)) |
| continue; |
| |
| // Try to get the operand forwarded by the predecessor. If we can't reason |
| // about the terminator of the predecessor, mark as having reached a |
| // fixpoint. |
| Optional<OperandRange> branchOperands; |
| if (auto branch = dyn_cast<BranchOpInterface>(pred->getTerminator())) |
| branchOperands = branch.getSuccessorOperands(it.getSuccessorIndex()); |
| if (!branchOperands) { |
| updatedLattice |= argLattice.markPessimisticFixpoint(); |
| break; |
| } |
| |
| // If the operand hasn't been resolved, it is uninitialized and can merge |
| // with anything. |
| AbstractLatticeElement *operandLattice = |
| analysis.lookupLatticeElement((*branchOperands)[i]); |
| if (!operandLattice) |
| continue; |
| |
| // Otherwise, join the operand lattice into the argument lattice. |
| updatedLattice |= argLattice.join(*operandLattice); |
| if (argLattice.isAtFixpoint()) |
| break; |
| } |
| |
| // If the lattice changed, visit users of the argument. |
| if (updatedLattice == ChangeResult::Change) |
| visitUsers(arg); |
| } |
| |
| ChangeResult |
| ForwardDataFlowSolver::markEntryBlockExecutable(Region *region, |
| bool markPessimisticFixpoint) { |
| if (!region->empty()) { |
| if (markPessimisticFixpoint) |
| markAllPessimisticFixpoint(region->front().getArguments()); |
| return markBlockExecutable(®ion->front()); |
| } |
| return ChangeResult::NoChange; |
| } |
| |
| ChangeResult ForwardDataFlowSolver::markBlockExecutable(Block *block) { |
| bool marked = executableBlocks.insert(block).second; |
| if (marked) |
| blockWorklist.push_back(block); |
| return marked ? ChangeResult::Change : ChangeResult::NoChange; |
| } |
| |
| bool ForwardDataFlowSolver::isBlockExecutable(Block *block) const { |
| return executableBlocks.count(block); |
| } |
| |
| void ForwardDataFlowSolver::markEdgeExecutable(Block *from, Block *to) { |
| executableEdges.insert(std::make_pair(from, to)); |
| |
| // Mark the destination as executable, and reprocess its arguments if it was |
| // already executable. |
| if (markBlockExecutable(to) == ChangeResult::NoChange) { |
| for (int i : llvm::seq<int>(0, to->getNumArguments())) |
| visitBlockArgument(to, i); |
| } |
| } |
| |
| bool ForwardDataFlowSolver::isEdgeExecutable(Block *from, Block *to) const { |
| return executableEdges.count(std::make_pair(from, to)); |
| } |
| |
| void ForwardDataFlowSolver::markPessimisticFixpoint(Value value) { |
| analysis.getLatticeElement(value).markPessimisticFixpoint(); |
| } |
| |
| bool ForwardDataFlowSolver::isAtFixpoint(Value value) const { |
| if (auto *lattice = analysis.lookupLatticeElement(value)) |
| return lattice->isAtFixpoint(); |
| return false; |
| } |
| |
| void ForwardDataFlowSolver::join(Operation *owner, AbstractLatticeElement &to, |
| const AbstractLatticeElement &from) { |
| if (to.join(from) == ChangeResult::Change) |
| opWorklist.push_back(owner); |
| } |
| |
| //===----------------------------------------------------------------------===// |
| // AbstractLatticeElement |
| //===----------------------------------------------------------------------===// |
| |
| AbstractLatticeElement::~AbstractLatticeElement() {} |
| |
| //===----------------------------------------------------------------------===// |
| // ForwardDataFlowAnalysisBase |
| //===----------------------------------------------------------------------===// |
| |
| ForwardDataFlowAnalysisBase::~ForwardDataFlowAnalysisBase() {} |
| |
| AbstractLatticeElement & |
| ForwardDataFlowAnalysisBase::getLatticeElement(Value value) { |
| AbstractLatticeElement *&latticeValue = latticeValues[value]; |
| if (!latticeValue) |
| latticeValue = createLatticeElement(value); |
| return *latticeValue; |
| } |
| |
| AbstractLatticeElement * |
| ForwardDataFlowAnalysisBase::lookupLatticeElement(Value value) { |
| return latticeValues.lookup(value); |
| } |
| |
| void ForwardDataFlowAnalysisBase::run(Operation *topLevelOp) { |
| // Run the main dataflow solver. |
| ForwardDataFlowSolver solver(*this, topLevelOp); |
| solver.solve(); |
| |
| // Any values that are still uninitialized now go to a pessimistic fixpoint, |
| // otherwise we assume an optimistic fixpoint has been reached. |
| for (auto &it : latticeValues) |
| if (it.second->isUninitialized()) |
| it.second->markPessimisticFixpoint(); |
| else |
| it.second->markOptimisticFixpoint(); |
| } |