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457 lines
15 KiB
C++
457 lines
15 KiB
C++
//===- DivergenceAnalysis.cpp --------- Divergence Analysis Implementation -==//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file implements a general divergence analysis for loop vectorization
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// and GPU programs. It determines which branches and values in a loop or GPU
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// program are divergent. It can help branch optimizations such as jump
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// threading and loop unswitching to make better decisions.
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//
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// GPU programs typically use the SIMD execution model, where multiple threads
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// in the same execution group have to execute in lock-step. Therefore, if the
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// code contains divergent branches (i.e., threads in a group do not agree on
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// which path of the branch to take), the group of threads has to execute all
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// the paths from that branch with different subsets of threads enabled until
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// they re-converge.
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//
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// Due to this execution model, some optimizations such as jump
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// threading and loop unswitching can interfere with thread re-convergence.
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// Therefore, an analysis that computes which branches in a GPU program are
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// divergent can help the compiler to selectively run these optimizations.
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//
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// This implementation is derived from the Vectorization Analysis of the
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// Region Vectorizer (RV). That implementation in turn is based on the approach
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// described in
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//
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// Improving Performance of OpenCL on CPUs
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// Ralf Karrenberg and Sebastian Hack
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// CC '12
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//
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// This DivergenceAnalysis implementation is generic in the sense that it does
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// not itself identify original sources of divergence.
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// Instead specialized adapter classes, (LoopDivergenceAnalysis) for loops and
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// (GPUDivergenceAnalysis) for GPU programs, identify the sources of divergence
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// (e.g., special variables that hold the thread ID or the iteration variable).
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//
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// The generic implementation propagates divergence to variables that are data
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// or sync dependent on a source of divergence.
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//
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// While data dependency is a well-known concept, the notion of sync dependency
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// is worth more explanation. Sync dependence characterizes the control flow
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// aspect of the propagation of branch divergence. For example,
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//
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// %cond = icmp slt i32 %tid, 10
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// br i1 %cond, label %then, label %else
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// then:
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// br label %merge
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// else:
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// br label %merge
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// merge:
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// %a = phi i32 [ 0, %then ], [ 1, %else ]
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//
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// Suppose %tid holds the thread ID. Although %a is not data dependent on %tid
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// because %tid is not on its use-def chains, %a is sync dependent on %tid
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// because the branch "br i1 %cond" depends on %tid and affects which value %a
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// is assigned to.
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//
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// The sync dependence detection (which branch induces divergence in which join
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// points) is implemented in the SyncDependenceAnalysis.
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//
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// The current DivergenceAnalysis implementation has the following limitations:
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// 1. intra-procedural. It conservatively considers the arguments of a
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// non-kernel-entry function and the return value of a function call as
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// divergent.
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// 2. memory as black box. It conservatively considers values loaded from
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// generic or local address as divergent. This can be improved by leveraging
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// pointer analysis and/or by modelling non-escaping memory objects in SSA
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// as done in RV.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Analysis/DivergenceAnalysis.h"
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#include "llvm/Analysis/LoopInfo.h"
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#include "llvm/Analysis/Passes.h"
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#include "llvm/Analysis/PostDominators.h"
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#include "llvm/Analysis/TargetTransformInfo.h"
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#include "llvm/IR/Dominators.h"
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#include "llvm/IR/InstIterator.h"
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#include "llvm/IR/Instructions.h"
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#include "llvm/IR/IntrinsicInst.h"
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#include "llvm/IR/Value.h"
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#include "llvm/Support/Debug.h"
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#include "llvm/Support/raw_ostream.h"
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#include <vector>
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using namespace llvm;
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#define DEBUG_TYPE "divergence-analysis"
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// class DivergenceAnalysis
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DivergenceAnalysis::DivergenceAnalysis(
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const Function &F, const Loop *RegionLoop, const DominatorTree &DT,
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const LoopInfo &LI, SyncDependenceAnalysis &SDA, bool IsLCSSAForm)
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: F(F), RegionLoop(RegionLoop), DT(DT), LI(LI), SDA(SDA),
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IsLCSSAForm(IsLCSSAForm) {}
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void DivergenceAnalysis::markDivergent(const Value &DivVal) {
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assert(isa<Instruction>(DivVal) || isa<Argument>(DivVal));
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assert(!isAlwaysUniform(DivVal) && "cannot be a divergent");
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DivergentValues.insert(&DivVal);
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}
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void DivergenceAnalysis::addUniformOverride(const Value &UniVal) {
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UniformOverrides.insert(&UniVal);
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}
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bool DivergenceAnalysis::updateTerminator(const Instruction &Term) const {
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if (Term.getNumSuccessors() <= 1)
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return false;
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if (auto *BranchTerm = dyn_cast<BranchInst>(&Term)) {
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assert(BranchTerm->isConditional());
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return isDivergent(*BranchTerm->getCondition());
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}
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if (auto *SwitchTerm = dyn_cast<SwitchInst>(&Term)) {
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return isDivergent(*SwitchTerm->getCondition());
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}
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if (isa<InvokeInst>(Term)) {
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return false; // ignore abnormal executions through landingpad
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}
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llvm_unreachable("unexpected terminator");
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}
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bool DivergenceAnalysis::updateNormalInstruction(const Instruction &I) const {
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// TODO function calls with side effects, etc
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for (const auto &Op : I.operands()) {
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if (isDivergent(*Op))
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return true;
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}
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return false;
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}
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bool DivergenceAnalysis::isTemporalDivergent(const BasicBlock &ObservingBlock,
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const Value &Val) const {
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const auto *Inst = dyn_cast<const Instruction>(&Val);
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if (!Inst)
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return false;
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// check whether any divergent loop carrying Val terminates before control
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// proceeds to ObservingBlock
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for (const auto *Loop = LI.getLoopFor(Inst->getParent());
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Loop != RegionLoop && !Loop->contains(&ObservingBlock);
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Loop = Loop->getParentLoop()) {
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if (DivergentLoops.find(Loop) != DivergentLoops.end())
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return true;
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}
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return false;
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}
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bool DivergenceAnalysis::updatePHINode(const PHINode &Phi) const {
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// joining divergent disjoint path in Phi parent block
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if (!Phi.hasConstantOrUndefValue() && isJoinDivergent(*Phi.getParent())) {
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return true;
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}
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// An incoming value could be divergent by itself.
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// Otherwise, an incoming value could be uniform within the loop
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// that carries its definition but it may appear divergent
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// from outside the loop. This happens when divergent loop exits
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// drop definitions of that uniform value in different iterations.
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//
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// for (int i = 0; i < n; ++i) { // 'i' is uniform inside the loop
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// if (i % thread_id == 0) break; // divergent loop exit
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// }
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// int divI = i; // divI is divergent
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for (size_t i = 0; i < Phi.getNumIncomingValues(); ++i) {
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const auto *InVal = Phi.getIncomingValue(i);
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if (isDivergent(*Phi.getIncomingValue(i)) ||
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isTemporalDivergent(*Phi.getParent(), *InVal)) {
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return true;
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}
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}
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return false;
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}
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bool DivergenceAnalysis::inRegion(const Instruction &I) const {
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return I.getParent() && inRegion(*I.getParent());
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}
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bool DivergenceAnalysis::inRegion(const BasicBlock &BB) const {
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return (!RegionLoop && BB.getParent() == &F) || RegionLoop->contains(&BB);
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}
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// marks all users of loop-carried values of the loop headed by LoopHeader as
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// divergent
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void DivergenceAnalysis::taintLoopLiveOuts(const BasicBlock &LoopHeader) {
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auto *DivLoop = LI.getLoopFor(&LoopHeader);
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assert(DivLoop && "loopHeader is not actually part of a loop");
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SmallVector<BasicBlock *, 8> TaintStack;
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DivLoop->getExitBlocks(TaintStack);
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// Otherwise potential users of loop-carried values could be anywhere in the
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// dominance region of DivLoop (including its fringes for phi nodes)
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DenseSet<const BasicBlock *> Visited;
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for (auto *Block : TaintStack) {
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Visited.insert(Block);
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}
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Visited.insert(&LoopHeader);
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while (!TaintStack.empty()) {
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auto *UserBlock = TaintStack.back();
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TaintStack.pop_back();
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// don't spread divergence beyond the region
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if (!inRegion(*UserBlock))
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continue;
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assert(!DivLoop->contains(UserBlock) &&
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"irreducible control flow detected");
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// phi nodes at the fringes of the dominance region
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if (!DT.dominates(&LoopHeader, UserBlock)) {
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// all PHI nodes of UserBlock become divergent
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for (auto &Phi : UserBlock->phis()) {
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Worklist.push_back(&Phi);
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}
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continue;
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}
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// taint outside users of values carried by DivLoop
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for (auto &I : *UserBlock) {
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if (isAlwaysUniform(I))
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continue;
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if (isDivergent(I))
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continue;
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for (auto &Op : I.operands()) {
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auto *OpInst = dyn_cast<Instruction>(&Op);
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if (!OpInst)
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continue;
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if (DivLoop->contains(OpInst->getParent())) {
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markDivergent(I);
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pushUsers(I);
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break;
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}
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}
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}
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// visit all blocks in the dominance region
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for (auto *SuccBlock : successors(UserBlock)) {
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if (!Visited.insert(SuccBlock).second) {
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continue;
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}
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TaintStack.push_back(SuccBlock);
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}
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}
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}
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void DivergenceAnalysis::pushPHINodes(const BasicBlock &Block) {
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for (const auto &Phi : Block.phis()) {
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if (isDivergent(Phi))
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continue;
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Worklist.push_back(&Phi);
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}
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}
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void DivergenceAnalysis::pushUsers(const Value &V) {
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for (const auto *User : V.users()) {
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const auto *UserInst = dyn_cast<const Instruction>(User);
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if (!UserInst)
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continue;
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if (isDivergent(*UserInst))
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continue;
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// only compute divergent inside loop
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if (!inRegion(*UserInst))
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continue;
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Worklist.push_back(UserInst);
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}
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}
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bool DivergenceAnalysis::propagateJoinDivergence(const BasicBlock &JoinBlock,
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const Loop *BranchLoop) {
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LLVM_DEBUG(dbgs() << "\tpropJoinDiv " << JoinBlock.getName() << "\n");
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// ignore divergence outside the region
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if (!inRegion(JoinBlock)) {
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return false;
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}
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// push non-divergent phi nodes in JoinBlock to the worklist
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pushPHINodes(JoinBlock);
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// JoinBlock is a divergent loop exit
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if (BranchLoop && !BranchLoop->contains(&JoinBlock)) {
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return true;
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}
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// disjoint-paths divergent at JoinBlock
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markBlockJoinDivergent(JoinBlock);
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return false;
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}
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void DivergenceAnalysis::propagateBranchDivergence(const Instruction &Term) {
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LLVM_DEBUG(dbgs() << "propBranchDiv " << Term.getParent()->getName() << "\n");
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markDivergent(Term);
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const auto *BranchLoop = LI.getLoopFor(Term.getParent());
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// whether there is a divergent loop exit from BranchLoop (if any)
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bool IsBranchLoopDivergent = false;
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// iterate over all blocks reachable by disjoint from Term within the loop
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// also iterates over loop exits that become divergent due to Term.
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for (const auto *JoinBlock : SDA.join_blocks(Term)) {
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IsBranchLoopDivergent |= propagateJoinDivergence(*JoinBlock, BranchLoop);
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}
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// Branch loop is a divergent loop due to the divergent branch in Term
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if (IsBranchLoopDivergent) {
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assert(BranchLoop);
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if (!DivergentLoops.insert(BranchLoop).second) {
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return;
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}
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propagateLoopDivergence(*BranchLoop);
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}
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}
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void DivergenceAnalysis::propagateLoopDivergence(const Loop &ExitingLoop) {
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LLVM_DEBUG(dbgs() << "propLoopDiv " << ExitingLoop.getName() << "\n");
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// don't propagate beyond region
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if (!inRegion(*ExitingLoop.getHeader()))
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return;
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const auto *BranchLoop = ExitingLoop.getParentLoop();
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// Uses of loop-carried values could occur anywhere
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// within the dominance region of the definition. All loop-carried
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// definitions are dominated by the loop header (reducible control).
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// Thus all users have to be in the dominance region of the loop header,
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// except PHI nodes that can also live at the fringes of the dom region
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// (incoming defining value).
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if (!IsLCSSAForm)
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taintLoopLiveOuts(*ExitingLoop.getHeader());
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// whether there is a divergent loop exit from BranchLoop (if any)
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bool IsBranchLoopDivergent = false;
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// iterate over all blocks reachable by disjoint paths from exits of
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// ExitingLoop also iterates over loop exits (of BranchLoop) that in turn
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// become divergent.
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for (const auto *JoinBlock : SDA.join_blocks(ExitingLoop)) {
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IsBranchLoopDivergent |= propagateJoinDivergence(*JoinBlock, BranchLoop);
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}
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// Branch loop is a divergent due to divergent loop exit in ExitingLoop
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if (IsBranchLoopDivergent) {
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assert(BranchLoop);
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if (!DivergentLoops.insert(BranchLoop).second) {
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return;
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}
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propagateLoopDivergence(*BranchLoop);
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}
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}
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void DivergenceAnalysis::compute() {
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for (auto *DivVal : DivergentValues) {
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pushUsers(*DivVal);
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}
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// propagate divergence
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while (!Worklist.empty()) {
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const Instruction &I = *Worklist.back();
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Worklist.pop_back();
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// maintain uniformity of overrides
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if (isAlwaysUniform(I))
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continue;
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bool WasDivergent = isDivergent(I);
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if (WasDivergent)
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continue;
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// propagate divergence caused by terminator
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if (I.isTerminator()) {
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if (updateTerminator(I)) {
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// propagate control divergence to affected instructions
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propagateBranchDivergence(I);
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continue;
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}
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}
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// update divergence of I due to divergent operands
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bool DivergentUpd = false;
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const auto *Phi = dyn_cast<const PHINode>(&I);
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if (Phi) {
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DivergentUpd = updatePHINode(*Phi);
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} else {
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DivergentUpd = updateNormalInstruction(I);
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}
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// propagate value divergence to users
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if (DivergentUpd) {
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markDivergent(I);
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pushUsers(I);
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}
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}
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}
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bool DivergenceAnalysis::isAlwaysUniform(const Value &V) const {
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return UniformOverrides.find(&V) != UniformOverrides.end();
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}
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bool DivergenceAnalysis::isDivergent(const Value &V) const {
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return DivergentValues.find(&V) != DivergentValues.end();
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}
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void DivergenceAnalysis::print(raw_ostream &OS, const Module *) const {
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if (DivergentValues.empty())
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return;
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// iterate instructions using instructions() to ensure a deterministic order.
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for (auto &I : instructions(F)) {
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if (isDivergent(I))
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OS << "DIVERGENT:" << I << '\n';
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}
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}
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// class GPUDivergenceAnalysis
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GPUDivergenceAnalysis::GPUDivergenceAnalysis(Function &F,
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const DominatorTree &DT,
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const PostDominatorTree &PDT,
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const LoopInfo &LI,
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const TargetTransformInfo &TTI)
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: SDA(DT, PDT, LI), DA(F, nullptr, DT, LI, SDA, false) {
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for (auto &I : instructions(F)) {
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if (TTI.isSourceOfDivergence(&I)) {
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DA.markDivergent(I);
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} else if (TTI.isAlwaysUniform(&I)) {
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DA.addUniformOverride(I);
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}
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}
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for (auto &Arg : F.args()) {
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if (TTI.isSourceOfDivergence(&Arg)) {
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DA.markDivergent(Arg);
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}
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}
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DA.compute();
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}
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bool GPUDivergenceAnalysis::isDivergent(const Value &val) const {
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return DA.isDivergent(val);
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}
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void GPUDivergenceAnalysis::print(raw_ostream &OS, const Module *mod) const {
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OS << "Divergence of kernel " << DA.getFunction().getName() << " {\n";
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DA.print(OS, mod);
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OS << "}\n";
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}
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