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460 lines
15 KiB
C++
460 lines
15 KiB
C++
//===--- SyncDependenceAnalysis.cpp - Compute Control Divergence Effects --===//
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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 an algorithm that returns for a divergent branch
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// the set of basic blocks whose phi nodes become divergent due to divergent
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// control. These are the blocks that are reachable by two disjoint paths from
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// the branch or loop exits that have a reaching path that is disjoint from a
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// path to the loop latch.
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//
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// The SyncDependenceAnalysis is used in the DivergenceAnalysis to model
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// control-induced divergence in phi nodes.
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//
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// -- Summary --
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// The SyncDependenceAnalysis lazily computes sync dependences [3].
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// The analysis evaluates the disjoint path criterion [2] by a reduction
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// to SSA construction. The SSA construction algorithm is implemented as
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// a simple data-flow analysis [1].
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//
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// [1] "A Simple, Fast Dominance Algorithm", SPI '01, Cooper, Harvey and Kennedy
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// [2] "Efficiently Computing Static Single Assignment Form
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// and the Control Dependence Graph", TOPLAS '91,
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// Cytron, Ferrante, Rosen, Wegman and Zadeck
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// [3] "Improving Performance of OpenCL on CPUs", CC '12, Karrenberg and Hack
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// [4] "Divergence Analysis", TOPLAS '13, Sampaio, Souza, Collange and Pereira
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//
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// -- Sync dependence --
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// Sync dependence [4] characterizes the control flow aspect of the
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// 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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// -- Reduction to SSA construction --
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// There are two disjoint paths from A to X, if a certain variant of SSA
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// construction places a phi node in X under the following set-up scheme [2].
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//
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// This variant of SSA construction ignores incoming undef values.
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// That is paths from the entry without a definition do not result in
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// phi nodes.
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//
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// entry
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// / \
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// A \
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// / \ Y
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// B C /
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// \ / \ /
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// D E
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// \ /
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// F
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// Assume that A contains a divergent branch. We are interested
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// in the set of all blocks where each block is reachable from A
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// via two disjoint paths. This would be the set {D, F} in this
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// case.
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// To generally reduce this query to SSA construction we introduce
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// a virtual variable x and assign to x different values in each
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// successor block of A.
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// entry
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// / \
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// A \
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// / \ Y
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// x = 0 x = 1 /
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// \ / \ /
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// D E
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// \ /
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// F
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// Our flavor of SSA construction for x will construct the following
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// entry
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// / \
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// A \
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// / \ Y
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// x0 = 0 x1 = 1 /
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// \ / \ /
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// x2=phi E
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// \ /
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// x3=phi
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// The blocks D and F contain phi nodes and are thus each reachable
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// by two disjoins paths from A.
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//
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// -- Remarks --
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// In case of loop exits we need to check the disjoint path criterion for loops
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// [2]. To this end, we check whether the definition of x differs between the
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// loop exit and the loop header (_after_ SSA construction).
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Analysis/SyncDependenceAnalysis.h"
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#include "llvm/ADT/PostOrderIterator.h"
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#include "llvm/ADT/SmallPtrSet.h"
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#include "llvm/Analysis/PostDominators.h"
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#include "llvm/IR/BasicBlock.h"
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#include "llvm/IR/CFG.h"
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#include "llvm/IR/Dominators.h"
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#include "llvm/IR/Function.h"
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#include <functional>
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#include <stack>
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#include <unordered_set>
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#define DEBUG_TYPE "sync-dependence"
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// The SDA algorithm operates on a modified CFG - we modify the edges leaving
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// loop headers as follows:
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//
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// * We remove all edges leaving all loop headers.
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// * We add additional edges from the loop headers to their exit blocks.
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//
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// The modification is virtual, that is whenever we visit a loop header we
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// pretend it had different successors.
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namespace {
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using namespace llvm;
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// Custom Post-Order Traveral
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//
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// We cannot use the vanilla (R)PO computation of LLVM because:
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// * We (virtually) modify the CFG.
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// * We want a loop-compact block enumeration, that is the numbers assigned by
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// the traveral to the blocks of a loop are an interval.
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using POCB = std::function<void(const BasicBlock &)>;
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using VisitedSet = std::set<const BasicBlock *>;
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using BlockStack = std::vector<const BasicBlock *>;
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// forward
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static void computeLoopPO(const LoopInfo &LI, Loop &Loop, POCB CallBack,
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VisitedSet &Finalized);
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// for a nested region (top-level loop or nested loop)
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static void computeStackPO(BlockStack &Stack, const LoopInfo &LI, Loop *Loop,
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POCB CallBack, VisitedSet &Finalized) {
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const auto *LoopHeader = Loop ? Loop->getHeader() : nullptr;
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while (!Stack.empty()) {
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const auto *NextBB = Stack.back();
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auto *NestedLoop = LI.getLoopFor(NextBB);
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bool IsNestedLoop = NestedLoop != Loop;
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// Treat the loop as a node
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if (IsNestedLoop) {
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SmallVector<BasicBlock *, 3> NestedExits;
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NestedLoop->getUniqueExitBlocks(NestedExits);
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bool PushedNodes = false;
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for (const auto *NestedExitBB : NestedExits) {
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if (NestedExitBB == LoopHeader)
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continue;
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if (Loop && !Loop->contains(NestedExitBB))
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continue;
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if (Finalized.count(NestedExitBB))
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continue;
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PushedNodes = true;
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Stack.push_back(NestedExitBB);
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}
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if (!PushedNodes) {
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// All loop exits finalized -> finish this node
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Stack.pop_back();
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computeLoopPO(LI, *NestedLoop, CallBack, Finalized);
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}
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continue;
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}
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// DAG-style
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bool PushedNodes = false;
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for (const auto *SuccBB : successors(NextBB)) {
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if (SuccBB == LoopHeader)
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continue;
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if (Loop && !Loop->contains(SuccBB))
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continue;
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if (Finalized.count(SuccBB))
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continue;
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PushedNodes = true;
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Stack.push_back(SuccBB);
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}
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if (!PushedNodes) {
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// Never push nodes twice
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Stack.pop_back();
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if (!Finalized.insert(NextBB).second)
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continue;
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CallBack(*NextBB);
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}
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}
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}
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static void computeTopLevelPO(Function &F, const LoopInfo &LI, POCB CallBack) {
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VisitedSet Finalized;
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BlockStack Stack;
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Stack.reserve(24); // FIXME made-up number
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Stack.push_back(&F.getEntryBlock());
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computeStackPO(Stack, LI, nullptr, CallBack, Finalized);
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}
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static void computeLoopPO(const LoopInfo &LI, Loop &Loop, POCB CallBack,
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VisitedSet &Finalized) {
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/// Call CallBack on all loop blocks.
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std::vector<const BasicBlock *> Stack;
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const auto *LoopHeader = Loop.getHeader();
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// Visit the header last
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Finalized.insert(LoopHeader);
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CallBack(*LoopHeader);
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// Initialize with immediate successors
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for (const auto *BB : successors(LoopHeader)) {
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if (!Loop.contains(BB))
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continue;
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if (BB == LoopHeader)
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continue;
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Stack.push_back(BB);
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}
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// Compute PO inside region
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computeStackPO(Stack, LI, &Loop, CallBack, Finalized);
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}
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} // namespace
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namespace llvm {
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ControlDivergenceDesc SyncDependenceAnalysis::EmptyDivergenceDesc;
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SyncDependenceAnalysis::SyncDependenceAnalysis(const DominatorTree &DT,
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const PostDominatorTree &PDT,
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const LoopInfo &LI)
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: DT(DT), PDT(PDT), LI(LI) {
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computeTopLevelPO(*DT.getRoot()->getParent(), LI,
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[&](const BasicBlock &BB) { LoopPO.appendBlock(BB); });
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}
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SyncDependenceAnalysis::~SyncDependenceAnalysis() {}
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// divergence propagator for reducible CFGs
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struct DivergencePropagator {
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const ModifiedPO &LoopPOT;
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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 BasicBlock &DivTermBlock;
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// * if BlockLabels[IndexOf(B)] == C then C is the dominating definition at
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// block B
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// * if BlockLabels[IndexOf(B)] ~ undef then we haven't seen B yet
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// * if BlockLabels[IndexOf(B)] == B then B is a join point of disjoint paths
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// from X or B is an immediate successor of X (initial value).
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using BlockLabelVec = std::vector<const BasicBlock *>;
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BlockLabelVec BlockLabels;
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// divergent join and loop exit descriptor.
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std::unique_ptr<ControlDivergenceDesc> DivDesc;
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DivergencePropagator(const ModifiedPO &LoopPOT, const DominatorTree &DT,
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const PostDominatorTree &PDT, const LoopInfo &LI,
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const BasicBlock &DivTermBlock)
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: LoopPOT(LoopPOT), DT(DT), PDT(PDT), LI(LI), DivTermBlock(DivTermBlock),
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BlockLabels(LoopPOT.size(), nullptr),
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DivDesc(new ControlDivergenceDesc) {}
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void printDefs(raw_ostream &Out) {
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Out << "Propagator::BlockLabels {\n";
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for (int BlockIdx = (int)BlockLabels.size() - 1; BlockIdx > 0; --BlockIdx) {
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const auto *Label = BlockLabels[BlockIdx];
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Out << LoopPOT.getBlockAt(BlockIdx)->getName().str() << "(" << BlockIdx
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<< ") : ";
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if (!Label) {
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Out << "<null>\n";
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} else {
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Out << Label->getName() << "\n";
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}
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}
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Out << "}\n";
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}
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// Push a definition (\p PushedLabel) to \p SuccBlock and return whether this
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// causes a divergent join.
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bool computeJoin(const BasicBlock &SuccBlock, const BasicBlock &PushedLabel) {
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auto SuccIdx = LoopPOT.getIndexOf(SuccBlock);
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// unset or same reaching label
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const auto *OldLabel = BlockLabels[SuccIdx];
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if (!OldLabel || (OldLabel == &PushedLabel)) {
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BlockLabels[SuccIdx] = &PushedLabel;
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return false;
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}
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// Update the definition
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BlockLabels[SuccIdx] = &SuccBlock;
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return true;
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}
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// visiting a virtual loop exit edge from the loop header --> temporal
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// divergence on join
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bool visitLoopExitEdge(const BasicBlock &ExitBlock,
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const BasicBlock &DefBlock, bool FromParentLoop) {
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// Pushing from a non-parent loop cannot cause temporal divergence.
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if (!FromParentLoop)
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return visitEdge(ExitBlock, DefBlock);
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if (!computeJoin(ExitBlock, DefBlock))
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return false;
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// Identified a divergent loop exit
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DivDesc->LoopDivBlocks.insert(&ExitBlock);
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LLVM_DEBUG(dbgs() << "\tDivergent loop exit: " << ExitBlock.getName()
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<< "\n");
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return true;
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}
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// process \p SuccBlock with reaching definition \p DefBlock
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bool visitEdge(const BasicBlock &SuccBlock, const BasicBlock &DefBlock) {
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if (!computeJoin(SuccBlock, DefBlock))
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return false;
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// Divergent, disjoint paths join.
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DivDesc->JoinDivBlocks.insert(&SuccBlock);
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LLVM_DEBUG(dbgs() << "\tDivergent join: " << SuccBlock.getName());
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return true;
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}
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std::unique_ptr<ControlDivergenceDesc> computeJoinPoints() {
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assert(DivDesc);
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LLVM_DEBUG(dbgs() << "SDA:computeJoinPoints: " << DivTermBlock.getName()
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<< "\n");
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const auto *DivBlockLoop = LI.getLoopFor(&DivTermBlock);
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// Early stopping criterion
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int FloorIdx = LoopPOT.size() - 1;
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const BasicBlock *FloorLabel = nullptr;
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// bootstrap with branch targets
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int BlockIdx = 0;
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for (const auto *SuccBlock : successors(&DivTermBlock)) {
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auto SuccIdx = LoopPOT.getIndexOf(*SuccBlock);
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BlockLabels[SuccIdx] = SuccBlock;
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// Find the successor with the highest index to start with
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BlockIdx = std::max<int>(BlockIdx, SuccIdx);
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FloorIdx = std::min<int>(FloorIdx, SuccIdx);
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// Identify immediate divergent loop exits
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if (!DivBlockLoop)
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continue;
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const auto *BlockLoop = LI.getLoopFor(SuccBlock);
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if (BlockLoop && DivBlockLoop->contains(BlockLoop))
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continue;
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DivDesc->LoopDivBlocks.insert(SuccBlock);
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LLVM_DEBUG(dbgs() << "\tImmediate divergent loop exit: "
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<< SuccBlock->getName() << "\n");
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}
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// propagate definitions at the immediate successors of the node in RPO
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for (; BlockIdx >= FloorIdx; --BlockIdx) {
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LLVM_DEBUG(dbgs() << "Before next visit:\n"; printDefs(dbgs()));
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// Any label available here
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const auto *Label = BlockLabels[BlockIdx];
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if (!Label)
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continue;
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// Ok. Get the block
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const auto *Block = LoopPOT.getBlockAt(BlockIdx);
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LLVM_DEBUG(dbgs() << "SDA::joins. visiting " << Block->getName() << "\n");
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auto *BlockLoop = LI.getLoopFor(Block);
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bool IsLoopHeader = BlockLoop && BlockLoop->getHeader() == Block;
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bool CausedJoin = false;
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int LoweredFloorIdx = FloorIdx;
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if (IsLoopHeader) {
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// Disconnect from immediate successors and propagate directly to loop
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// exits.
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SmallVector<BasicBlock *, 4> BlockLoopExits;
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BlockLoop->getExitBlocks(BlockLoopExits);
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bool IsParentLoop = BlockLoop->contains(&DivTermBlock);
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for (const auto *BlockLoopExit : BlockLoopExits) {
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CausedJoin |= visitLoopExitEdge(*BlockLoopExit, *Label, IsParentLoop);
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LoweredFloorIdx = std::min<int>(LoweredFloorIdx,
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LoopPOT.getIndexOf(*BlockLoopExit));
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}
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} else {
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// Acyclic successor case
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for (const auto *SuccBlock : successors(Block)) {
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CausedJoin |= visitEdge(*SuccBlock, *Label);
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LoweredFloorIdx =
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std::min<int>(LoweredFloorIdx, LoopPOT.getIndexOf(*SuccBlock));
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}
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}
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// Floor update
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if (CausedJoin) {
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// 1. Different labels pushed to successors
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FloorIdx = LoweredFloorIdx;
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} else if (FloorLabel != Label) {
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// 2. No join caused BUT we pushed a label that is different than the
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// last pushed label
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FloorIdx = LoweredFloorIdx;
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FloorLabel = Label;
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}
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}
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LLVM_DEBUG(dbgs() << "SDA::joins. After propagation:\n"; printDefs(dbgs()));
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return std::move(DivDesc);
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}
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};
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#ifndef NDEBUG
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static void printBlockSet(ConstBlockSet &Blocks, raw_ostream &Out) {
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Out << "[";
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ListSeparator LS;
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for (const auto *BB : Blocks)
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Out << LS << BB->getName();
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Out << "]";
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}
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#endif
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const ControlDivergenceDesc &
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SyncDependenceAnalysis::getJoinBlocks(const Instruction &Term) {
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// trivial case
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if (Term.getNumSuccessors() <= 1) {
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return EmptyDivergenceDesc;
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}
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// already available in cache?
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auto ItCached = CachedControlDivDescs.find(&Term);
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if (ItCached != CachedControlDivDescs.end())
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return *ItCached->second;
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// compute all join points
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// Special handling of divergent loop exits is not needed for LCSSA
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const auto &TermBlock = *Term.getParent();
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DivergencePropagator Propagator(LoopPO, DT, PDT, LI, TermBlock);
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auto DivDesc = Propagator.computeJoinPoints();
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LLVM_DEBUG(dbgs() << "Result (" << Term.getParent()->getName() << "):\n";
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dbgs() << "JoinDivBlocks: ";
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printBlockSet(DivDesc->JoinDivBlocks, dbgs());
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dbgs() << "\nLoopDivBlocks: ";
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printBlockSet(DivDesc->LoopDivBlocks, dbgs()); dbgs() << "\n";);
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auto ItInserted = CachedControlDivDescs.emplace(&Term, std::move(DivDesc));
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assert(ItInserted.second);
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return *ItInserted.first->second;
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}
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} // namespace llvm
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