// Copyright (c) 2017 Google Inc. // // 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 "opt/loop_descriptor.h" #include #include #include #include #include #include "constants.h" #include "opt/cfg.h" #include "opt/dominator_tree.h" #include "opt/ir_builder.h" #include "opt/ir_context.h" #include "opt/iterator.h" #include "opt/make_unique.h" #include "opt/tree_iterator.h" namespace spvtools { namespace opt { // Takes in a phi instruction |induction| and the loop |header| and returns the // step operation of the loop. Instruction* Loop::GetInductionStepOperation( const Instruction* induction) const { // Induction must be a phi instruction. assert(induction->opcode() == SpvOpPhi); Instruction* step = nullptr; analysis::DefUseManager* def_use_manager = context_->get_def_use_mgr(); // Traverse the incoming operands of the phi instruction. for (uint32_t operand_id = 1; operand_id < induction->NumInOperands(); operand_id += 2) { // Incoming edge. BasicBlock* incoming_block = context_->cfg()->block(induction->GetSingleWordInOperand(operand_id)); // Check if the block is dominated by header, and thus coming from within // the loop. if (IsInsideLoop(incoming_block)) { step = def_use_manager->GetDef( induction->GetSingleWordInOperand(operand_id - 1)); break; } } if (!step || !IsSupportedStepOp(step->opcode())) { return nullptr; } // The induction variable which binds the loop must only be modified once. uint32_t lhs = step->GetSingleWordInOperand(0); uint32_t rhs = step->GetSingleWordInOperand(1); // One of the left hand side or right hand side of the step instruction must // be the induction phi and the other must be an OpConstant. if (lhs != induction->result_id() && rhs != induction->result_id()) { return nullptr; } if (def_use_manager->GetDef(lhs)->opcode() != SpvOp::SpvOpConstant && def_use_manager->GetDef(rhs)->opcode() != SpvOp::SpvOpConstant) { return nullptr; } return step; } // Returns true if the |step| operation is an induction variable step operation // which is currently handled. bool Loop::IsSupportedStepOp(SpvOp step) const { switch (step) { case SpvOp::SpvOpISub: case SpvOp::SpvOpIAdd: return true; default: return false; } } bool Loop::IsSupportedCondition(SpvOp condition) const { switch (condition) { // < case SpvOp::SpvOpULessThan: case SpvOp::SpvOpSLessThan: // > case SpvOp::SpvOpUGreaterThan: case SpvOp::SpvOpSGreaterThan: // >= case SpvOp::SpvOpSGreaterThanEqual: case SpvOp::SpvOpUGreaterThanEqual: // <= case SpvOp::SpvOpSLessThanEqual: case SpvOp::SpvOpULessThanEqual: return true; default: return false; } } int64_t Loop::GetResidualConditionValue(SpvOp condition, int64_t initial_value, int64_t step_value, size_t number_of_iterations, size_t factor) { int64_t remainder = initial_value + (number_of_iterations % factor) * step_value; // We subtract or add one as the above formula calculates the remainder if the // loop where just less than or greater than. Adding or subtracting one should // give a functionally equivalent value. switch (condition) { case SpvOp::SpvOpSGreaterThanEqual: case SpvOp::SpvOpUGreaterThanEqual: { remainder -= 1; break; } case SpvOp::SpvOpSLessThanEqual: case SpvOp::SpvOpULessThanEqual: { remainder += 1; break; } default: break; } return remainder; } Instruction* Loop::GetConditionInst() const { BasicBlock* condition_block = FindConditionBlock(); if (!condition_block) { return nullptr; } Instruction* branch_conditional = &*condition_block->tail(); if (!branch_conditional || branch_conditional->opcode() != SpvOpBranchConditional) { return nullptr; } Instruction* condition_inst = context_->get_def_use_mgr()->GetDef( branch_conditional->GetSingleWordInOperand(0)); if (IsSupportedCondition(condition_inst->opcode())) { return condition_inst; } return nullptr; } // Extract the initial value from the |induction| OpPhi instruction and store it // in |value|. If the function couldn't find the initial value of |induction| // return false. bool Loop::GetInductionInitValue(const Instruction* induction, int64_t* value) const { Instruction* constant_instruction = nullptr; analysis::DefUseManager* def_use_manager = context_->get_def_use_mgr(); for (uint32_t operand_id = 0; operand_id < induction->NumInOperands(); operand_id += 2) { BasicBlock* bb = context_->cfg()->block( induction->GetSingleWordInOperand(operand_id + 1)); if (!IsInsideLoop(bb)) { constant_instruction = def_use_manager->GetDef( induction->GetSingleWordInOperand(operand_id)); } } if (!constant_instruction) return false; const analysis::Constant* constant = context_->get_constant_mgr()->FindDeclaredConstant( constant_instruction->result_id()); if (!constant) return false; if (value) { const analysis::Integer* type = constant->AsIntConstant()->type()->AsInteger(); if (type->IsSigned()) { *value = constant->AsIntConstant()->GetS32BitValue(); } else { *value = constant->AsIntConstant()->GetU32BitValue(); } } return true; } Loop::Loop(IRContext* context, DominatorAnalysis* dom_analysis, BasicBlock* header, BasicBlock* continue_target, BasicBlock* merge_target) : context_(context), loop_header_(header), loop_continue_(continue_target), loop_merge_(merge_target), loop_preheader_(nullptr), parent_(nullptr), loop_is_marked_for_removal_(false) { assert(context); assert(dom_analysis); loop_preheader_ = FindLoopPreheader(dom_analysis); loop_latch_ = FindLatchBlock(); } BasicBlock* Loop::FindLoopPreheader(DominatorAnalysis* dom_analysis) { CFG* cfg = context_->cfg(); DominatorTree& dom_tree = dom_analysis->GetDomTree(); DominatorTreeNode* header_node = dom_tree.GetTreeNode(loop_header_); // The loop predecessor. BasicBlock* loop_pred = nullptr; auto header_pred = cfg->preds(loop_header_->id()); for (uint32_t p_id : header_pred) { DominatorTreeNode* node = dom_tree.GetTreeNode(p_id); if (node && !dom_tree.Dominates(header_node, node)) { // The predecessor is not part of the loop, so potential loop preheader. if (loop_pred && node->bb_ != loop_pred) { // If we saw 2 distinct predecessors that are outside the loop, we don't // have a loop preheader. return nullptr; } loop_pred = node->bb_; } } // Safe guard against invalid code, SPIR-V spec forbids loop with the entry // node as header. assert(loop_pred && "The header node is the entry block ?"); // So we have a unique basic block that can enter this loop. // If this loop is the unique successor of this block, then it is a loop // preheader. bool is_preheader = true; uint32_t loop_header_id = loop_header_->id(); const auto* const_loop_pred = loop_pred; const_loop_pred->ForEachSuccessorLabel( [&is_preheader, loop_header_id](const uint32_t id) { if (id != loop_header_id) is_preheader = false; }); if (is_preheader) return loop_pred; return nullptr; } bool Loop::IsInsideLoop(Instruction* inst) const { const BasicBlock* parent_block = context_->get_instr_block(inst); if (!parent_block) return false; return IsInsideLoop(parent_block); } bool Loop::IsBasicBlockInLoopSlow(const BasicBlock* bb) { assert(bb->GetParent() && "The basic block does not belong to a function"); DominatorAnalysis* dom_analysis = context_->GetDominatorAnalysis(bb->GetParent()); if (dom_analysis->IsReachable(bb) && !dom_analysis->Dominates(GetHeaderBlock(), bb)) return false; return true; } BasicBlock* Loop::GetOrCreatePreHeaderBlock() { if (loop_preheader_) return loop_preheader_; CFG* cfg = context_->cfg(); loop_header_ = cfg->SplitLoopHeader(loop_header_); return loop_preheader_; } void Loop::SetContinueBlock(BasicBlock* continue_block) { assert(IsInsideLoop(continue_block)); loop_continue_ = continue_block; } void Loop::SetLatchBlock(BasicBlock* latch) { #ifndef NDEBUG assert(latch->GetParent() && "The basic block does not belong to a function"); const auto* const_latch = latch; const_latch->ForEachSuccessorLabel([this](uint32_t id) { assert((!IsInsideLoop(id) || id == GetHeaderBlock()->id()) && "A predecessor of the continue block does not belong to the loop"); }); #endif // NDEBUG assert(IsInsideLoop(latch) && "The continue block is not in the loop"); SetLatchBlockImpl(latch); } void Loop::SetMergeBlock(BasicBlock* merge) { #ifndef NDEBUG assert(merge->GetParent() && "The basic block does not belong to a function"); #endif // NDEBUG assert(!IsInsideLoop(merge) && "The merge block is in the loop"); SetMergeBlockImpl(merge); if (GetHeaderBlock()->GetLoopMergeInst()) { UpdateLoopMergeInst(); } } void Loop::SetPreHeaderBlock(BasicBlock* preheader) { if (preheader) { assert(!IsInsideLoop(preheader) && "The preheader block is in the loop"); assert(preheader->tail()->opcode() == SpvOpBranch && "The preheader block does not unconditionally branch to the header " "block"); assert(preheader->tail()->GetSingleWordOperand(0) == GetHeaderBlock()->id() && "The preheader block does not unconditionally branch to the header " "block"); } loop_preheader_ = preheader; } BasicBlock* Loop::FindLatchBlock() { CFG* cfg = context_->cfg(); DominatorAnalysis* dominator_analysis = context_->GetDominatorAnalysis(loop_header_->GetParent()); // Look at the predecessors of the loop header to find a predecessor block // which is dominated by the loop continue target. There should only be one // block which meets this criteria and this is the latch block, as per the // SPIR-V spec. for (uint32_t block_id : cfg->preds(loop_header_->id())) { if (dominator_analysis->Dominates(loop_continue_->id(), block_id)) { return cfg->block(block_id); } } assert( false && "Every loop should have a latch block dominated by the continue target"); return nullptr; } void Loop::GetExitBlocks(std::unordered_set* exit_blocks) const { CFG* cfg = context_->cfg(); exit_blocks->clear(); for (uint32_t bb_id : GetBlocks()) { const BasicBlock* bb = cfg->block(bb_id); bb->ForEachSuccessorLabel([exit_blocks, this](uint32_t succ) { if (!IsInsideLoop(succ)) { exit_blocks->insert(succ); } }); } } void Loop::GetMergingBlocks( std::unordered_set* merging_blocks) const { assert(GetMergeBlock() && "This loop is not structured"); CFG* cfg = context_->cfg(); merging_blocks->clear(); std::stack to_visit; to_visit.push(GetMergeBlock()); while (!to_visit.empty()) { const BasicBlock* bb = to_visit.top(); to_visit.pop(); merging_blocks->insert(bb->id()); for (uint32_t pred_id : cfg->preds(bb->id())) { if (!IsInsideLoop(pred_id) && !merging_blocks->count(pred_id)) { to_visit.push(cfg->block(pred_id)); } } } } namespace { static inline bool IsBasicBlockSafeToClone(IRContext* context, BasicBlock* bb) { for (Instruction& inst : *bb) { if (!inst.IsBranch() && !context->IsCombinatorInstruction(&inst)) return false; } return true; } } // namespace bool Loop::IsSafeToClone() const { CFG& cfg = *context_->cfg(); for (uint32_t bb_id : GetBlocks()) { BasicBlock* bb = cfg.block(bb_id); assert(bb); if (!IsBasicBlockSafeToClone(context_, bb)) return false; } // Look at the merge construct. if (GetHeaderBlock()->GetLoopMergeInst()) { std::unordered_set blocks; GetMergingBlocks(&blocks); blocks.erase(GetMergeBlock()->id()); for (uint32_t bb_id : blocks) { BasicBlock* bb = cfg.block(bb_id); assert(bb); if (!IsBasicBlockSafeToClone(context_, bb)) return false; } } return true; } bool Loop::IsLCSSA() const { CFG* cfg = context_->cfg(); analysis::DefUseManager* def_use_mgr = context_->get_def_use_mgr(); std::unordered_set exit_blocks; GetExitBlocks(&exit_blocks); // Declare ir_context so we can capture context_ in the below lambda IRContext* ir_context = context_; for (uint32_t bb_id : GetBlocks()) { for (Instruction& insn : *cfg->block(bb_id)) { // All uses must be either: // - In the loop; // - In an exit block and in a phi instruction. if (!def_use_mgr->WhileEachUser( &insn, [&exit_blocks, ir_context, this](Instruction* use) -> bool { BasicBlock* parent = ir_context->get_instr_block(use); assert(parent && "Invalid analysis"); if (IsInsideLoop(parent)) return true; if (use->opcode() != SpvOpPhi) return false; return exit_blocks.count(parent->id()); })) return false; } } return true; } bool Loop::ShouldHoistInstruction(IRContext* context, Instruction* inst) { return AreAllOperandsOutsideLoop(context, inst) && inst->IsOpcodeCodeMotionSafe(); } bool Loop::AreAllOperandsOutsideLoop(IRContext* context, Instruction* inst) { analysis::DefUseManager* def_use_mgr = context->get_def_use_mgr(); bool all_outside_loop = true; const std::function operand_outside_loop = [this, &def_use_mgr, &all_outside_loop](uint32_t* id) { if (this->IsInsideLoop(def_use_mgr->GetDef(*id))) { all_outside_loop = false; return; } }; inst->ForEachInId(operand_outside_loop); return all_outside_loop; } void Loop::ComputeLoopStructuredOrder( std::vector* ordered_loop_blocks, bool include_pre_header, bool include_merge) const { CFG& cfg = *context_->cfg(); // Reserve the memory: all blocks in the loop + extra if needed. ordered_loop_blocks->reserve(GetBlocks().size() + include_pre_header + include_merge); if (include_pre_header && GetPreHeaderBlock()) ordered_loop_blocks->push_back(loop_preheader_); cfg.ForEachBlockInReversePostOrder( loop_header_, [ordered_loop_blocks, this](BasicBlock* bb) { if (IsInsideLoop(bb)) ordered_loop_blocks->push_back(bb); }); if (include_merge && GetMergeBlock()) ordered_loop_blocks->push_back(loop_merge_); } LoopDescriptor::LoopDescriptor(IRContext* context, const Function* f) : loops_(), dummy_top_loop_(nullptr) { PopulateList(context, f); } LoopDescriptor::~LoopDescriptor() { ClearLoops(); } void LoopDescriptor::PopulateList(IRContext* context, const Function* f) { DominatorAnalysis* dom_analysis = context->GetDominatorAnalysis(f); ClearLoops(); // Post-order traversal of the dominator tree to find all the OpLoopMerge // instructions. DominatorTree& dom_tree = dom_analysis->GetDomTree(); for (DominatorTreeNode& node : make_range(dom_tree.post_begin(), dom_tree.post_end())) { Instruction* merge_inst = node.bb_->GetLoopMergeInst(); if (merge_inst) { bool all_backedge_unreachable = true; for (uint32_t pid : context->cfg()->preds(node.bb_->id())) { if (dom_analysis->IsReachable(pid) && dom_analysis->Dominates(node.bb_->id(), pid)) { all_backedge_unreachable = false; break; } } if (all_backedge_unreachable) continue; // ignore this one, we actually never branch back. // The id of the merge basic block of this loop. uint32_t merge_bb_id = merge_inst->GetSingleWordOperand(0); // The id of the continue basic block of this loop. uint32_t continue_bb_id = merge_inst->GetSingleWordOperand(1); // The merge target of this loop. BasicBlock* merge_bb = context->cfg()->block(merge_bb_id); // The continue target of this loop. BasicBlock* continue_bb = context->cfg()->block(continue_bb_id); // The basic block containing the merge instruction. BasicBlock* header_bb = context->get_instr_block(merge_inst); // Add the loop to the list of all the loops in the function. Loop* current_loop = new Loop(context, dom_analysis, header_bb, continue_bb, merge_bb); loops_.push_back(current_loop); // We have a bottom-up construction, so if this loop has nested-loops, // they are by construction at the tail of the loop list. for (auto itr = loops_.rbegin() + 1; itr != loops_.rend(); ++itr) { Loop* previous_loop = *itr; // If the loop already has a parent, then it has been processed. if (previous_loop->HasParent()) continue; // If the current loop does not dominates the previous loop then it is // not nested loop. if (!dom_analysis->Dominates(header_bb, previous_loop->GetHeaderBlock())) continue; // If the current loop merge dominates the previous loop then it is // not nested loop. if (dom_analysis->Dominates(merge_bb, previous_loop->GetHeaderBlock())) continue; current_loop->AddNestedLoop(previous_loop); } DominatorTreeNode* dom_merge_node = dom_tree.GetTreeNode(merge_bb); for (DominatorTreeNode& loop_node : make_range(node.df_begin(), node.df_end())) { // Check if we are in the loop. if (dom_tree.Dominates(dom_merge_node, &loop_node)) continue; current_loop->AddBasicBlock(loop_node.bb_); basic_block_to_loop_.insert( std::make_pair(loop_node.bb_->id(), current_loop)); } } } for (Loop* loop : loops_) { if (!loop->HasParent()) dummy_top_loop_.nested_loops_.push_back(loop); } } std::vector LoopDescriptor::GetLoopsInBinaryLayoutOrder() { std::vector ids{}; for (size_t i = 0; i < NumLoops(); ++i) { ids.push_back(GetLoopByIndex(i).GetHeaderBlock()->id()); } std::vector loops{}; if (!ids.empty()) { auto function = GetLoopByIndex(0).GetHeaderBlock()->GetParent(); for (const auto& block : *function) { auto block_id = block.id(); auto element = std::find(std::begin(ids), std::end(ids), block_id); if (element != std::end(ids)) { loops.push_back(&GetLoopByIndex(element - std::begin(ids))); } } } return loops; } BasicBlock* Loop::FindConditionBlock() const { if (!loop_merge_) { return nullptr; } BasicBlock* condition_block = nullptr; uint32_t in_loop_pred = 0; for (uint32_t p : context_->cfg()->preds(loop_merge_->id())) { if (IsInsideLoop(p)) { if (in_loop_pred) { // 2 in-loop predecessors. return nullptr; } in_loop_pred = p; } } if (!in_loop_pred) { // Merge block is unreachable. return nullptr; } BasicBlock* bb = context_->cfg()->block(in_loop_pred); if (!bb) return nullptr; const Instruction& branch = *bb->ctail(); // Make sure the branch is a conditional branch. if (branch.opcode() != SpvOpBranchConditional) return nullptr; // Make sure one of the two possible branches is to the merge block. if (branch.GetSingleWordInOperand(1) == loop_merge_->id() || branch.GetSingleWordInOperand(2) == loop_merge_->id()) { condition_block = bb; } return condition_block; } bool Loop::FindNumberOfIterations(const Instruction* induction, const Instruction* branch_inst, size_t* iterations_out, int64_t* step_value_out, int64_t* init_value_out) const { // From the branch instruction find the branch condition. analysis::DefUseManager* def_use_manager = context_->get_def_use_mgr(); // Condition instruction from the OpConditionalBranch. Instruction* condition = def_use_manager->GetDef(branch_inst->GetSingleWordOperand(0)); assert(IsSupportedCondition(condition->opcode())); // Get the constant manager from the ir context. analysis::ConstantManager* const_manager = context_->get_constant_mgr(); // Find the constant value used by the condition variable. Exit out if it // isn't a constant int. const analysis::Constant* upper_bound = const_manager->FindDeclaredConstant(condition->GetSingleWordOperand(3)); if (!upper_bound) return false; // Must be integer because of the opcode on the condition. int64_t condition_value = 0; const analysis::Integer* type = upper_bound->AsIntConstant()->type()->AsInteger(); if (type->width() > 32) { return false; } if (type->IsSigned()) { condition_value = upper_bound->AsIntConstant()->GetS32BitValue(); } else { condition_value = upper_bound->AsIntConstant()->GetU32BitValue(); } // Find the instruction which is stepping through the loop. Instruction* step_inst = GetInductionStepOperation(induction); if (!step_inst) return false; // Find the constant value used by the condition variable. const analysis::Constant* step_constant = const_manager->FindDeclaredConstant(step_inst->GetSingleWordOperand(3)); if (!step_constant) return false; // Must be integer because of the opcode on the condition. int64_t step_value = 0; const analysis::Integer* step_type = step_constant->AsIntConstant()->type()->AsInteger(); if (step_type->IsSigned()) { step_value = step_constant->AsIntConstant()->GetS32BitValue(); } else { step_value = step_constant->AsIntConstant()->GetU32BitValue(); } // If this is a subtraction step we should negate the step value. if (step_inst->opcode() == SpvOp::SpvOpISub) { step_value = -step_value; } // Find the inital value of the loop and make sure it is a constant integer. int64_t init_value = 0; if (!GetInductionInitValue(induction, &init_value)) return false; // If iterations is non null then store the value in that. int64_t num_itrs = GetIterations(condition->opcode(), condition_value, init_value, step_value); // If the loop body will not be reached return false. if (num_itrs <= 0) { return false; } if (iterations_out) { assert(static_cast(num_itrs) <= std::numeric_limits::max()); *iterations_out = static_cast(num_itrs); } if (step_value_out) { *step_value_out = step_value; } if (init_value_out) { *init_value_out = init_value; } return true; } // We retrieve the number of iterations using the following formula, diff / // |step_value| where diff is calculated differently according to the // |condition| and uses the |condition_value| and |init_value|. If diff / // |step_value| is NOT cleanly divisable then we add one to the sum. int64_t Loop::GetIterations(SpvOp condition, int64_t condition_value, int64_t init_value, int64_t step_value) const { int64_t diff = 0; switch (condition) { case SpvOp::SpvOpSLessThan: case SpvOp::SpvOpULessThan: { // If the condition is not met to begin with the loop will never iterate. if (!(init_value < condition_value)) return 0; diff = condition_value - init_value; // If the operation is a less then operation then the diff and step must // have the same sign otherwise the induction will never cross the // condition (either never true or always true). if ((diff < 0 && step_value > 0) || (diff > 0 && step_value < 0)) { return 0; } break; } case SpvOp::SpvOpSGreaterThan: case SpvOp::SpvOpUGreaterThan: { // If the condition is not met to begin with the loop will never iterate. if (!(init_value > condition_value)) return 0; diff = init_value - condition_value; // If the operation is a greater than operation then the diff and step // must have opposite signs. Otherwise the condition will always be true // or will never be true. if ((diff < 0 && step_value < 0) || (diff > 0 && step_value > 0)) { return 0; } break; } case SpvOp::SpvOpSGreaterThanEqual: case SpvOp::SpvOpUGreaterThanEqual: { // If the condition is not met to begin with the loop will never iterate. if (!(init_value >= condition_value)) return 0; // We subract one to make it the same as SpvOpGreaterThan as it is // functionally equivalent. diff = init_value - (condition_value - 1); // If the operation is a greater than operation then the diff and step // must have opposite signs. Otherwise the condition will always be true // or will never be true. if ((diff > 0 && step_value > 0) || (diff < 0 && step_value < 0)) { return 0; } break; } case SpvOp::SpvOpSLessThanEqual: case SpvOp::SpvOpULessThanEqual: { // If the condition is not met to begin with the loop will never iterate. if (!(init_value <= condition_value)) return 0; // We add one to make it the same as SpvOpLessThan as it is functionally // equivalent. diff = (condition_value + 1) - init_value; // If the operation is a less than operation then the diff and step must // have the same sign otherwise the induction will never cross the // condition (either never true or always true). if ((diff < 0 && step_value > 0) || (diff > 0 && step_value < 0)) { return 0; } break; } default: assert(false && "Could not retrieve number of iterations from the loop condition. " "Condition is not supported."); } // Take the abs of - step values. step_value = llabs(step_value); diff = llabs(diff); int64_t result = diff / step_value; if (diff % step_value != 0) { result += 1; } return result; } // Returns the list of induction variables within the loop. void Loop::GetInductionVariables( std::vector& induction_variables) const { for (Instruction& inst : *loop_header_) { if (inst.opcode() == SpvOp::SpvOpPhi) { induction_variables.push_back(&inst); } } } Instruction* Loop::FindConditionVariable( const BasicBlock* condition_block) const { // Find the branch instruction. const Instruction& branch_inst = *condition_block->ctail(); Instruction* induction = nullptr; // Verify that the branch instruction is a conditional branch. if (branch_inst.opcode() == SpvOp::SpvOpBranchConditional) { // From the branch instruction find the branch condition. analysis::DefUseManager* def_use_manager = context_->get_def_use_mgr(); // Find the instruction representing the condition used in the conditional // branch. Instruction* condition = def_use_manager->GetDef(branch_inst.GetSingleWordOperand(0)); // Ensure that the condition is a less than operation. if (condition && IsSupportedCondition(condition->opcode())) { // The left hand side operand of the operation. Instruction* variable_inst = def_use_manager->GetDef(condition->GetSingleWordOperand(2)); // Make sure the variable instruction used is a phi. if (!variable_inst || variable_inst->opcode() != SpvOpPhi) return nullptr; // Make sure the phi instruction only has two incoming blocks. Each // incoming block will be represented by two in operands in the phi // instruction, the value and the block which that value came from. We // assume the cannocalised phi will have two incoming values, one from the // preheader and one from the continue block. size_t max_supported_operands = 4; if (variable_inst->NumInOperands() == max_supported_operands) { // The operand index of the first incoming block label. uint32_t operand_label_1 = 1; // The operand index of the second incoming block label. uint32_t operand_label_2 = 3; // Make sure one of them is the preheader. if (!IsInsideLoop( variable_inst->GetSingleWordInOperand(operand_label_1)) && !IsInsideLoop( variable_inst->GetSingleWordInOperand(operand_label_2))) { return nullptr; } // And make sure that the other is the latch block. if (variable_inst->GetSingleWordInOperand(operand_label_1) != loop_latch_->id() && variable_inst->GetSingleWordInOperand(operand_label_2) != loop_latch_->id()) { return nullptr; } } else { return nullptr; } if (!FindNumberOfIterations(variable_inst, &branch_inst, nullptr)) return nullptr; induction = variable_inst; } } return induction; } bool LoopDescriptor::CreatePreHeaderBlocksIfMissing() { auto modified = false; for (auto& loop : *this) { if (!loop.GetPreHeaderBlock()) { modified = true; loop.GetOrCreatePreHeaderBlock(); } } return modified; } // Add and remove loops which have been marked for addition and removal to // maintain the state of the loop descriptor class. void LoopDescriptor::PostModificationCleanup() { LoopContainerType loops_to_remove_; for (Loop* loop : loops_) { if (loop->IsMarkedForRemoval()) { loops_to_remove_.push_back(loop); if (loop->HasParent()) { loop->GetParent()->RemoveChildLoop(loop); } } } for (Loop* loop : loops_to_remove_) { loops_.erase(std::find(loops_.begin(), loops_.end(), loop)); } for (auto& pair : loops_to_add_) { Loop* parent = pair.first; Loop* loop = pair.second; if (parent) { loop->SetParent(nullptr); parent->AddNestedLoop(loop); for (uint32_t block_id : loop->GetBlocks()) { parent->AddBasicBlock(block_id); } } loops_.emplace_back(loop); } loops_to_add_.clear(); } void LoopDescriptor::ClearLoops() { for (Loop* loop : loops_) { delete loop; } loops_.clear(); } // Adds a new loop nest to the descriptor set. Loop* LoopDescriptor::AddLoopNest(std::unique_ptr new_loop) { Loop* loop = new_loop.release(); if (!loop->HasParent()) dummy_top_loop_.nested_loops_.push_back(loop); // Iterate from inner to outer most loop, adding basic block to loop mapping // as we go. for (Loop& current_loop : make_range(iterator::begin(loop), iterator::end(nullptr))) { loops_.push_back(¤t_loop); for (uint32_t bb_id : current_loop.GetBlocks()) basic_block_to_loop_.insert(std::make_pair(bb_id, ¤t_loop)); } return loop; } void LoopDescriptor::RemoveLoop(Loop* loop) { Loop* parent = loop->GetParent() ? loop->GetParent() : &dummy_top_loop_; parent->nested_loops_.erase(std::find(parent->nested_loops_.begin(), parent->nested_loops_.end(), loop)); std::for_each( loop->nested_loops_.begin(), loop->nested_loops_.end(), [loop](Loop* sub_loop) { sub_loop->SetParent(loop->GetParent()); }); parent->nested_loops_.insert(parent->nested_loops_.end(), loop->nested_loops_.begin(), loop->nested_loops_.end()); for (uint32_t bb_id : loop->GetBlocks()) { Loop* l = FindLoopForBasicBlock(bb_id); if (l == loop) { SetBasicBlockToLoop(bb_id, l->GetParent()); } else { ForgetBasicBlock(bb_id); } } LoopContainerType::iterator it = std::find(loops_.begin(), loops_.end(), loop); assert(it != loops_.end()); delete loop; loops_.erase(it); } } // namespace opt } // namespace spvtools