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042041bdf3
disturbing the graph or having to update edges. This is motivated by porting argument promotion to the new pass manager. Because of how LLVM IR Function objects work, in order to change their signature a new object needs to be created. This is efficient and straight forward in the IR but previously was very hard to implement in LCG. We could easily replace the function a node in the graph represents. The challenging part is how to handle updating the edges in the graph. LCG previously used an edge to a raw function to represent a node that had not yet been scanned for calls and references. This was the core of its laziness. However, that model causes this kind of update to be very hard: 1) The keys to lookup an edge need to be `Function*`s that would all need to be updated when we update the node. 2) There will be some unknown number of edges that haven't transitioned from `Function*` edges to `Node*` edges. All of this complexity isn't necessary. Instead, we can always build a node around any function, always pointing edges at it and always using it as the key to lookup an edge. To maintain the laziness, we need to sink the *edges* of a node into a secondary object and explicitly model transitioning a node from empty to populated by scanning the function. This design seems much cleaner in a number of ways, but importantly there is now exactly *one* place where the `Function*` has to be updated! Some other cleanups that fall out of this include having something to model the *entry* edges more accurately. Rather than hand rolling parts of the node in the graph itself, we have an explicit `EdgeSequence` object that gives us exactly the functionality needed. We also have a consistent place to define the edge iterators and can use them for both the entry edges and the internal edges of the graph. The API used to model the separation between a node and its edges is intentionally very thin as most clients are expected to deal with nodes that have populated edges. We model this exactly as an optional does with an additional method to populate the edges when that is a reasonable thing for a client to do. This is based on API design suggestions from Richard Smith and David Blaikie, credit goes to them for helping pick how to model this without it being either too explicit or too implicit. The patch is somewhat noisy due to shifting around iterator types and new syntax for walking the edges of a node, but most of the functionality change is in the `Edge`, `EdgeSequence`, and `Node` types. Differential Revision: https://reviews.llvm.org/D29577 llvm-svn: 294653
515 lines
21 KiB
C++
515 lines
21 KiB
C++
//===- CGSCCPassManager.cpp - Managing & running CGSCC passes -------------===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Analysis/CGSCCPassManager.h"
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#include "llvm/IR/CallSite.h"
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#include "llvm/IR/InstIterator.h"
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using namespace llvm;
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// Explicit template instantiations and specialization defininitions for core
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// template typedefs.
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namespace llvm {
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// Explicit instantiations for the core proxy templates.
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template class AllAnalysesOn<LazyCallGraph::SCC>;
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template class AnalysisManager<LazyCallGraph::SCC, LazyCallGraph &>;
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template class PassManager<LazyCallGraph::SCC, CGSCCAnalysisManager,
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LazyCallGraph &, CGSCCUpdateResult &>;
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template class InnerAnalysisManagerProxy<CGSCCAnalysisManager, Module>;
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template class OuterAnalysisManagerProxy<ModuleAnalysisManager,
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LazyCallGraph::SCC, LazyCallGraph &>;
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template class OuterAnalysisManagerProxy<CGSCCAnalysisManager, Function>;
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/// Explicitly specialize the pass manager run method to handle call graph
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/// updates.
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template <>
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PreservedAnalyses
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PassManager<LazyCallGraph::SCC, CGSCCAnalysisManager, LazyCallGraph &,
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CGSCCUpdateResult &>::run(LazyCallGraph::SCC &InitialC,
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CGSCCAnalysisManager &AM,
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LazyCallGraph &G, CGSCCUpdateResult &UR) {
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PreservedAnalyses PA = PreservedAnalyses::all();
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if (DebugLogging)
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dbgs() << "Starting CGSCC pass manager run.\n";
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// The SCC may be refined while we are running passes over it, so set up
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// a pointer that we can update.
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LazyCallGraph::SCC *C = &InitialC;
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for (auto &Pass : Passes) {
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if (DebugLogging)
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dbgs() << "Running pass: " << Pass->name() << " on " << *C << "\n";
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PreservedAnalyses PassPA = Pass->run(*C, AM, G, UR);
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// Update the SCC if necessary.
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C = UR.UpdatedC ? UR.UpdatedC : C;
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// Check that we didn't miss any update scenario.
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assert(!UR.InvalidatedSCCs.count(C) && "Processing an invalid SCC!");
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assert(C->begin() != C->end() && "Cannot have an empty SCC!");
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// Update the analysis manager as each pass runs and potentially
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// invalidates analyses.
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AM.invalidate(*C, PassPA);
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// Finally, we intersect the final preserved analyses to compute the
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// aggregate preserved set for this pass manager.
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PA.intersect(std::move(PassPA));
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// FIXME: Historically, the pass managers all called the LLVM context's
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// yield function here. We don't have a generic way to acquire the
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// context and it isn't yet clear what the right pattern is for yielding
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// in the new pass manager so it is currently omitted.
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// ...getContext().yield();
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}
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// Invaliadtion was handled after each pass in the above loop for the current
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// SCC. Therefore, the remaining analysis results in the AnalysisManager are
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// preserved. We mark this with a set so that we don't need to inspect each
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// one individually.
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PA.preserveSet<AllAnalysesOn<LazyCallGraph::SCC>>();
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if (DebugLogging)
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dbgs() << "Finished CGSCC pass manager run.\n";
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return PA;
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}
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bool CGSCCAnalysisManagerModuleProxy::Result::invalidate(
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Module &M, const PreservedAnalyses &PA,
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ModuleAnalysisManager::Invalidator &Inv) {
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// If literally everything is preserved, we're done.
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if (PA.areAllPreserved())
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return false; // This is still a valid proxy.
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// If this proxy or the call graph is going to be invalidated, we also need
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// to clear all the keys coming from that analysis.
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//
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// We also directly invalidate the FAM's module proxy if necessary, and if
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// that proxy isn't preserved we can't preserve this proxy either. We rely on
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// it to handle module -> function analysis invalidation in the face of
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// structural changes and so if it's unavailable we conservatively clear the
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// entire SCC layer as well rather than trying to do invalidation ourselves.
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auto PAC = PA.getChecker<CGSCCAnalysisManagerModuleProxy>();
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if (!(PAC.preserved() || PAC.preservedSet<AllAnalysesOn<Module>>()) ||
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Inv.invalidate<LazyCallGraphAnalysis>(M, PA) ||
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Inv.invalidate<FunctionAnalysisManagerModuleProxy>(M, PA)) {
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InnerAM->clear();
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// And the proxy itself should be marked as invalid so that we can observe
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// the new call graph. This isn't strictly necessary because we cheat
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// above, but is still useful.
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return true;
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}
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// Directly check if the relevant set is preserved so we can short circuit
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// invalidating SCCs below.
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bool AreSCCAnalysesPreserved =
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PA.allAnalysesInSetPreserved<AllAnalysesOn<LazyCallGraph::SCC>>();
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// Ok, we have a graph, so we can propagate the invalidation down into it.
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G->buildRefSCCs();
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for (auto &RC : G->postorder_ref_sccs())
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for (auto &C : RC) {
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Optional<PreservedAnalyses> InnerPA;
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// Check to see whether the preserved set needs to be adjusted based on
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// module-level analysis invalidation triggering deferred invalidation
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// for this SCC.
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if (auto *OuterProxy =
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InnerAM->getCachedResult<ModuleAnalysisManagerCGSCCProxy>(C))
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for (const auto &OuterInvalidationPair :
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OuterProxy->getOuterInvalidations()) {
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AnalysisKey *OuterAnalysisID = OuterInvalidationPair.first;
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const auto &InnerAnalysisIDs = OuterInvalidationPair.second;
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if (Inv.invalidate(OuterAnalysisID, M, PA)) {
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if (!InnerPA)
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InnerPA = PA;
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for (AnalysisKey *InnerAnalysisID : InnerAnalysisIDs)
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InnerPA->abandon(InnerAnalysisID);
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}
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}
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// Check if we needed a custom PA set. If so we'll need to run the inner
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// invalidation.
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if (InnerPA) {
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InnerAM->invalidate(C, *InnerPA);
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continue;
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}
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// Otherwise we only need to do invalidation if the original PA set didn't
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// preserve all SCC analyses.
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if (!AreSCCAnalysesPreserved)
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InnerAM->invalidate(C, PA);
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}
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// Return false to indicate that this result is still a valid proxy.
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return false;
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}
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template <>
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CGSCCAnalysisManagerModuleProxy::Result
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CGSCCAnalysisManagerModuleProxy::run(Module &M, ModuleAnalysisManager &AM) {
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// Force the Function analysis manager to also be available so that it can
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// be accessed in an SCC analysis and proxied onward to function passes.
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// FIXME: It is pretty awkward to just drop the result here and assert that
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// we can find it again later.
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(void)AM.getResult<FunctionAnalysisManagerModuleProxy>(M);
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return Result(*InnerAM, AM.getResult<LazyCallGraphAnalysis>(M));
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}
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AnalysisKey FunctionAnalysisManagerCGSCCProxy::Key;
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FunctionAnalysisManagerCGSCCProxy::Result
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FunctionAnalysisManagerCGSCCProxy::run(LazyCallGraph::SCC &C,
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CGSCCAnalysisManager &AM,
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LazyCallGraph &CG) {
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// Collect the FunctionAnalysisManager from the Module layer and use that to
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// build the proxy result.
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//
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// This allows us to rely on the FunctionAnalysisMangaerModuleProxy to
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// invalidate the function analyses.
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auto &MAM = AM.getResult<ModuleAnalysisManagerCGSCCProxy>(C, CG).getManager();
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Module &M = *C.begin()->getFunction().getParent();
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auto *FAMProxy = MAM.getCachedResult<FunctionAnalysisManagerModuleProxy>(M);
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assert(FAMProxy && "The CGSCC pass manager requires that the FAM module "
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"proxy is run on the module prior to entering the CGSCC "
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"walk.");
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// Note that we special-case invalidation handling of this proxy in the CGSCC
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// analysis manager's Module proxy. This avoids the need to do anything
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// special here to recompute all of this if ever the FAM's module proxy goes
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// away.
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return Result(FAMProxy->getManager());
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}
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bool FunctionAnalysisManagerCGSCCProxy::Result::invalidate(
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LazyCallGraph::SCC &C, const PreservedAnalyses &PA,
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CGSCCAnalysisManager::Invalidator &Inv) {
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for (LazyCallGraph::Node &N : C)
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FAM->invalidate(N.getFunction(), PA);
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// This proxy doesn't need to handle invalidation itself. Instead, the
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// module-level CGSCC proxy handles it above by ensuring that if the
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// module-level FAM proxy becomes invalid the entire SCC layer, which
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// includes this proxy, is cleared.
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return false;
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}
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} // End llvm namespace
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namespace {
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/// Helper function to update both the \c CGSCCAnalysisManager \p AM and the \c
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/// CGSCCPassManager's \c CGSCCUpdateResult \p UR based on a range of newly
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/// added SCCs.
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///
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/// The range of new SCCs must be in postorder already. The SCC they were split
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/// out of must be provided as \p C. The current node being mutated and
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/// triggering updates must be passed as \p N.
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///
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/// This function returns the SCC containing \p N. This will be either \p C if
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/// no new SCCs have been split out, or it will be the new SCC containing \p N.
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template <typename SCCRangeT>
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LazyCallGraph::SCC *
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incorporateNewSCCRange(const SCCRangeT &NewSCCRange, LazyCallGraph &G,
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LazyCallGraph::Node &N, LazyCallGraph::SCC *C,
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CGSCCAnalysisManager &AM, CGSCCUpdateResult &UR,
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bool DebugLogging = false) {
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typedef LazyCallGraph::SCC SCC;
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if (NewSCCRange.begin() == NewSCCRange.end())
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return C;
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// Add the current SCC to the worklist as its shape has changed.
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UR.CWorklist.insert(C);
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if (DebugLogging)
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dbgs() << "Enqueuing the existing SCC in the worklist:" << *C << "\n";
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SCC *OldC = C;
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(void)OldC;
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// Update the current SCC. Note that if we have new SCCs, this must actually
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// change the SCC.
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assert(C != &*NewSCCRange.begin() &&
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"Cannot insert new SCCs without changing current SCC!");
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C = &*NewSCCRange.begin();
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assert(G.lookupSCC(N) == C && "Failed to update current SCC!");
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for (SCC &NewC :
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reverse(make_range(std::next(NewSCCRange.begin()), NewSCCRange.end()))) {
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assert(C != &NewC && "No need to re-visit the current SCC!");
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assert(OldC != &NewC && "Already handled the original SCC!");
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UR.CWorklist.insert(&NewC);
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if (DebugLogging)
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dbgs() << "Enqueuing a newly formed SCC:" << NewC << "\n";
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}
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return C;
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}
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}
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LazyCallGraph::SCC &llvm::updateCGAndAnalysisManagerForFunctionPass(
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LazyCallGraph &G, LazyCallGraph::SCC &InitialC, LazyCallGraph::Node &N,
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CGSCCAnalysisManager &AM, CGSCCUpdateResult &UR, bool DebugLogging) {
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typedef LazyCallGraph::Node Node;
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typedef LazyCallGraph::Edge Edge;
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typedef LazyCallGraph::SCC SCC;
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typedef LazyCallGraph::RefSCC RefSCC;
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RefSCC &InitialRC = InitialC.getOuterRefSCC();
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SCC *C = &InitialC;
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RefSCC *RC = &InitialRC;
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Function &F = N.getFunction();
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// Walk the function body and build up the set of retained, promoted, and
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// demoted edges.
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SmallVector<Constant *, 16> Worklist;
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SmallPtrSet<Constant *, 16> Visited;
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SmallPtrSet<Node *, 16> RetainedEdges;
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SmallSetVector<Node *, 4> PromotedRefTargets;
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SmallSetVector<Node *, 4> DemotedCallTargets;
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// First walk the function and handle all called functions. We do this first
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// because if there is a single call edge, whether there are ref edges is
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// irrelevant.
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for (Instruction &I : instructions(F))
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if (auto CS = CallSite(&I))
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if (Function *Callee = CS.getCalledFunction())
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if (Visited.insert(Callee).second && !Callee->isDeclaration()) {
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Node &CalleeN = *G.lookup(*Callee);
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Edge *E = N->lookup(CalleeN);
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// FIXME: We should really handle adding new calls. While it will
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// make downstream usage more complex, there is no fundamental
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// limitation and it will allow passes within the CGSCC to be a bit
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// more flexible in what transforms they can do. Until then, we
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// verify that new calls haven't been introduced.
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assert(E && "No function transformations should introduce *new* "
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"call edges! Any new calls should be modeled as "
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"promoted existing ref edges!");
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RetainedEdges.insert(&CalleeN);
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if (!E->isCall())
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PromotedRefTargets.insert(&CalleeN);
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}
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// Now walk all references.
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for (Instruction &I : instructions(F))
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for (Value *Op : I.operand_values())
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if (Constant *C = dyn_cast<Constant>(Op))
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if (Visited.insert(C).second)
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Worklist.push_back(C);
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LazyCallGraph::visitReferences(Worklist, Visited, [&](Function &Referee) {
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Node &RefereeN = *G.lookup(Referee);
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Edge *E = N->lookup(RefereeN);
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// FIXME: Similarly to new calls, we also currently preclude
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// introducing new references. See above for details.
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assert(E && "No function transformations should introduce *new* ref "
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"edges! Any new ref edges would require IPO which "
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"function passes aren't allowed to do!");
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RetainedEdges.insert(&RefereeN);
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if (E->isCall())
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DemotedCallTargets.insert(&RefereeN);
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});
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// First remove all of the edges that are no longer present in this function.
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// We have to build a list of dead targets first and then remove them as the
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// data structures will all be invalidated by removing them.
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SmallVector<PointerIntPair<Node *, 1, Edge::Kind>, 4> DeadTargets;
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for (Edge &E : *N)
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if (!RetainedEdges.count(&E.getNode()))
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DeadTargets.push_back({&E.getNode(), E.getKind()});
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for (auto DeadTarget : DeadTargets) {
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Node &TargetN = *DeadTarget.getPointer();
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bool IsCall = DeadTarget.getInt() == Edge::Call;
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SCC &TargetC = *G.lookupSCC(TargetN);
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RefSCC &TargetRC = TargetC.getOuterRefSCC();
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if (&TargetRC != RC) {
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RC->removeOutgoingEdge(N, TargetN);
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if (DebugLogging)
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dbgs() << "Deleting outgoing edge from '" << N << "' to '" << TargetN
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<< "'\n";
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continue;
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}
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if (DebugLogging)
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dbgs() << "Deleting internal " << (IsCall ? "call" : "ref")
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<< " edge from '" << N << "' to '" << TargetN << "'\n";
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if (IsCall) {
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if (C != &TargetC) {
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// For separate SCCs this is trivial.
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RC->switchTrivialInternalEdgeToRef(N, TargetN);
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} else {
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// Otherwise we may end up re-structuring the call graph. First,
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// invalidate any SCC analyses. We have to do this before we split
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// functions into new SCCs and lose track of where their analyses are
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// cached.
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// FIXME: We should accept a more precise preserved set here. For
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// example, it might be possible to preserve some function analyses
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// even as the SCC structure is changed.
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AM.invalidate(*C, PreservedAnalyses::none());
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// Now update the call graph.
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C = incorporateNewSCCRange(RC->switchInternalEdgeToRef(N, TargetN), G,
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N, C, AM, UR, DebugLogging);
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}
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}
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auto NewRefSCCs = RC->removeInternalRefEdge(N, TargetN);
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if (!NewRefSCCs.empty()) {
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// Note that we don't bother to invalidate analyses as ref-edge
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// connectivity is not really observable in any way and is intended
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// exclusively to be used for ordering of transforms rather than for
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// analysis conclusions.
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// The RC worklist is in reverse postorder, so we first enqueue the
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// current RefSCC as it will remain the parent of all split RefSCCs, then
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// we enqueue the new ones in RPO except for the one which contains the
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// source node as that is the "bottom" we will continue processing in the
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// bottom-up walk.
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UR.RCWorklist.insert(RC);
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if (DebugLogging)
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dbgs() << "Enqueuing the existing RefSCC in the update worklist: "
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<< *RC << "\n";
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// Update the RC to the "bottom".
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assert(G.lookupSCC(N) == C && "Changed the SCC when splitting RefSCCs!");
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RC = &C->getOuterRefSCC();
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assert(G.lookupRefSCC(N) == RC && "Failed to update current RefSCC!");
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assert(NewRefSCCs.front() == RC &&
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"New current RefSCC not first in the returned list!");
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for (RefSCC *NewRC : reverse(
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make_range(std::next(NewRefSCCs.begin()), NewRefSCCs.end()))) {
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assert(NewRC != RC && "Should not encounter the current RefSCC further "
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"in the postorder list of new RefSCCs.");
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UR.RCWorklist.insert(NewRC);
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if (DebugLogging)
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dbgs() << "Enqueuing a new RefSCC in the update worklist: " << *NewRC
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<< "\n";
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}
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}
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}
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// Next demote all the call edges that are now ref edges. This helps make
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// the SCCs small which should minimize the work below as we don't want to
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// form cycles that this would break.
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for (Node *RefTarget : DemotedCallTargets) {
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SCC &TargetC = *G.lookupSCC(*RefTarget);
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RefSCC &TargetRC = TargetC.getOuterRefSCC();
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// The easy case is when the target RefSCC is not this RefSCC. This is
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// only supported when the target RefSCC is a child of this RefSCC.
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if (&TargetRC != RC) {
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assert(RC->isAncestorOf(TargetRC) &&
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"Cannot potentially form RefSCC cycles here!");
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RC->switchOutgoingEdgeToRef(N, *RefTarget);
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if (DebugLogging)
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dbgs() << "Switch outgoing call edge to a ref edge from '" << N
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<< "' to '" << *RefTarget << "'\n";
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continue;
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}
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// We are switching an internal call edge to a ref edge. This may split up
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// some SCCs.
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if (C != &TargetC) {
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// For separate SCCs this is trivial.
|
|
RC->switchTrivialInternalEdgeToRef(N, *RefTarget);
|
|
continue;
|
|
}
|
|
|
|
// Otherwise we may end up re-structuring the call graph. First, invalidate
|
|
// any SCC analyses. We have to do this before we split functions into new
|
|
// SCCs and lose track of where their analyses are cached.
|
|
// FIXME: We should accept a more precise preserved set here. For example,
|
|
// it might be possible to preserve some function analyses even as the SCC
|
|
// structure is changed.
|
|
AM.invalidate(*C, PreservedAnalyses::none());
|
|
// Now update the call graph.
|
|
C = incorporateNewSCCRange(RC->switchInternalEdgeToRef(N, *RefTarget), G, N,
|
|
C, AM, UR, DebugLogging);
|
|
}
|
|
|
|
// Now promote ref edges into call edges.
|
|
for (Node *CallTarget : PromotedRefTargets) {
|
|
SCC &TargetC = *G.lookupSCC(*CallTarget);
|
|
RefSCC &TargetRC = TargetC.getOuterRefSCC();
|
|
|
|
// The easy case is when the target RefSCC is not this RefSCC. This is
|
|
// only supported when the target RefSCC is a child of this RefSCC.
|
|
if (&TargetRC != RC) {
|
|
assert(RC->isAncestorOf(TargetRC) &&
|
|
"Cannot potentially form RefSCC cycles here!");
|
|
RC->switchOutgoingEdgeToCall(N, *CallTarget);
|
|
if (DebugLogging)
|
|
dbgs() << "Switch outgoing ref edge to a call edge from '" << N
|
|
<< "' to '" << *CallTarget << "'\n";
|
|
continue;
|
|
}
|
|
if (DebugLogging)
|
|
dbgs() << "Switch an internal ref edge to a call edge from '" << N
|
|
<< "' to '" << *CallTarget << "'\n";
|
|
|
|
// Otherwise we are switching an internal ref edge to a call edge. This
|
|
// may merge away some SCCs, and we add those to the UpdateResult. We also
|
|
// need to make sure to update the worklist in the event SCCs have moved
|
|
// before the current one in the post-order sequence.
|
|
auto InitialSCCIndex = RC->find(*C) - RC->begin();
|
|
auto InvalidatedSCCs = RC->switchInternalEdgeToCall(N, *CallTarget);
|
|
if (!InvalidatedSCCs.empty()) {
|
|
C = &TargetC;
|
|
assert(G.lookupSCC(N) == C && "Failed to update current SCC!");
|
|
|
|
// Any analyses cached for this SCC are no longer precise as the shape
|
|
// has changed by introducing this cycle.
|
|
AM.invalidate(*C, PreservedAnalyses::none());
|
|
|
|
for (SCC *InvalidatedC : InvalidatedSCCs) {
|
|
assert(InvalidatedC != C && "Cannot invalidate the current SCC!");
|
|
UR.InvalidatedSCCs.insert(InvalidatedC);
|
|
|
|
// Also clear any cached analyses for the SCCs that are dead. This
|
|
// isn't really necessary for correctness but can release memory.
|
|
AM.clear(*InvalidatedC);
|
|
}
|
|
}
|
|
auto NewSCCIndex = RC->find(*C) - RC->begin();
|
|
if (InitialSCCIndex < NewSCCIndex) {
|
|
// Put our current SCC back onto the worklist as we'll visit other SCCs
|
|
// that are now definitively ordered prior to the current one in the
|
|
// post-order sequence, and may end up observing more precise context to
|
|
// optimize the current SCC.
|
|
UR.CWorklist.insert(C);
|
|
if (DebugLogging)
|
|
dbgs() << "Enqueuing the existing SCC in the worklist: " << *C << "\n";
|
|
// Enqueue in reverse order as we pop off the back of the worklist.
|
|
for (SCC &MovedC : reverse(make_range(RC->begin() + InitialSCCIndex,
|
|
RC->begin() + NewSCCIndex))) {
|
|
UR.CWorklist.insert(&MovedC);
|
|
if (DebugLogging)
|
|
dbgs() << "Enqueuing a newly earlier in post-order SCC: " << MovedC
|
|
<< "\n";
|
|
}
|
|
}
|
|
}
|
|
|
|
assert(!UR.InvalidatedSCCs.count(C) && "Invalidated the current SCC!");
|
|
assert(!UR.InvalidatedRefSCCs.count(RC) && "Invalidated the current RefSCC!");
|
|
assert(&C->getOuterRefSCC() == RC && "Current SCC not in current RefSCC!");
|
|
|
|
// Record the current RefSCC and SCC for higher layers of the CGSCC pass
|
|
// manager now that all the updates have been applied.
|
|
if (RC != &InitialRC)
|
|
UR.UpdatedRC = RC;
|
|
if (C != &InitialC)
|
|
UR.UpdatedC = C;
|
|
|
|
return *C;
|
|
}
|