// Copyright 2014 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/compiler/osr.h" #include "src/ast/scopes.h" #include "src/compilation-info.h" #include "src/compiler/all-nodes.h" #include "src/compiler/common-operator-reducer.h" #include "src/compiler/common-operator.h" #include "src/compiler/dead-code-elimination.h" #include "src/compiler/frame.h" #include "src/compiler/graph-reducer.h" #include "src/compiler/graph-trimmer.h" #include "src/compiler/graph-visualizer.h" #include "src/compiler/graph.h" #include "src/compiler/js-graph.h" #include "src/compiler/loop-analysis.h" #include "src/compiler/node-marker.h" #include "src/compiler/node.h" #include "src/objects-inl.h" namespace v8 { namespace internal { namespace compiler { OsrHelper::OsrHelper(CompilationInfo* info) : parameter_count_( info->is_optimizing_from_bytecode() ? info->shared_info()->bytecode_array()->parameter_count() : info->scope()->num_parameters()), stack_slot_count_( info->is_optimizing_from_bytecode() ? info->shared_info()->bytecode_array()->register_count() + InterpreterFrameConstants::kExtraSlotCount : info->scope()->num_stack_slots() + info->osr_expr_stack_height()) {} #ifdef DEBUG #define TRACE_COND (FLAG_trace_turbo_graph && FLAG_trace_osr) #else #define TRACE_COND false #endif #define TRACE(...) \ do { \ if (TRACE_COND) PrintF(__VA_ARGS__); \ } while (false) namespace { // Peel outer loops and rewire the graph so that control reduction can // produce a properly formed graph. void PeelOuterLoopsForOsr(Graph* graph, CommonOperatorBuilder* common, Zone* tmp_zone, Node* dead, LoopTree* loop_tree, LoopTree::Loop* osr_loop, Node* osr_normal_entry, Node* osr_loop_entry) { const size_t original_count = graph->NodeCount(); AllNodes all(tmp_zone, graph); NodeVector tmp_inputs(tmp_zone); Node* sentinel = graph->NewNode(dead->op()); // Make a copy of the graph for each outer loop. ZoneVector copies(tmp_zone); for (LoopTree::Loop* loop = osr_loop->parent(); loop; loop = loop->parent()) { void* stuff = tmp_zone->New(sizeof(NodeVector)); NodeVector* mapping = new (stuff) NodeVector(original_count, sentinel, tmp_zone); copies.push_back(mapping); TRACE("OsrDuplication #%zu, depth %zu, header #%d:%s\n", copies.size(), loop->depth(), loop_tree->HeaderNode(loop)->id(), loop_tree->HeaderNode(loop)->op()->mnemonic()); // Prepare the mapping for OSR values and the OSR loop entry. mapping->at(osr_normal_entry->id()) = dead; mapping->at(osr_loop_entry->id()) = dead; // The outer loops are dead in this copy. for (LoopTree::Loop* outer = loop->parent(); outer; outer = outer->parent()) { for (Node* node : loop_tree->HeaderNodes(outer)) { mapping->at(node->id()) = dead; TRACE(" ---- #%d:%s -> dead (header)\n", node->id(), node->op()->mnemonic()); } } // Copy all nodes. for (size_t i = 0; i < all.reachable.size(); i++) { Node* orig = all.reachable[i]; Node* copy = mapping->at(orig->id()); if (copy != sentinel) { // Mapping already exists. continue; } if (orig->InputCount() == 0 || orig->opcode() == IrOpcode::kParameter || orig->opcode() == IrOpcode::kOsrValue || orig->opcode() == IrOpcode::kOsrGuard) { // No need to copy leaf nodes or parameters. mapping->at(orig->id()) = orig; continue; } // Copy the node. tmp_inputs.clear(); for (Node* input : orig->inputs()) { tmp_inputs.push_back(mapping->at(input->id())); } copy = graph->NewNode(orig->op(), orig->InputCount(), &tmp_inputs[0]); if (NodeProperties::IsTyped(orig)) { NodeProperties::SetType(copy, NodeProperties::GetType(orig)); } mapping->at(orig->id()) = copy; TRACE(" copy #%d:%s -> #%d\n", orig->id(), orig->op()->mnemonic(), copy->id()); } // Fix missing inputs. for (Node* orig : all.reachable) { Node* copy = mapping->at(orig->id()); for (int j = 0; j < copy->InputCount(); j++) { if (copy->InputAt(j) == sentinel) { copy->ReplaceInput(j, mapping->at(orig->InputAt(j)->id())); } } } // Construct the entry into this loop from previous copies. // Gather the live loop header nodes, {loop_header} first. Node* loop_header = loop_tree->HeaderNode(loop); NodeVector header_nodes(tmp_zone); header_nodes.reserve(loop->HeaderSize()); header_nodes.push_back(loop_header); // put the loop header first. for (Node* node : loop_tree->HeaderNodes(loop)) { if (node != loop_header && all.IsLive(node)) { header_nodes.push_back(node); } } // Gather backedges from the previous copies of the inner loops of {loop}. NodeVectorVector backedges(tmp_zone); TRACE("Gathering backedges...\n"); for (int i = 1; i < loop_header->InputCount(); i++) { if (TRACE_COND) { Node* control = loop_header->InputAt(i); size_t incoming_depth = 0; for (int j = 0; j < control->op()->ControlInputCount(); j++) { Node* k = NodeProperties::GetControlInput(control, j); incoming_depth = std::max(incoming_depth, loop_tree->ContainingLoop(k)->depth()); } TRACE(" edge @%d #%d:%s, incoming depth %zu\n", i, control->id(), control->op()->mnemonic(), incoming_depth); } for (int pos = static_cast(copies.size()) - 1; pos >= 0; pos--) { backedges.push_back(NodeVector(tmp_zone)); backedges.back().reserve(header_nodes.size()); NodeVector* previous_map = pos > 0 ? copies[pos - 1] : nullptr; for (Node* node : header_nodes) { Node* input = node->InputAt(i); if (previous_map) input = previous_map->at(input->id()); backedges.back().push_back(input); TRACE(" node #%d:%s(@%d) = #%d:%s\n", node->id(), node->op()->mnemonic(), i, input->id(), input->op()->mnemonic()); } } } int backedge_count = static_cast(backedges.size()); if (backedge_count == 1) { // Simple case of single backedge, therefore a single entry. int index = 0; for (Node* node : header_nodes) { Node* copy = mapping->at(node->id()); Node* input = backedges[0][index]; copy->ReplaceInput(0, input); TRACE(" header #%d:%s(0) => #%d:%s\n", copy->id(), copy->op()->mnemonic(), input->id(), input->op()->mnemonic()); index++; } } else { // Complex case of multiple backedges from previous copies requires // merging the backedges to create the entry into the loop header. Node* merge = nullptr; int index = 0; for (Node* node : header_nodes) { // Gather edge inputs into {tmp_inputs}. tmp_inputs.clear(); for (int edge = 0; edge < backedge_count; edge++) { tmp_inputs.push_back(backedges[edge][index]); } Node* copy = mapping->at(node->id()); Node* input; if (node == loop_header) { // Create the merge for the entry into the loop header. input = merge = graph->NewNode(common->Merge(backedge_count), backedge_count, &tmp_inputs[0]); copy->ReplaceInput(0, merge); } else { // Create a phi that merges values at entry into the loop header. DCHECK_NOT_NULL(merge); DCHECK(IrOpcode::IsPhiOpcode(node->opcode())); tmp_inputs.push_back(merge); Node* phi = input = graph->NewNode( common->ResizeMergeOrPhi(node->op(), backedge_count), backedge_count + 1, &tmp_inputs[0]); copy->ReplaceInput(0, phi); } // Print the merge. if (TRACE_COND) { TRACE(" header #%d:%s(0) => #%d:%s(", copy->id(), copy->op()->mnemonic(), input->id(), input->op()->mnemonic()); for (size_t i = 0; i < tmp_inputs.size(); i++) { if (i > 0) TRACE(", "); Node* input = tmp_inputs[i]; TRACE("#%d:%s", input->id(), input->op()->mnemonic()); } TRACE(")\n"); } index++; } } } // Kill the outer loops in the original graph. TRACE("Killing outer loop headers...\n"); for (LoopTree::Loop* outer = osr_loop->parent(); outer; outer = outer->parent()) { Node* loop_header = loop_tree->HeaderNode(outer); loop_header->ReplaceUses(dead); TRACE(" ---- #%d:%s\n", loop_header->id(), loop_header->op()->mnemonic()); } // Merge the ends of the graph copies. Node* const end = graph->end(); int const input_count = end->InputCount(); for (int i = 0; i < input_count; ++i) { NodeId const id = end->InputAt(i)->id(); for (NodeVector* const copy : copies) { end->AppendInput(graph->zone(), copy->at(id)); NodeProperties::ChangeOp(end, common->End(end->InputCount())); } } if (FLAG_trace_turbo_graph) { // Simple textual RPO. OFStream os(stdout); os << "-- Graph after OSR duplication -- " << std::endl; os << AsRPO(*graph); } } void SetTypeForOsrValue(Node* osr_value, Node* loop, CommonOperatorBuilder* common) { Node* osr_guard = nullptr; for (Node* use : osr_value->uses()) { if (use->opcode() == IrOpcode::kOsrGuard) { DCHECK_EQ(use->InputAt(0), osr_value); osr_guard = use; break; } } NodeProperties::ChangeOp(osr_guard, common->OsrGuard(OsrGuardType::kAny)); } } // namespace void OsrHelper::Deconstruct(JSGraph* jsgraph, CommonOperatorBuilder* common, Zone* tmp_zone) { Graph* graph = jsgraph->graph(); Node* osr_normal_entry = nullptr; Node* osr_loop_entry = nullptr; Node* osr_loop = nullptr; for (Node* node : graph->start()->uses()) { if (node->opcode() == IrOpcode::kOsrLoopEntry) { osr_loop_entry = node; // found the OSR loop entry } else if (node->opcode() == IrOpcode::kOsrNormalEntry) { osr_normal_entry = node; } } CHECK_NOT_NULL(osr_normal_entry); // Should have found the OSR normal entry. CHECK_NOT_NULL(osr_loop_entry); // Should have found the OSR loop entry. for (Node* use : osr_loop_entry->uses()) { if (use->opcode() == IrOpcode::kLoop) { CHECK(!osr_loop); // should be only one OSR loop. osr_loop = use; // found the OSR loop. } } CHECK(osr_loop); // Should have found the OSR loop. for (Node* use : osr_loop_entry->uses()) { if (use->opcode() == IrOpcode::kOsrValue) { SetTypeForOsrValue(use, osr_loop, common); } } // Analyze the graph to determine how deeply nested the OSR loop is. LoopTree* loop_tree = LoopFinder::BuildLoopTree(graph, tmp_zone); Node* dead = jsgraph->Dead(); LoopTree::Loop* loop = loop_tree->ContainingLoop(osr_loop); if (loop->depth() > 0) { PeelOuterLoopsForOsr(graph, common, tmp_zone, dead, loop_tree, loop, osr_normal_entry, osr_loop_entry); } // Replace the normal entry with {Dead} and the loop entry with {Start} // and run the control reducer to clean up the graph. osr_normal_entry->ReplaceUses(dead); osr_normal_entry->Kill(); osr_loop_entry->ReplaceUses(graph->start()); osr_loop_entry->Kill(); // Remove the first input to the {osr_loop}. int const live_input_count = osr_loop->InputCount() - 1; CHECK_NE(0, live_input_count); for (Node* const use : osr_loop->uses()) { if (NodeProperties::IsPhi(use)) { use->RemoveInput(0); NodeProperties::ChangeOp( use, common->ResizeMergeOrPhi(use->op(), live_input_count)); } } osr_loop->RemoveInput(0); NodeProperties::ChangeOp( osr_loop, common->ResizeMergeOrPhi(osr_loop->op(), live_input_count)); // Run control reduction and graph trimming. // TODO(bmeurer): The OSR deconstruction could be a regular reducer and play // nice together with the rest, instead of having this custom stuff here. GraphReducer graph_reducer(tmp_zone, graph); DeadCodeElimination dce(&graph_reducer, graph, common); CommonOperatorReducer cor(&graph_reducer, graph, common, jsgraph->machine()); graph_reducer.AddReducer(&dce); graph_reducer.AddReducer(&cor); graph_reducer.ReduceGraph(); GraphTrimmer trimmer(tmp_zone, graph); NodeVector roots(tmp_zone); jsgraph->GetCachedNodes(&roots); trimmer.TrimGraph(roots.begin(), roots.end()); } void OsrHelper::SetupFrame(Frame* frame) { // The optimized frame will subsume the unoptimized frame. Do so by reserving // the first spill slots. frame->ReserveSpillSlots(UnoptimizedFrameSlots()); } } // namespace compiler } // namespace internal } // namespace v8