/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "load_store_analysis.h" namespace art { // A cap for the number of heap locations to prevent pathological time/space consumption. // The number of heap locations for most of the methods stays below this threshold. constexpr size_t kMaxNumberOfHeapLocations = 32; // Test if two integer ranges [l1,h1] and [l2,h2] overlap. // Note that the ranges are inclusive on both ends. // l1|------|h1 // l2|------|h2 static bool CanIntegerRangesOverlap(int64_t l1, int64_t h1, int64_t l2, int64_t h2) { return std::max(l1, l2) <= std::min(h1, h2); } static bool CanBinaryOpAndIndexAlias(const HBinaryOperation* idx1, const size_t vector_length1, const HInstruction* idx2, const size_t vector_length2) { if (!IsAddOrSub(idx1)) { // We currently only support Add and Sub operations. return true; } if (idx1->AsBinaryOperation()->GetLeastConstantLeft() != idx2) { // Cannot analyze [i+CONST1] and [j]. return true; } if (!idx1->GetConstantRight()->IsIntConstant()) { return true; } // Since 'i' are the same in [i+CONST] and [i], // further compare [CONST] and [0]. int64_t l1 = idx1->IsAdd() ? idx1->GetConstantRight()->AsIntConstant()->GetValue() : -idx1->GetConstantRight()->AsIntConstant()->GetValue(); int64_t l2 = 0; int64_t h1 = l1 + (vector_length1 - 1); int64_t h2 = l2 + (vector_length2 - 1); return CanIntegerRangesOverlap(l1, h1, l2, h2); } static bool CanBinaryOpsAlias(const HBinaryOperation* idx1, const size_t vector_length1, const HBinaryOperation* idx2, const size_t vector_length2) { if (!IsAddOrSub(idx1) || !IsAddOrSub(idx2)) { // We currently only support Add and Sub operations. return true; } if (idx1->AsBinaryOperation()->GetLeastConstantLeft() != idx2->AsBinaryOperation()->GetLeastConstantLeft()) { // Cannot analyze [i+CONST1] and [j+CONST2]. return true; } if (!idx1->GetConstantRight()->IsIntConstant() || !idx2->GetConstantRight()->IsIntConstant()) { return true; } // Since 'i' are the same in [i+CONST1] and [i+CONST2], // further compare [CONST1] and [CONST2]. int64_t l1 = idx1->IsAdd() ? idx1->GetConstantRight()->AsIntConstant()->GetValue() : -idx1->GetConstantRight()->AsIntConstant()->GetValue(); int64_t l2 = idx2->IsAdd() ? idx2->GetConstantRight()->AsIntConstant()->GetValue() : -idx2->GetConstantRight()->AsIntConstant()->GetValue(); int64_t h1 = l1 + (vector_length1 - 1); int64_t h2 = l2 + (vector_length2 - 1); return CanIntegerRangesOverlap(l1, h1, l2, h2); } bool HeapLocationCollector::CanArrayElementsAlias(const HInstruction* idx1, const size_t vector_length1, const HInstruction* idx2, const size_t vector_length2) const { DCHECK(idx1 != nullptr); DCHECK(idx2 != nullptr); DCHECK_GE(vector_length1, HeapLocation::kScalar); DCHECK_GE(vector_length2, HeapLocation::kScalar); // [i] and [i]. if (idx1 == idx2) { return true; } // [CONST1] and [CONST2]. if (idx1->IsIntConstant() && idx2->IsIntConstant()) { int64_t l1 = idx1->AsIntConstant()->GetValue(); int64_t l2 = idx2->AsIntConstant()->GetValue(); // To avoid any overflow in following CONST+vector_length calculation, // use int64_t instead of int32_t. int64_t h1 = l1 + (vector_length1 - 1); int64_t h2 = l2 + (vector_length2 - 1); return CanIntegerRangesOverlap(l1, h1, l2, h2); } // [i+CONST] and [i]. if (idx1->IsBinaryOperation() && idx1->AsBinaryOperation()->GetConstantRight() != nullptr && idx1->AsBinaryOperation()->GetLeastConstantLeft() == idx2) { return CanBinaryOpAndIndexAlias(idx1->AsBinaryOperation(), vector_length1, idx2, vector_length2); } // [i] and [i+CONST]. if (idx2->IsBinaryOperation() && idx2->AsBinaryOperation()->GetConstantRight() != nullptr && idx2->AsBinaryOperation()->GetLeastConstantLeft() == idx1) { return CanBinaryOpAndIndexAlias(idx2->AsBinaryOperation(), vector_length2, idx1, vector_length1); } // [i+CONST1] and [i+CONST2]. if (idx1->IsBinaryOperation() && idx1->AsBinaryOperation()->GetConstantRight() != nullptr && idx2->IsBinaryOperation() && idx2->AsBinaryOperation()->GetConstantRight() != nullptr) { return CanBinaryOpsAlias(idx1->AsBinaryOperation(), vector_length1, idx2->AsBinaryOperation(), vector_length2); } // By default, MAY alias. return true; } bool LoadStoreAnalysis::Run() { for (HBasicBlock* block : graph_->GetReversePostOrder()) { heap_location_collector_.VisitBasicBlock(block); } if (heap_location_collector_.GetNumberOfHeapLocations() > kMaxNumberOfHeapLocations) { // Bail out if there are too many heap locations to deal with. heap_location_collector_.CleanUp(); return false; } if (!heap_location_collector_.HasHeapStores()) { // Without heap stores, this pass would act mostly as GVN on heap accesses. heap_location_collector_.CleanUp(); return false; } if (heap_location_collector_.HasVolatile() || heap_location_collector_.HasMonitorOps()) { // Don't do load/store elimination if the method has volatile field accesses or // monitor operations, for now. // TODO: do it right. heap_location_collector_.CleanUp(); return false; } heap_location_collector_.BuildAliasingMatrix(); return true; } } // namespace art