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https://github.com/KhronosGroup/SPIRV-Tools
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d35a78db57
Fixes #4960 * Switches to using enum classes with an underlying type to avoid undefined behaviour
514 lines
19 KiB
C++
514 lines
19 KiB
C++
// Copyright (c) 2018 Google LLC.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "source/opt/loop_fission.h"
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#include <set>
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#include "source/opt/register_pressure.h"
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// Implement loop fission with an optional parameter to split only
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// if the register pressure in a given loop meets a certain criteria. This is
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// controlled via the constructors of LoopFissionPass.
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//
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// 1 - Build a list of loops to be split, these are top level loops (loops
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// without child loops themselves) which meet the register pressure criteria, as
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// determined by the ShouldSplitLoop method of LoopFissionPass.
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//
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// 2 - For each loop in the list, group each instruction into a set of related
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// instructions by traversing each instructions users and operands recursively.
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// We stop if we encounter an instruction we have seen before or an instruction
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// which we don't consider relevant (i.e OpLoopMerge). We then group these
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// groups into two different sets, one for the first loop and one for the
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// second.
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//
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// 3 - We then run CanPerformSplit to check that it would be legal to split a
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// loop using those two sets. We check that we haven't altered the relative
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// order load/stores appear in the binary and that we aren't breaking any
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// dependency between load/stores by splitting them into two loops. We also
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// check that none of the OpBranch instructions are dependent on a load as we
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// leave control flow structure intact and move only instructions in the body so
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// we want to avoid any loads with side affects or aliasing.
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//
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// 4 - We then split the loop by calling SplitLoop. This function clones the
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// loop and attaches it to the preheader and connects the new loops merge block
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// to the current loop header block. We then use the two sets built in step 2 to
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// remove instructions from each loop. If an instruction appears in the first
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// set it is removed from the second loop and vice versa.
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//
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// 5 - If the multiple split passes flag is set we check if each of the loops
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// still meet the register pressure criteria. If they do then we add them to the
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// list of loops to be split (created in step one) to allow for loops to be
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// split multiple times.
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//
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namespace spvtools {
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namespace opt {
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class LoopFissionImpl {
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public:
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LoopFissionImpl(IRContext* context, Loop* loop)
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: context_(context), loop_(loop), load_used_in_condition_(false) {}
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// Group each instruction in the loop into sets of instructions related by
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// their usedef chains. An instruction which uses another will appear in the
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// same set. Then merge those sets into just two sets. Returns false if there
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// was one or less sets created.
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bool GroupInstructionsByUseDef();
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// Check if the sets built by GroupInstructionsByUseDef violate any data
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// dependence rules.
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bool CanPerformSplit();
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// Split the loop and return a pointer to the new loop.
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Loop* SplitLoop();
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// Checks if |inst| is safe to move. We can only move instructions which don't
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// have any side effects and OpLoads and OpStores.
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bool MovableInstruction(const Instruction& inst) const;
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private:
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// Traverse the def use chain of |inst| and add the users and uses of |inst|
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// which are in the same loop to the |returned_set|.
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void TraverseUseDef(Instruction* inst, std::set<Instruction*>* returned_set,
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bool ignore_phi_users = false, bool report_loads = false);
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// We group the instructions in the block into two different groups, the
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// instructions to be kept in the original loop and the ones to be cloned into
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// the new loop. As the cloned loop is attached to the preheader it will be
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// the first loop and the second loop will be the original.
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std::set<Instruction*> cloned_loop_instructions_;
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std::set<Instruction*> original_loop_instructions_;
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// We need a set of all the instructions to be seen so we can break any
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// recursion and also so we can ignore certain instructions by preemptively
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// adding them to this set.
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std::set<Instruction*> seen_instructions_;
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// A map of instructions to their relative position in the function.
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std::map<Instruction*, size_t> instruction_order_;
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IRContext* context_;
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Loop* loop_;
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// This is set to true by TraverseUseDef when traversing the instructions
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// related to the loop condition and any if conditions should any of those
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// instructions be a load.
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bool load_used_in_condition_;
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};
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bool LoopFissionImpl::MovableInstruction(const Instruction& inst) const {
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return inst.opcode() == spv::Op::OpLoad ||
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inst.opcode() == spv::Op::OpStore ||
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inst.opcode() == spv::Op::OpSelectionMerge ||
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inst.opcode() == spv::Op::OpPhi || inst.IsOpcodeCodeMotionSafe();
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}
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void LoopFissionImpl::TraverseUseDef(Instruction* inst,
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std::set<Instruction*>* returned_set,
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bool ignore_phi_users, bool report_loads) {
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assert(returned_set && "Set to be returned cannot be null.");
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analysis::DefUseManager* def_use = context_->get_def_use_mgr();
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std::set<Instruction*>& inst_set = *returned_set;
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// We create this functor to traverse the use def chain to build the
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// grouping of related instructions. The lambda captures the std::function
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// to allow it to recurse.
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std::function<void(Instruction*)> traverser_functor;
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traverser_functor = [this, def_use, &inst_set, &traverser_functor,
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ignore_phi_users, report_loads](Instruction* user) {
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// If we've seen the instruction before or it is not inside the loop end the
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// traversal.
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if (!user || seen_instructions_.count(user) != 0 ||
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!context_->get_instr_block(user) ||
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!loop_->IsInsideLoop(context_->get_instr_block(user))) {
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return;
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}
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// Don't include labels or loop merge instructions in the instruction sets.
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// Including them would mean we group instructions related only by using the
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// same labels (i.e phis). We already preempt the inclusion of
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// OpSelectionMerge by adding related instructions to the seen_instructions_
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// set.
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if (user->opcode() == spv::Op::OpLoopMerge ||
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user->opcode() == spv::Op::OpLabel)
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return;
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// If the |report_loads| flag is set, set the class field
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// load_used_in_condition_ to false. This is used to check that none of the
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// condition checks in the loop rely on loads.
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if (user->opcode() == spv::Op::OpLoad && report_loads) {
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load_used_in_condition_ = true;
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}
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// Add the instruction to the set of instructions already seen, this breaks
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// recursion and allows us to ignore certain instructions.
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seen_instructions_.insert(user);
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inst_set.insert(user);
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// Wrapper functor to traverse the operands of each instruction.
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auto traverse_operand = [&traverser_functor, def_use](const uint32_t* id) {
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traverser_functor(def_use->GetDef(*id));
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};
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user->ForEachInOperand(traverse_operand);
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// For the first traversal we want to ignore the users of the phi.
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if (ignore_phi_users && user->opcode() == spv::Op::OpPhi) return;
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// Traverse each user with this lambda.
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def_use->ForEachUser(user, traverser_functor);
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// Wrapper functor for the use traversal.
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auto traverse_use = [&traverser_functor](Instruction* use, uint32_t) {
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traverser_functor(use);
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};
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def_use->ForEachUse(user, traverse_use);
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};
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// We start the traversal of the use def graph by invoking the above
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// lambda with the |inst| parameter.
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traverser_functor(inst);
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}
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bool LoopFissionImpl::GroupInstructionsByUseDef() {
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std::vector<std::set<Instruction*>> sets{};
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// We want to ignore all the instructions stemming from the loop condition
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// instruction.
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BasicBlock* condition_block = loop_->FindConditionBlock();
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if (!condition_block) return false;
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Instruction* condition = &*condition_block->tail();
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// We iterate over the blocks via iterating over all the blocks in the
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// function, we do this so we are iterating in the same order which the blocks
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// appear in the binary.
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Function& function = *loop_->GetHeaderBlock()->GetParent();
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// Create a temporary set to ignore certain groups of instructions within the
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// loop. We don't want any instructions related to control flow to be removed
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// from either loop only instructions within the control flow bodies.
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std::set<Instruction*> instructions_to_ignore{};
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TraverseUseDef(condition, &instructions_to_ignore, true, true);
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// Traverse control flow instructions to ensure they are added to the
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// seen_instructions_ set and will be ignored when it it called with actual
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// sets.
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for (BasicBlock& block : function) {
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if (!loop_->IsInsideLoop(block.id())) continue;
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for (Instruction& inst : block) {
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// Ignore all instructions related to control flow.
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if (inst.opcode() == spv::Op::OpSelectionMerge || inst.IsBranch()) {
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TraverseUseDef(&inst, &instructions_to_ignore, true, true);
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}
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}
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}
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// Traverse the instructions and generate the sets, automatically ignoring any
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// instructions in instructions_to_ignore.
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for (BasicBlock& block : function) {
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if (!loop_->IsInsideLoop(block.id()) ||
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loop_->GetHeaderBlock()->id() == block.id())
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continue;
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for (Instruction& inst : block) {
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// Record the order that each load/store is seen.
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if (inst.opcode() == spv::Op::OpLoad ||
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inst.opcode() == spv::Op::OpStore) {
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instruction_order_[&inst] = instruction_order_.size();
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}
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// Ignore instructions already seen in a traversal.
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if (seen_instructions_.count(&inst) != 0) {
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continue;
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}
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// Build the set.
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std::set<Instruction*> inst_set{};
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TraverseUseDef(&inst, &inst_set);
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if (!inst_set.empty()) sets.push_back(std::move(inst_set));
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}
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}
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// If we have one or zero sets return false to indicate that due to
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// insufficient instructions we couldn't split the loop into two groups and
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// thus the loop can't be split any further.
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if (sets.size() < 2) {
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return false;
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}
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// Merge the loop sets into two different sets. In CanPerformSplit we will
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// validate that we don't break the relative ordering of loads/stores by doing
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// this.
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for (size_t index = 0; index < sets.size() / 2; ++index) {
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cloned_loop_instructions_.insert(sets[index].begin(), sets[index].end());
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}
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for (size_t index = sets.size() / 2; index < sets.size(); ++index) {
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original_loop_instructions_.insert(sets[index].begin(), sets[index].end());
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}
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return true;
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}
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bool LoopFissionImpl::CanPerformSplit() {
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// Return false if any of the condition instructions in the loop depend on a
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// load.
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if (load_used_in_condition_) {
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return false;
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}
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// Build a list of all parent loops of this loop. Loop dependence analysis
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// needs this structure.
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std::vector<const Loop*> loops;
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Loop* parent_loop = loop_;
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while (parent_loop) {
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loops.push_back(parent_loop);
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parent_loop = parent_loop->GetParent();
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}
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LoopDependenceAnalysis analysis{context_, loops};
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// A list of all the stores in the cloned loop.
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std::vector<Instruction*> set_one_stores{};
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// A list of all the loads in the cloned loop.
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std::vector<Instruction*> set_one_loads{};
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// Populate the above lists.
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for (Instruction* inst : cloned_loop_instructions_) {
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if (inst->opcode() == spv::Op::OpStore) {
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set_one_stores.push_back(inst);
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} else if (inst->opcode() == spv::Op::OpLoad) {
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set_one_loads.push_back(inst);
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}
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// If we find any instruction which we can't move (such as a barrier),
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// return false.
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if (!MovableInstruction(*inst)) return false;
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}
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// We need to calculate the depth of the loop to create the loop dependency
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// distance vectors.
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const size_t loop_depth = loop_->GetDepth();
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// Check the dependencies between loads in the cloned loop and stores in the
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// original and vice versa.
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for (Instruction* inst : original_loop_instructions_) {
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// If we find any instruction which we can't move (such as a barrier),
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// return false.
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if (!MovableInstruction(*inst)) return false;
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// Look at the dependency between the loads in the original and stores in
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// the cloned loops.
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if (inst->opcode() == spv::Op::OpLoad) {
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for (Instruction* store : set_one_stores) {
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DistanceVector vec{loop_depth};
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// If the store actually should appear after the load, return false.
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// This means the store has been placed in the wrong grouping.
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if (instruction_order_[store] > instruction_order_[inst]) {
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return false;
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}
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// If not independent check the distance vector.
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if (!analysis.GetDependence(store, inst, &vec)) {
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for (DistanceEntry& entry : vec.GetEntries()) {
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// A distance greater than zero means that the store in the cloned
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// loop has a dependency on the load in the original loop.
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if (entry.distance > 0) return false;
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}
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}
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}
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} else if (inst->opcode() == spv::Op::OpStore) {
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for (Instruction* load : set_one_loads) {
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DistanceVector vec{loop_depth};
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// If the load actually should appear after the store, return false.
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if (instruction_order_[load] > instruction_order_[inst]) {
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return false;
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}
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// If not independent check the distance vector.
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if (!analysis.GetDependence(inst, load, &vec)) {
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for (DistanceEntry& entry : vec.GetEntries()) {
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// A distance less than zero means the load in the cloned loop is
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// dependent on the store instruction in the original loop.
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if (entry.distance < 0) return false;
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}
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}
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}
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}
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}
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return true;
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}
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Loop* LoopFissionImpl::SplitLoop() {
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// Clone the loop.
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LoopUtils util{context_, loop_};
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LoopUtils::LoopCloningResult clone_results;
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Loop* cloned_loop = util.CloneAndAttachLoopToHeader(&clone_results);
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// Update the OpLoopMerge in the cloned loop.
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cloned_loop->UpdateLoopMergeInst();
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// Add the loop_ to the module.
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// TODO(1841): Handle failure to create pre-header.
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Function::iterator it =
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util.GetFunction()->FindBlock(loop_->GetOrCreatePreHeaderBlock()->id());
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util.GetFunction()->AddBasicBlocks(clone_results.cloned_bb_.begin(),
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clone_results.cloned_bb_.end(), ++it);
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loop_->SetPreHeaderBlock(cloned_loop->GetMergeBlock());
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std::vector<Instruction*> instructions_to_kill{};
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// Kill all the instructions which should appear in the cloned loop but not in
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// the original loop.
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for (uint32_t id : loop_->GetBlocks()) {
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BasicBlock* block = context_->cfg()->block(id);
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for (Instruction& inst : *block) {
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// If the instruction appears in the cloned loop instruction group, kill
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// it.
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if (cloned_loop_instructions_.count(&inst) == 1 &&
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original_loop_instructions_.count(&inst) == 0) {
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instructions_to_kill.push_back(&inst);
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if (inst.opcode() == spv::Op::OpPhi) {
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context_->ReplaceAllUsesWith(
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inst.result_id(), clone_results.value_map_[inst.result_id()]);
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}
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}
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}
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}
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// Kill all instructions which should appear in the original loop and not in
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// the cloned loop.
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for (uint32_t id : cloned_loop->GetBlocks()) {
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BasicBlock* block = context_->cfg()->block(id);
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for (Instruction& inst : *block) {
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Instruction* old_inst = clone_results.ptr_map_[&inst];
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// If the instruction belongs to the original loop instruction group, kill
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// it.
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if (cloned_loop_instructions_.count(old_inst) == 0 &&
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original_loop_instructions_.count(old_inst) == 1) {
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instructions_to_kill.push_back(&inst);
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}
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}
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}
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for (Instruction* i : instructions_to_kill) {
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context_->KillInst(i);
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}
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return cloned_loop;
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}
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LoopFissionPass::LoopFissionPass(const size_t register_threshold_to_split,
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bool split_multiple_times)
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: split_multiple_times_(split_multiple_times) {
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// Split if the number of registers in the loop exceeds
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// |register_threshold_to_split|.
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split_criteria_ =
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[register_threshold_to_split](
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const RegisterLiveness::RegionRegisterLiveness& liveness) {
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return liveness.used_registers_ > register_threshold_to_split;
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};
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}
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LoopFissionPass::LoopFissionPass() : split_multiple_times_(false) {
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// Split by default.
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split_criteria_ = [](const RegisterLiveness::RegionRegisterLiveness&) {
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return true;
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};
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}
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bool LoopFissionPass::ShouldSplitLoop(const Loop& loop, IRContext* c) {
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LivenessAnalysis* analysis = c->GetLivenessAnalysis();
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RegisterLiveness::RegionRegisterLiveness liveness{};
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Function* function = loop.GetHeaderBlock()->GetParent();
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analysis->Get(function)->ComputeLoopRegisterPressure(loop, &liveness);
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return split_criteria_(liveness);
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}
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Pass::Status LoopFissionPass::Process() {
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bool changed = false;
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for (Function& f : *context()->module()) {
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// We collect all the inner most loops in the function and run the loop
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// splitting util on each. The reason we do this is to allow us to iterate
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// over each, as creating new loops will invalidate the loop iterator.
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std::vector<Loop*> inner_most_loops{};
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LoopDescriptor& loop_descriptor = *context()->GetLoopDescriptor(&f);
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for (Loop& loop : loop_descriptor) {
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if (!loop.HasChildren() && ShouldSplitLoop(loop, context())) {
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inner_most_loops.push_back(&loop);
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}
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}
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// List of new loops which meet the criteria to be split again.
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std::vector<Loop*> new_loops_to_split{};
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while (!inner_most_loops.empty()) {
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for (Loop* loop : inner_most_loops) {
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LoopFissionImpl impl{context(), loop};
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// Group the instructions in the loop into two different sets of related
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// instructions. If we can't group the instructions into the two sets
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// then we can't split the loop any further.
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if (!impl.GroupInstructionsByUseDef()) {
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continue;
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}
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if (impl.CanPerformSplit()) {
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Loop* second_loop = impl.SplitLoop();
|
|
changed = true;
|
|
context()->InvalidateAnalysesExceptFor(
|
|
IRContext::kAnalysisLoopAnalysis);
|
|
|
|
// If the newly created loop meets the criteria to be split, split it
|
|
// again.
|
|
if (ShouldSplitLoop(*second_loop, context()))
|
|
new_loops_to_split.push_back(second_loop);
|
|
|
|
// If the original loop (now split) still meets the criteria to be
|
|
// split, split it again.
|
|
if (ShouldSplitLoop(*loop, context()))
|
|
new_loops_to_split.push_back(loop);
|
|
}
|
|
}
|
|
|
|
// If the split multiple times flag has been set add the new loops which
|
|
// meet the splitting criteria into the list of loops to be split on the
|
|
// next iteration.
|
|
if (split_multiple_times_) {
|
|
inner_most_loops = std::move(new_loops_to_split);
|
|
} else {
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
return changed ? Pass::Status::SuccessWithChange
|
|
: Pass::Status::SuccessWithoutChange;
|
|
}
|
|
|
|
} // namespace opt
|
|
} // namespace spvtools
|