//===- PassManager.h - Pass management infrastructure -----------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
/// \file
///
/// This header defines various interfaces for pass management in LLVM. There
/// is no "pass" interface in LLVM per se. Instead, an instance of any class
/// which supports a method to 'run' it over a unit of IR can be used as
/// a pass. A pass manager is generally a tool to collect a sequence of passes
/// which run over a particular IR construct, and run each of them in sequence
/// over each such construct in the containing IR construct. As there is no
/// containing IR construct for a Module, a manager for passes over modules
/// forms the base case which runs its managed passes in sequence over the
/// single module provided.
///
/// The core IR library provides managers for running passes over
/// modules and functions.
///
/// * FunctionPassManager can run over a Module, runs each pass over
/// a Function.
/// * ModulePassManager must be directly run, runs each pass over the Module.
///
/// Note that the implementations of the pass managers use concept-based
/// polymorphism as outlined in the "Value Semantics and Concept-based
/// Polymorphism" talk (or its abbreviated sibling "Inheritance Is The Base
/// Class of Evil") by Sean Parent:
/// * http://github.com/sean-parent/sean-parent.github.com/wiki/Papers-and-Presentations
/// * http://www.youtube.com/watch?v=_BpMYeUFXv8
/// * http://channel9.msdn.com/Events/GoingNative/2013/Inheritance-Is-The-Base-Class-of-Evil
///
//===----------------------------------------------------------------------===//
#ifndef LLVM_IR_PASSMANAGER_H
#define LLVM_IR_PASSMANAGER_H
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/TinyPtrVector.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/Module.h"
#include "llvm/IR/PassInstrumentation.h"
#include "llvm/IR/PassManagerInternal.h"
#include "llvm/Support/TimeProfiler.h"
#include "llvm/Support/TypeName.h"
#include <cassert>
#include <cstring>
#include <iterator>
#include <list>
#include <memory>
#include <tuple>
#include <type_traits>
#include <utility>
#include <vector>
namespace llvm {
/// A special type used by analysis passes to provide an address that
/// identifies that particular analysis pass type.
///
/// Analysis passes should have a static data member of this type and derive
/// from the \c AnalysisInfoMixin to get a static ID method used to identify
/// the analysis in the pass management infrastructure.
struct alignas(8) AnalysisKey {};
/// A special type used to provide an address that identifies a set of related
/// analyses. These sets are primarily used below to mark sets of analyses as
/// preserved.
///
/// For example, a transformation can indicate that it preserves the CFG of a
/// function by preserving the appropriate AnalysisSetKey. An analysis that
/// depends only on the CFG can then check if that AnalysisSetKey is preserved;
/// if it is, the analysis knows that it itself is preserved.
struct alignas(8) AnalysisSetKey {};
/// This templated class represents "all analyses that operate over \<a
/// particular IR unit\>" (e.g. a Function or a Module) in instances of
/// PreservedAnalysis.
///
/// This lets a transformation say e.g. "I preserved all function analyses".
///
/// Note that you must provide an explicit instantiation declaration and
/// definition for this template in order to get the correct behavior on
/// Windows. Otherwise, the address of SetKey will not be stable.
template <typename IRUnitT> class AllAnalysesOn {
public:
static AnalysisSetKey *ID() { return &SetKey; }
private:
static AnalysisSetKey SetKey;
};
template <typename IRUnitT> AnalysisSetKey AllAnalysesOn<IRUnitT>::SetKey;
extern template class AllAnalysesOn<Module>;
extern template class AllAnalysesOn<Function>;
/// Represents analyses that only rely on functions' control flow.
///
/// This can be used with \c PreservedAnalyses to mark the CFG as preserved and
/// to query whether it has been preserved.
///
/// The CFG of a function is defined as the set of basic blocks and the edges
/// between them. Changing the set of basic blocks in a function is enough to
/// mutate the CFG. Mutating the condition of a branch or argument of an
/// invoked function does not mutate the CFG, but changing the successor labels
/// of those instructions does.
class CFGAnalyses {
public:
static AnalysisSetKey *ID() { return &SetKey; }
private:
static AnalysisSetKey SetKey;
};
/// A set of analyses that are preserved following a run of a transformation
/// pass.
///
/// Transformation passes build and return these objects to communicate which
/// analyses are still valid after the transformation. For most passes this is
/// fairly simple: if they don't change anything all analyses are preserved,
/// otherwise only a short list of analyses that have been explicitly updated
/// are preserved.
///
/// This class also lets transformation passes mark abstract *sets* of analyses
/// as preserved. A transformation that (say) does not alter the CFG can
/// indicate such by marking a particular AnalysisSetKey as preserved, and
/// then analyses can query whether that AnalysisSetKey is preserved.
///
/// Finally, this class can represent an "abandoned" analysis, which is
/// not preserved even if it would be covered by some abstract set of analyses.
///
/// Given a `PreservedAnalyses` object, an analysis will typically want to
/// figure out whether it is preserved. In the example below, MyAnalysisType is
/// preserved if it's not abandoned, and (a) it's explicitly marked as
/// preserved, (b), the set AllAnalysesOn<MyIRUnit> is preserved, or (c) both
/// AnalysisSetA and AnalysisSetB are preserved.
///
/// ```
/// auto PAC = PA.getChecker<MyAnalysisType>();
/// if (PAC.preserved() || PAC.preservedSet<AllAnalysesOn<MyIRUnit>>() ||
/// (PAC.preservedSet<AnalysisSetA>() &&
/// PAC.preservedSet<AnalysisSetB>())) {
/// // The analysis has been successfully preserved ...
/// }
/// ```
class PreservedAnalyses {
public:
/// Convenience factory function for the empty preserved set.
static PreservedAnalyses none() { return PreservedAnalyses(); }
/// Construct a special preserved set that preserves all passes.
static PreservedAnalyses all() {
PreservedAnalyses PA;
PA.PreservedIDs.insert(&AllAnalysesKey);
return PA;
}
/// Construct a preserved analyses object with a single preserved set.
template <typename AnalysisSetT>
static PreservedAnalyses allInSet() {
PreservedAnalyses PA;
PA.preserveSet<AnalysisSetT>();
return PA;
}
/// Mark an analysis as preserved.
template <typename AnalysisT> void preserve() { preserve(AnalysisT::ID()); }
/// Given an analysis's ID, mark the analysis as preserved, adding it
/// to the set.
void preserve(AnalysisKey *ID) {
// Clear this ID from the explicit not-preserved set if present.
NotPreservedAnalysisIDs.erase(ID);
// If we're not already preserving all analyses (other than those in
// NotPreservedAnalysisIDs).
if (!areAllPreserved())
PreservedIDs.insert(ID);
}
/// Mark an analysis set as preserved.
template <typename AnalysisSetT> void preserveSet() {
preserveSet(AnalysisSetT::ID());
}
/// Mark an analysis set as preserved using its ID.
void preserveSet(AnalysisSetKey *ID) {
// If we're not already in the saturated 'all' state, add this set.
if (!areAllPreserved())
PreservedIDs.insert(ID);
}
/// Mark an analysis as abandoned.
///
/// An abandoned analysis is not preserved, even if it is nominally covered
/// by some other set or was previously explicitly marked as preserved.
///
/// Note that you can only abandon a specific analysis, not a *set* of
/// analyses.
template <typename AnalysisT> void abandon() { abandon(AnalysisT::ID()); }
/// Mark an analysis as abandoned using its ID.
///
/// An abandoned analysis is not preserved, even if it is nominally covered
/// by some other set or was previously explicitly marked as preserved.
///
/// Note that you can only abandon a specific analysis, not a *set* of
/// analyses.
void abandon(AnalysisKey *ID) {
PreservedIDs.erase(ID);
NotPreservedAnalysisIDs.insert(ID);
}
/// Intersect this set with another in place.
///
/// This is a mutating operation on this preserved set, removing all
/// preserved passes which are not also preserved in the argument.
void intersect(const PreservedAnalyses &Arg) {
if (Arg.areAllPreserved())
return;
if (areAllPreserved()) {
*this = Arg;
return;
}
// The intersection requires the *union* of the explicitly not-preserved
// IDs and the *intersection* of the preserved IDs.
for (auto ID : Arg.NotPreservedAnalysisIDs) {
PreservedIDs.erase(ID);
NotPreservedAnalysisIDs.insert(ID);
}
for (auto ID : PreservedIDs)
if (!Arg.PreservedIDs.count(ID))
PreservedIDs.erase(ID);
}
/// Intersect this set with a temporary other set in place.
///
/// This is a mutating operation on this preserved set, removing all
/// preserved passes which are not also preserved in the argument.
void intersect(PreservedAnalyses &&Arg) {
if (Arg.areAllPreserved())
return;
if (areAllPreserved()) {
*this = std::move(Arg);
return;
}
// The intersection requires the *union* of the explicitly not-preserved
// IDs and the *intersection* of the preserved IDs.
for (auto ID : Arg.NotPreservedAnalysisIDs) {
PreservedIDs.erase(ID);
NotPreservedAnalysisIDs.insert(ID);
}
for (auto ID : PreservedIDs)
if (!Arg.PreservedIDs.count(ID))
PreservedIDs.erase(ID);
}
/// A checker object that makes it easy to query for whether an analysis or
/// some set covering it is preserved.
class PreservedAnalysisChecker {
friend class PreservedAnalyses;
const PreservedAnalyses &PA;
AnalysisKey *const ID;
const bool IsAbandoned;
/// A PreservedAnalysisChecker is tied to a particular Analysis because
/// `preserved()` and `preservedSet()` both return false if the Analysis
/// was abandoned.
PreservedAnalysisChecker(const PreservedAnalyses &PA, AnalysisKey *ID)
: PA(PA), ID(ID), IsAbandoned(PA.NotPreservedAnalysisIDs.count(ID)) {}
public:
/// Returns true if the checker's analysis was not abandoned and either
/// - the analysis is explicitly preserved or
/// - all analyses are preserved.
bool preserved() {
return !IsAbandoned && (PA.PreservedIDs.count(&AllAnalysesKey) ||
PA.PreservedIDs.count(ID));
}
/// Return true if the checker's analysis was not abandoned, i.e. it was not
/// explicitly invalidated. Even if the analysis is not explicitly
/// preserved, if the analysis is known stateless, then it is preserved.
bool preservedWhenStateless() {
return !IsAbandoned;
}
/// Returns true if the checker's analysis was not abandoned and either
/// - \p AnalysisSetT is explicitly preserved or
/// - all analyses are preserved.
template <typename AnalysisSetT> bool preservedSet() {
AnalysisSetKey *SetID = AnalysisSetT::ID();
return !IsAbandoned && (PA.PreservedIDs.count(&AllAnalysesKey) ||
PA.PreservedIDs.count(SetID));
}
};
/// Build a checker for this `PreservedAnalyses` and the specified analysis
/// type.
///
/// You can use the returned object to query whether an analysis was
/// preserved. See the example in the comment on `PreservedAnalysis`.
template <typename AnalysisT> PreservedAnalysisChecker getChecker() const {
return PreservedAnalysisChecker(*this, AnalysisT::ID());
}
/// Build a checker for this `PreservedAnalyses` and the specified analysis
/// ID.
///
/// You can use the returned object to query whether an analysis was
/// preserved. See the example in the comment on `PreservedAnalysis`.
PreservedAnalysisChecker getChecker(AnalysisKey *ID) const {
return PreservedAnalysisChecker(*this, ID);
}
/// Test whether all analyses are preserved (and none are abandoned).
///
/// This is used primarily to optimize for the common case of a transformation
/// which makes no changes to the IR.
bool areAllPreserved() const {
return NotPreservedAnalysisIDs.empty() &&
PreservedIDs.count(&AllAnalysesKey);
}
/// Directly test whether a set of analyses is preserved.
///
/// This is only true when no analyses have been explicitly abandoned.
template <typename AnalysisSetT> bool allAnalysesInSetPreserved() const {
return allAnalysesInSetPreserved(AnalysisSetT::ID());
}
/// Directly test whether a set of analyses is preserved.
///
/// This is only true when no analyses have been explicitly abandoned.
bool allAnalysesInSetPreserved(AnalysisSetKey *SetID) const {
return NotPreservedAnalysisIDs.empty() &&
(PreservedIDs.count(&AllAnalysesKey) || PreservedIDs.count(SetID));
}
private:
/// A special key used to indicate all analyses.
static AnalysisSetKey AllAnalysesKey;
/// The IDs of analyses and analysis sets that are preserved.
SmallPtrSet<void *, 2> PreservedIDs;
/// The IDs of explicitly not-preserved analyses.
///
/// If an analysis in this set is covered by a set in `PreservedIDs`, we
/// consider it not-preserved. That is, `NotPreservedAnalysisIDs` always
/// "wins" over analysis sets in `PreservedIDs`.
///
/// Also, a given ID should never occur both here and in `PreservedIDs`.
SmallPtrSet<AnalysisKey *, 2> NotPreservedAnalysisIDs;
};
// Forward declare the analysis manager template.
template <typename IRUnitT, typename... ExtraArgTs> class AnalysisManager;
/// A CRTP mix-in to automatically provide informational APIs needed for
/// passes.
///
/// This provides some boilerplate for types that are passes.
template <typename DerivedT> struct PassInfoMixin {
/// Gets the name of the pass we are mixed into.
static StringRef name() {
static_assert(std::is_base_of<PassInfoMixin, DerivedT>::value,
"Must pass the derived type as the template argument!");
StringRef Name = getTypeName<DerivedT>();
Name.consume_front("llvm::");
return Name;
}
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName) {
StringRef ClassName = DerivedT::name();
auto PassName = MapClassName2PassName(ClassName);
OS << PassName;
}
};
/// A CRTP mix-in that provides informational APIs needed for analysis passes.
///
/// This provides some boilerplate for types that are analysis passes. It
/// automatically mixes in \c PassInfoMixin.
template <typename DerivedT>
struct AnalysisInfoMixin : PassInfoMixin<DerivedT> {
/// Returns an opaque, unique ID for this analysis type.
///
/// This ID is a pointer type that is guaranteed to be 8-byte aligned and thus
/// suitable for use in sets, maps, and other data structures that use the low
/// bits of pointers.
///
/// Note that this requires the derived type provide a static \c AnalysisKey
/// member called \c Key.
///
/// FIXME: The only reason the mixin type itself can't declare the Key value
/// is that some compilers cannot correctly unique a templated static variable
/// so it has the same addresses in each instantiation. The only currently
/// known platform with this limitation is Windows DLL builds, specifically
/// building each part of LLVM as a DLL. If we ever remove that build
/// configuration, this mixin can provide the static key as well.
static AnalysisKey *ID() {
static_assert(std::is_base_of<AnalysisInfoMixin, DerivedT>::value,
"Must pass the derived type as the template argument!");
return &DerivedT::Key;
}
};
namespace detail {
/// Actual unpacker of extra arguments in getAnalysisResult,
/// passes only those tuple arguments that are mentioned in index_sequence.
template <typename PassT, typename IRUnitT, typename AnalysisManagerT,
typename... ArgTs, size_t... Ns>
typename PassT::Result
getAnalysisResultUnpackTuple(AnalysisManagerT &AM, IRUnitT &IR,
std::tuple<ArgTs...> Args,
std::index_sequence<Ns...>) {
(void)Args;
return AM.template getResult<PassT>(IR, std::get<Ns>(Args)...);
}
/// Helper for *partial* unpacking of extra arguments in getAnalysisResult.
///
/// Arguments passed in tuple come from PassManager, so they might have extra
/// arguments after those AnalysisManager's ExtraArgTs ones that we need to
/// pass to getResult.
template <typename PassT, typename IRUnitT, typename... AnalysisArgTs,
typename... MainArgTs>
typename PassT::Result
getAnalysisResult(AnalysisManager<IRUnitT, AnalysisArgTs...> &AM, IRUnitT &IR,
std::tuple<MainArgTs...> Args) {
return (getAnalysisResultUnpackTuple<
PassT, IRUnitT>)(AM, IR, Args,
std::index_sequence_for<AnalysisArgTs...>{});
}
} // namespace detail
// Forward declare the pass instrumentation analysis explicitly queried in
// generic PassManager code.
// FIXME: figure out a way to move PassInstrumentationAnalysis into its own
// header.
class PassInstrumentationAnalysis;
/// Manages a sequence of passes over a particular unit of IR.
///
/// A pass manager contains a sequence of passes to run over a particular unit
/// of IR (e.g. Functions, Modules). It is itself a valid pass over that unit of
/// IR, and when run over some given IR will run each of its contained passes in
/// sequence. Pass managers are the primary and most basic building block of a
/// pass pipeline.
///
/// When you run a pass manager, you provide an \c AnalysisManager<IRUnitT>
/// argument. The pass manager will propagate that analysis manager to each
/// pass it runs, and will call the analysis manager's invalidation routine with
/// the PreservedAnalyses of each pass it runs.
template <typename IRUnitT,
typename AnalysisManagerT = AnalysisManager<IRUnitT>,
typename... ExtraArgTs>
class PassManager : public PassInfoMixin<
PassManager<IRUnitT, AnalysisManagerT, ExtraArgTs...>> {
public:
/// Construct a pass manager.
explicit PassManager() = default;
// FIXME: These are equivalent to the default move constructor/move
// assignment. However, using = default triggers linker errors due to the
// explicit instantiations below. Find away to use the default and remove the
// duplicated code here.
PassManager(PassManager &&Arg) : Passes(std::move(Arg.Passes)) {}
PassManager &operator=(PassManager &&RHS) {
Passes = std::move(RHS.Passes);
return *this;
}
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName) {
for (unsigned Idx = 0, Size = Passes.size(); Idx != Size; ++Idx) {
auto *P = Passes[Idx].get();
P->printPipeline(OS, MapClassName2PassName);
if (Idx + 1 < Size)
OS << ",";
}
}
/// Run all of the passes in this manager over the given unit of IR.
/// ExtraArgs are passed to each pass.
PreservedAnalyses run(IRUnitT &IR, AnalysisManagerT &AM,
ExtraArgTs... ExtraArgs) {
PreservedAnalyses PA = PreservedAnalyses::all();
// Request PassInstrumentation from analysis manager, will use it to run
// instrumenting callbacks for the passes later.
// Here we use std::tuple wrapper over getResult which helps to extract
// AnalysisManager's arguments out of the whole ExtraArgs set.
PassInstrumentation PI =
detail::getAnalysisResult<PassInstrumentationAnalysis>(
AM, IR, std::tuple<ExtraArgTs...>(ExtraArgs...));
for (unsigned Idx = 0, Size = Passes.size(); Idx != Size; ++Idx) {
auto *P = Passes[Idx].get();
// Check the PassInstrumentation's BeforePass callbacks before running the
// pass, skip its execution completely if asked to (callback returns
// false).
if (!PI.runBeforePass<IRUnitT>(*P, IR))
continue;
PreservedAnalyses PassPA;
{
TimeTraceScope TimeScope(P->name(), IR.getName());
PassPA = P->run(IR, AM, ExtraArgs...);
}
// Call onto PassInstrumentation's AfterPass callbacks immediately after
// running the pass.
PI.runAfterPass<IRUnitT>(*P, IR, PassPA);
// Update the analysis manager as each pass runs and potentially
// invalidates analyses.
AM.invalidate(IR, PassPA);
// Finally, intersect the preserved analyses to compute the aggregate
// preserved set for this pass manager.
PA.intersect(std::move(PassPA));
}
// Invalidation was handled after each pass in the above loop for the
// current unit of IR. Therefore, the remaining analysis results in the
// AnalysisManager are preserved. We mark this with a set so that we don't
// need to inspect each one individually.
PA.preserveSet<AllAnalysesOn<IRUnitT>>();
return PA;
}
template <typename PassT>
LLVM_ATTRIBUTE_MINSIZE
std::enable_if_t<!std::is_same<PassT, PassManager>::value>
addPass(PassT &&Pass) {
using PassModelT =
detail::PassModel<IRUnitT, PassT, PreservedAnalyses, AnalysisManagerT,
ExtraArgTs...>;
// Do not use make_unique or emplace_back, they cause too many template
// instantiations, causing terrible compile times.
Passes.push_back(std::unique_ptr<PassConceptT>(
new PassModelT(std::forward<PassT>(Pass))));
}
/// When adding a pass manager pass that has the same type as this pass
/// manager, simply move the passes over. This is because we don't have use
/// cases rely on executing nested pass managers. Doing this could reduce
/// implementation complexity and avoid potential invalidation issues that may
/// happen with nested pass managers of the same type.
template <typename PassT>
LLVM_ATTRIBUTE_MINSIZE
std::enable_if_t<std::is_same<PassT, PassManager>::value>
addPass(PassT &&Pass) {
for (auto &P : Pass.Passes)
Passes.push_back(std::move(P));
}
/// Returns if the pass manager contains any passes.
bool isEmpty() const { return Passes.empty(); }
static bool isRequired() { return true; }
protected:
using PassConceptT =
detail::PassConcept<IRUnitT, AnalysisManagerT, ExtraArgTs...>;
std::vector<std::unique_ptr<PassConceptT>> Passes;
};
extern template class PassManager<Module>;
/// Convenience typedef for a pass manager over modules.
using ModulePassManager = PassManager<Module>;
extern template class PassManager<Function>;
/// Convenience typedef for a pass manager over functions.
using FunctionPassManager = PassManager<Function>;
/// Pseudo-analysis pass that exposes the \c PassInstrumentation to pass
/// managers. Goes before AnalysisManager definition to provide its
/// internals (e.g PassInstrumentationAnalysis::ID) for use there if needed.
/// FIXME: figure out a way to move PassInstrumentationAnalysis into its own
/// header.
class PassInstrumentationAnalysis
: public AnalysisInfoMixin<PassInstrumentationAnalysis> {
friend AnalysisInfoMixin<PassInstrumentationAnalysis>;
static AnalysisKey Key;
PassInstrumentationCallbacks *Callbacks;
public:
/// PassInstrumentationCallbacks object is shared, owned by something else,
/// not this analysis.
PassInstrumentationAnalysis(PassInstrumentationCallbacks *Callbacks = nullptr)
: Callbacks(Callbacks) {}
using Result = PassInstrumentation;
template <typename IRUnitT, typename AnalysisManagerT, typename... ExtraArgTs>
Result run(IRUnitT &, AnalysisManagerT &, ExtraArgTs &&...) {
return PassInstrumentation(Callbacks);
}
};
/// A container for analyses that lazily runs them and caches their
/// results.
///
/// This class can manage analyses for any IR unit where the address of the IR
/// unit sufficies as its identity.
template <typename IRUnitT, typename... ExtraArgTs> class AnalysisManager {
public:
class Invalidator;
private:
// Now that we've defined our invalidator, we can define the concept types.
using ResultConceptT =
detail::AnalysisResultConcept<IRUnitT, PreservedAnalyses, Invalidator>;
using PassConceptT =
detail::AnalysisPassConcept<IRUnitT, PreservedAnalyses, Invalidator,
ExtraArgTs...>;
/// List of analysis pass IDs and associated concept pointers.
///
/// Requires iterators to be valid across appending new entries and arbitrary
/// erases. Provides the analysis ID to enable finding iterators to a given
/// entry in maps below, and provides the storage for the actual result
/// concept.
using AnalysisResultListT =
std::list<std::pair<AnalysisKey *, std::unique_ptr<ResultConceptT>>>;
/// Map type from IRUnitT pointer to our custom list type.
using AnalysisResultListMapT = DenseMap<IRUnitT *, AnalysisResultListT>;
/// Map type from a pair of analysis ID and IRUnitT pointer to an
/// iterator into a particular result list (which is where the actual analysis
/// result is stored).
using AnalysisResultMapT =
DenseMap<std::pair<AnalysisKey *, IRUnitT *>,
typename AnalysisResultListT::iterator>;
public:
/// API to communicate dependencies between analyses during invalidation.
///
/// When an analysis result embeds handles to other analysis results, it
/// needs to be invalidated both when its own information isn't preserved and
/// when any of its embedded analysis results end up invalidated. We pass an
/// \c Invalidator object as an argument to \c invalidate() in order to let
/// the analysis results themselves define the dependency graph on the fly.
/// This lets us avoid building an explicit representation of the
/// dependencies between analysis results.
class Invalidator {
public:
/// Trigger the invalidation of some other analysis pass if not already
/// handled and return whether it was in fact invalidated.
///
/// This is expected to be called from within a given analysis result's \c
/// invalidate method to trigger a depth-first walk of all inter-analysis
/// dependencies. The same \p IR unit and \p PA passed to that result's \c
/// invalidate method should in turn be provided to this routine.
///
/// The first time this is called for a given analysis pass, it will call
/// the corresponding result's \c invalidate method. Subsequent calls will
/// use a cache of the results of that initial call. It is an error to form
/// cyclic dependencies between analysis results.
///
/// This returns true if the given analysis's result is invalid. Any
/// dependecies on it will become invalid as a result.
template <typename PassT>
bool invalidate(IRUnitT &IR, const PreservedAnalyses &PA) {
using ResultModelT =
detail::AnalysisResultModel<IRUnitT, PassT, typename PassT::Result,
PreservedAnalyses, Invalidator>;
return invalidateImpl<ResultModelT>(PassT::ID(), IR, PA);
}
/// A type-erased variant of the above invalidate method with the same core
/// API other than passing an analysis ID rather than an analysis type
/// parameter.
///
/// This is sadly less efficient than the above routine, which leverages
/// the type parameter to avoid the type erasure overhead.
bool invalidate(AnalysisKey *ID, IRUnitT &IR, const PreservedAnalyses &PA) {
return invalidateImpl<>(ID, IR, PA);
}
private:
friend class AnalysisManager;
template <typename ResultT = ResultConceptT>
bool invalidateImpl(AnalysisKey *ID, IRUnitT &IR,
const PreservedAnalyses &PA) {
// If we've already visited this pass, return true if it was invalidated
// and false otherwise.
auto IMapI = IsResultInvalidated.find(ID);
if (IMapI != IsResultInvalidated.end())
return IMapI->second;
// Otherwise look up the result object.
auto RI = Results.find({ID, &IR});
assert(RI != Results.end() &&
"Trying to invalidate a dependent result that isn't in the "
"manager's cache is always an error, likely due to a stale result "
"handle!");
auto &Result = static_cast<ResultT &>(*RI->second->second);
// Insert into the map whether the result should be invalidated and return
// that. Note that we cannot reuse IMapI and must do a fresh insert here,
// as calling invalidate could (recursively) insert things into the map,
// making any iterator or reference invalid.
bool Inserted;
std::tie(IMapI, Inserted) =
IsResultInvalidated.insert({ID, Result.invalidate(IR, PA, *this)});
(void)Inserted;
assert(Inserted && "Should not have already inserted this ID, likely "
"indicates a dependency cycle!");
return IMapI->second;
}
Invalidator(SmallDenseMap<AnalysisKey *, bool, 8> &IsResultInvalidated,
const AnalysisResultMapT &Results)
: IsResultInvalidated(IsResultInvalidated), Results(Results) {}
SmallDenseMap<AnalysisKey *, bool, 8> &IsResultInvalidated;
const AnalysisResultMapT &Results;
};
/// Construct an empty analysis manager.
AnalysisManager();
AnalysisManager(AnalysisManager &&);
AnalysisManager &operator=(AnalysisManager &&);
/// Returns true if the analysis manager has an empty results cache.
bool empty() const {
assert(AnalysisResults.empty() == AnalysisResultLists.empty() &&
"The storage and index of analysis results disagree on how many "
"there are!");
return AnalysisResults.empty();
}
/// Clear any cached analysis results for a single unit of IR.
///
/// This doesn't invalidate, but instead simply deletes, the relevant results.
/// It is useful when the IR is being removed and we want to clear out all the
/// memory pinned for it.
void clear(IRUnitT &IR, llvm::StringRef Name);
/// Clear all analysis results cached by this AnalysisManager.
///
/// Like \c clear(IRUnitT&), this doesn't invalidate the results; it simply
/// deletes them. This lets you clean up the AnalysisManager when the set of
/// IR units itself has potentially changed, and thus we can't even look up a
/// a result and invalidate/clear it directly.
void clear() {
AnalysisResults.clear();
AnalysisResultLists.clear();
}
/// Get the result of an analysis pass for a given IR unit.
///
/// Runs the analysis if a cached result is not available.
template <typename PassT>
typename PassT::Result &getResult(IRUnitT &IR, ExtraArgTs... ExtraArgs) {
assert(AnalysisPasses.count(PassT::ID()) &&
"This analysis pass was not registered prior to being queried");
ResultConceptT &ResultConcept =
getResultImpl(PassT::ID(), IR, ExtraArgs...);
using ResultModelT =
detail::AnalysisResultModel<IRUnitT, PassT, typename PassT::Result,
PreservedAnalyses, Invalidator>;
return static_cast<ResultModelT &>(ResultConcept).Result;
}
/// Get the cached result of an analysis pass for a given IR unit.
///
/// This method never runs the analysis.
///
/// \returns null if there is no cached result.
template <typename PassT>
typename PassT::Result *getCachedResult(IRUnitT &IR) const {
assert(AnalysisPasses.count(PassT::ID()) &&
"This analysis pass was not registered prior to being queried");
ResultConceptT *ResultConcept = getCachedResultImpl(PassT::ID(), IR);
if (!ResultConcept)
return nullptr;
using ResultModelT =
detail::AnalysisResultModel<IRUnitT, PassT, typename PassT::Result,
PreservedAnalyses, Invalidator>;
return &static_cast<ResultModelT *>(ResultConcept)->Result;
}
/// Verify that the given Result cannot be invalidated, assert otherwise.
template <typename PassT>
void verifyNotInvalidated(IRUnitT &IR, typename PassT::Result *Result) const {
PreservedAnalyses PA = PreservedAnalyses::none();
SmallDenseMap<AnalysisKey *, bool, 8> IsResultInvalidated;
Invalidator Inv(IsResultInvalidated, AnalysisResults);
assert(!Result->invalidate(IR, PA, Inv) &&
"Cached result cannot be invalidated");
}
/// Register an analysis pass with the manager.
///
/// The parameter is a callable whose result is an analysis pass. This allows
/// passing in a lambda to construct the analysis.
///
/// The analysis type to register is the type returned by calling the \c
/// PassBuilder argument. If that type has already been registered, then the
/// argument will not be called and this function will return false.
/// Otherwise, we register the analysis returned by calling \c PassBuilder(),
/// and this function returns true.
///
/// (Note: Although the return value of this function indicates whether or not
/// an analysis was previously registered, there intentionally isn't a way to
/// query this directly. Instead, you should just register all the analyses
/// you might want and let this class run them lazily. This idiom lets us
/// minimize the number of times we have to look up analyses in our
/// hashtable.)
template <typename PassBuilderT>
bool registerPass(PassBuilderT &&PassBuilder) {
using PassT = decltype(PassBuilder());
using PassModelT =
detail::AnalysisPassModel<IRUnitT, PassT, PreservedAnalyses,
Invalidator, ExtraArgTs...>;
auto &PassPtr = AnalysisPasses[PassT::ID()];
if (PassPtr)
// Already registered this pass type!
return false;
// Construct a new model around the instance returned by the builder.
PassPtr.reset(new PassModelT(PassBuilder()));
return true;
}
/// Invalidate cached analyses for an IR unit.
///
/// Walk through all of the analyses pertaining to this unit of IR and
/// invalidate them, unless they are preserved by the PreservedAnalyses set.
void invalidate(IRUnitT &IR, const PreservedAnalyses &PA);
private:
/// Look up a registered analysis pass.
PassConceptT &lookUpPass(AnalysisKey *ID) {
typename AnalysisPassMapT::iterator PI = AnalysisPasses.find(ID);
assert(PI != AnalysisPasses.end() &&
"Analysis passes must be registered prior to being queried!");
return *PI->second;
}
/// Look up a registered analysis pass.
const PassConceptT &lookUpPass(AnalysisKey *ID) const {
typename AnalysisPassMapT::const_iterator PI = AnalysisPasses.find(ID);
assert(PI != AnalysisPasses.end() &&
"Analysis passes must be registered prior to being queried!");
return *PI->second;
}
/// Get an analysis result, running the pass if necessary.
ResultConceptT &getResultImpl(AnalysisKey *ID, IRUnitT &IR,
ExtraArgTs... ExtraArgs);
/// Get a cached analysis result or return null.
ResultConceptT *getCachedResultImpl(AnalysisKey *ID, IRUnitT &IR) const {
typename AnalysisResultMapT::const_iterator RI =
AnalysisResults.find({ID, &IR});
return RI == AnalysisResults.end() ? nullptr : &*RI->second->second;
}
/// Map type from analysis pass ID to pass concept pointer.
using AnalysisPassMapT =
DenseMap<AnalysisKey *, std::unique_ptr<PassConceptT>>;
/// Collection of analysis passes, indexed by ID.
AnalysisPassMapT AnalysisPasses;
/// Map from IR unit to a list of analysis results.
///
/// Provides linear time removal of all analysis results for a IR unit and
/// the ultimate storage for a particular cached analysis result.
AnalysisResultListMapT AnalysisResultLists;
/// Map from an analysis ID and IR unit to a particular cached
/// analysis result.
AnalysisResultMapT AnalysisResults;
};
extern template class AnalysisManager<Module>;
/// Convenience typedef for the Module analysis manager.
using ModuleAnalysisManager = AnalysisManager<Module>;
extern template class AnalysisManager<Function>;
/// Convenience typedef for the Function analysis manager.
using FunctionAnalysisManager = AnalysisManager<Function>;
/// An analysis over an "outer" IR unit that provides access to an
/// analysis manager over an "inner" IR unit. The inner unit must be contained
/// in the outer unit.
///
/// For example, InnerAnalysisManagerProxy<FunctionAnalysisManager, Module> is
/// an analysis over Modules (the "outer" unit) that provides access to a
/// Function analysis manager. The FunctionAnalysisManager is the "inner"
/// manager being proxied, and Functions are the "inner" unit. The inner/outer
/// relationship is valid because each Function is contained in one Module.
///
/// If you're (transitively) within a pass manager for an IR unit U that
/// contains IR unit V, you should never use an analysis manager over V, except
/// via one of these proxies.
///
/// Note that the proxy's result is a move-only RAII object. The validity of
/// the analyses in the inner analysis manager is tied to its lifetime.
template <typename AnalysisManagerT, typename IRUnitT, typename... ExtraArgTs>
class InnerAnalysisManagerProxy
: public AnalysisInfoMixin<
InnerAnalysisManagerProxy<AnalysisManagerT, IRUnitT>> {
public:
class Result {
public:
explicit Result(AnalysisManagerT &InnerAM) : InnerAM(&InnerAM) {}
Result(Result &&Arg) : InnerAM(std::move(Arg.InnerAM)) {
// We have to null out the analysis manager in the moved-from state
// because we are taking ownership of the responsibilty to clear the
// analysis state.
Arg.InnerAM = nullptr;
}
~Result() {
// InnerAM is cleared in a moved from state where there is nothing to do.
if (!InnerAM)
return;
// Clear out the analysis manager if we're being destroyed -- it means we
// didn't even see an invalidate call when we got invalidated.
InnerAM->clear();
}
Result &operator=(Result &&RHS) {
InnerAM = RHS.InnerAM;
// We have to null out the analysis manager in the moved-from state
// because we are taking ownership of the responsibilty to clear the
// analysis state.
RHS.InnerAM = nullptr;
return *this;
}
/// Accessor for the analysis manager.
AnalysisManagerT &getManager() { return *InnerAM; }
/// Handler for invalidation of the outer IR unit, \c IRUnitT.
///
/// If the proxy analysis itself is not preserved, we assume that the set of
/// inner IR objects contained in IRUnit may have changed. In this case,
/// we have to call \c clear() on the inner analysis manager, as it may now
/// have stale pointers to its inner IR objects.
///
/// Regardless of whether the proxy analysis is marked as preserved, all of
/// the analyses in the inner analysis manager are potentially invalidated
/// based on the set of preserved analyses.
bool invalidate(
IRUnitT &IR, const PreservedAnalyses &PA,
typename AnalysisManager<IRUnitT, ExtraArgTs...>::Invalidator &Inv);
private:
AnalysisManagerT *InnerAM;
};
explicit InnerAnalysisManagerProxy(AnalysisManagerT &InnerAM)
: InnerAM(&InnerAM) {}
/// Run the analysis pass and create our proxy result object.
///
/// This doesn't do any interesting work; it is primarily used to insert our
/// proxy result object into the outer analysis cache so that we can proxy
/// invalidation to the inner analysis manager.
Result run(IRUnitT &IR, AnalysisManager<IRUnitT, ExtraArgTs...> &AM,
ExtraArgTs...) {
return Result(*InnerAM);
}
private:
friend AnalysisInfoMixin<
InnerAnalysisManagerProxy<AnalysisManagerT, IRUnitT>>;
static AnalysisKey Key;
AnalysisManagerT *InnerAM;
};
template <typename AnalysisManagerT, typename IRUnitT, typename... ExtraArgTs>
AnalysisKey
InnerAnalysisManagerProxy<AnalysisManagerT, IRUnitT, ExtraArgTs...>::Key;
/// Provide the \c FunctionAnalysisManager to \c Module proxy.
using FunctionAnalysisManagerModuleProxy =
InnerAnalysisManagerProxy<FunctionAnalysisManager, Module>;
/// Specialization of the invalidate method for the \c
/// FunctionAnalysisManagerModuleProxy's result.
template <>
bool FunctionAnalysisManagerModuleProxy::Result::invalidate(
Module &M, const PreservedAnalyses &PA,
ModuleAnalysisManager::Invalidator &Inv);
// Ensure the \c FunctionAnalysisManagerModuleProxy is provided as an extern
// template.
extern template class InnerAnalysisManagerProxy<FunctionAnalysisManager,
Module>;
/// An analysis over an "inner" IR unit that provides access to an
/// analysis manager over a "outer" IR unit. The inner unit must be contained
/// in the outer unit.
///
/// For example OuterAnalysisManagerProxy<ModuleAnalysisManager, Function> is an
/// analysis over Functions (the "inner" unit) which provides access to a Module
/// analysis manager. The ModuleAnalysisManager is the "outer" manager being
/// proxied, and Modules are the "outer" IR unit. The inner/outer relationship
/// is valid because each Function is contained in one Module.
///
/// This proxy only exposes the const interface of the outer analysis manager,
/// to indicate that you cannot cause an outer analysis to run from within an
/// inner pass. Instead, you must rely on the \c getCachedResult API. This is
/// due to keeping potential future concurrency in mind. To give an example,
/// running a module analysis before any function passes may give a different
/// result than running it in a function pass. Both may be valid, but it would
/// produce non-deterministic results. GlobalsAA is a good analysis example,
/// because the cached information has the mod/ref info for all memory for each
/// function at the time the analysis was computed. The information is still
/// valid after a function transformation, but it may be *different* if
/// recomputed after that transform. GlobalsAA is never invalidated.
///
/// This proxy doesn't manage invalidation in any way -- that is handled by the
/// recursive return path of each layer of the pass manager. A consequence of
/// this is the outer analyses may be stale. We invalidate the outer analyses
/// only when we're done running passes over the inner IR units.
template <typename AnalysisManagerT, typename IRUnitT, typename... ExtraArgTs>
class OuterAnalysisManagerProxy
: public AnalysisInfoMixin<
OuterAnalysisManagerProxy<AnalysisManagerT, IRUnitT, ExtraArgTs...>> {
public:
/// Result proxy object for \c OuterAnalysisManagerProxy.
class Result {
public:
explicit Result(const AnalysisManagerT &OuterAM) : OuterAM(&OuterAM) {}
/// Get a cached analysis. If the analysis can be invalidated, this will
/// assert.
template <typename PassT, typename IRUnitTParam>
typename PassT::Result *getCachedResult(IRUnitTParam &IR) const {
typename PassT::Result *Res =
OuterAM->template getCachedResult<PassT>(IR);
if (Res)
OuterAM->template verifyNotInvalidated<PassT>(IR, Res);
return Res;
}
/// Method provided for unit testing, not intended for general use.
template <typename PassT, typename IRUnitTParam>
bool cachedResultExists(IRUnitTParam &IR) const {
typename PassT::Result *Res =
OuterAM->template getCachedResult<PassT>(IR);
return Res != nullptr;
}
/// When invalidation occurs, remove any registered invalidation events.
bool invalidate(
IRUnitT &IRUnit, const PreservedAnalyses &PA,
typename AnalysisManager<IRUnitT, ExtraArgTs...>::Invalidator &Inv) {
// Loop over the set of registered outer invalidation mappings and if any
// of them map to an analysis that is now invalid, clear it out.
SmallVector<AnalysisKey *, 4> DeadKeys;
for (auto &KeyValuePair : OuterAnalysisInvalidationMap) {
AnalysisKey *OuterID = KeyValuePair.first;
auto &InnerIDs = KeyValuePair.second;
llvm::erase_if(InnerIDs, [&](AnalysisKey *InnerID) {
return Inv.invalidate(InnerID, IRUnit, PA);
});
if (InnerIDs.empty())
DeadKeys.push_back(OuterID);
}
for (auto OuterID : DeadKeys)
OuterAnalysisInvalidationMap.erase(OuterID);
// The proxy itself remains valid regardless of anything else.
return false;
}
/// Register a deferred invalidation event for when the outer analysis
/// manager processes its invalidations.
template <typename OuterAnalysisT, typename InvalidatedAnalysisT>
void registerOuterAnalysisInvalidation() {
AnalysisKey *OuterID = OuterAnalysisT::ID();
AnalysisKey *InvalidatedID = InvalidatedAnalysisT::ID();
auto &InvalidatedIDList = OuterAnalysisInvalidationMap[OuterID];
// Note, this is a linear scan. If we end up with large numbers of
// analyses that all trigger invalidation on the same outer analysis,
// this entire system should be changed to some other deterministic
// data structure such as a `SetVector` of a pair of pointers.
if (!llvm::is_contained(InvalidatedIDList, InvalidatedID))
InvalidatedIDList.push_back(InvalidatedID);
}
/// Access the map from outer analyses to deferred invalidation requiring
/// analyses.
const SmallDenseMap<AnalysisKey *, TinyPtrVector<AnalysisKey *>, 2> &
getOuterInvalidations() const {
return OuterAnalysisInvalidationMap;
}
private:
const AnalysisManagerT *OuterAM;
/// A map from an outer analysis ID to the set of this IR-unit's analyses
/// which need to be invalidated.
SmallDenseMap<AnalysisKey *, TinyPtrVector<AnalysisKey *>, 2>
OuterAnalysisInvalidationMap;
};
OuterAnalysisManagerProxy(const AnalysisManagerT &OuterAM)
: OuterAM(&OuterAM) {}
/// Run the analysis pass and create our proxy result object.
/// Nothing to see here, it just forwards the \c OuterAM reference into the
/// result.
Result run(IRUnitT &, AnalysisManager<IRUnitT, ExtraArgTs...> &,
ExtraArgTs...) {
return Result(*OuterAM);
}
private:
friend AnalysisInfoMixin<
OuterAnalysisManagerProxy<AnalysisManagerT, IRUnitT, ExtraArgTs...>>;
static AnalysisKey Key;
const AnalysisManagerT *OuterAM;
};
template <typename AnalysisManagerT, typename IRUnitT, typename... ExtraArgTs>
AnalysisKey
OuterAnalysisManagerProxy<AnalysisManagerT, IRUnitT, ExtraArgTs...>::Key;
extern template class OuterAnalysisManagerProxy<ModuleAnalysisManager,
Function>;
/// Provide the \c ModuleAnalysisManager to \c Function proxy.
using ModuleAnalysisManagerFunctionProxy =
OuterAnalysisManagerProxy<ModuleAnalysisManager, Function>;
/// Trivial adaptor that maps from a module to its functions.
///
/// Designed to allow composition of a FunctionPass(Manager) and
/// a ModulePassManager, by running the FunctionPass(Manager) over every
/// function in the module.
///
/// Function passes run within this adaptor can rely on having exclusive access
/// to the function they are run over. They should not read or modify any other
/// functions! Other threads or systems may be manipulating other functions in
/// the module, and so their state should never be relied on.
/// FIXME: Make the above true for all of LLVM's actual passes, some still
/// violate this principle.
///
/// Function passes can also read the module containing the function, but they
/// should not modify that module outside of the use lists of various globals.
/// For example, a function pass is not permitted to add functions to the
/// module.
/// FIXME: Make the above true for all of LLVM's actual passes, some still
/// violate this principle.
///
/// Note that although function passes can access module analyses, module
/// analyses are not invalidated while the function passes are running, so they
/// may be stale. Function analyses will not be stale.
class ModuleToFunctionPassAdaptor
: public PassInfoMixin<ModuleToFunctionPassAdaptor> {
public:
using PassConceptT = detail::PassConcept<Function, FunctionAnalysisManager>;
explicit ModuleToFunctionPassAdaptor(std::unique_ptr<PassConceptT> Pass,
bool EagerlyInvalidate)
: Pass(std::move(Pass)), EagerlyInvalidate(EagerlyInvalidate) {}
/// Runs the function pass across every function in the module.
PreservedAnalyses run(Module &M, ModuleAnalysisManager &AM);
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName);
static bool isRequired() { return true; }
private:
std::unique_ptr<PassConceptT> Pass;
bool EagerlyInvalidate;
};
/// A function to deduce a function pass type and wrap it in the
/// templated adaptor.
template <typename FunctionPassT>
ModuleToFunctionPassAdaptor
createModuleToFunctionPassAdaptor(FunctionPassT &&Pass,
bool EagerlyInvalidate = false) {
using PassModelT =
detail::PassModel<Function, FunctionPassT, PreservedAnalyses,
FunctionAnalysisManager>;
// Do not use make_unique, it causes too many template instantiations,
// causing terrible compile times.
return ModuleToFunctionPassAdaptor(
std::unique_ptr<ModuleToFunctionPassAdaptor::PassConceptT>(
new PassModelT(std::forward<FunctionPassT>(Pass))),
EagerlyInvalidate);
}
/// A utility pass template to force an analysis result to be available.
///
/// If there are extra arguments at the pass's run level there may also be
/// extra arguments to the analysis manager's \c getResult routine. We can't
/// guess how to effectively map the arguments from one to the other, and so
/// this specialization just ignores them.
///
/// Specific patterns of run-method extra arguments and analysis manager extra
/// arguments will have to be defined as appropriate specializations.
template <typename AnalysisT, typename IRUnitT,
typename AnalysisManagerT = AnalysisManager<IRUnitT>,
typename... ExtraArgTs>
struct RequireAnalysisPass
: PassInfoMixin<RequireAnalysisPass<AnalysisT, IRUnitT, AnalysisManagerT,
ExtraArgTs...>> {
/// Run this pass over some unit of IR.
///
/// This pass can be run over any unit of IR and use any analysis manager
/// provided they satisfy the basic API requirements. When this pass is
/// created, these methods can be instantiated to satisfy whatever the
/// context requires.
PreservedAnalyses run(IRUnitT &Arg, AnalysisManagerT &AM,
ExtraArgTs &&... Args) {
(void)AM.template getResult<AnalysisT>(Arg,
std::forward<ExtraArgTs>(Args)...);
return PreservedAnalyses::all();
}
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName) {
auto ClassName = AnalysisT::name();
auto PassName = MapClassName2PassName(ClassName);
OS << "require<" << PassName << ">";
}
static bool isRequired() { return true; }
};
/// A no-op pass template which simply forces a specific analysis result
/// to be invalidated.
template <typename AnalysisT>
struct InvalidateAnalysisPass
: PassInfoMixin<InvalidateAnalysisPass<AnalysisT>> {
/// Run this pass over some unit of IR.
///
/// This pass can be run over any unit of IR and use any analysis manager,
/// provided they satisfy the basic API requirements. When this pass is
/// created, these methods can be instantiated to satisfy whatever the
/// context requires.
template <typename IRUnitT, typename AnalysisManagerT, typename... ExtraArgTs>
PreservedAnalyses run(IRUnitT &Arg, AnalysisManagerT &AM, ExtraArgTs &&...) {
auto PA = PreservedAnalyses::all();
PA.abandon<AnalysisT>();
return PA;
}
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName) {
auto ClassName = AnalysisT::name();
auto PassName = MapClassName2PassName(ClassName);
OS << "invalidate<" << PassName << ">";
}
};
/// A utility pass that does nothing, but preserves no analyses.
///
/// Because this preserves no analyses, any analysis passes queried after this
/// pass runs will recompute fresh results.
struct InvalidateAllAnalysesPass : PassInfoMixin<InvalidateAllAnalysesPass> {
/// Run this pass over some unit of IR.
template <typename IRUnitT, typename AnalysisManagerT, typename... ExtraArgTs>
PreservedAnalyses run(IRUnitT &, AnalysisManagerT &, ExtraArgTs &&...) {
return PreservedAnalyses::none();
}
};
/// A utility pass template that simply runs another pass multiple times.
///
/// This can be useful when debugging or testing passes. It also serves as an
/// example of how to extend the pass manager in ways beyond composition.
template <typename PassT>
class RepeatedPass : public PassInfoMixin<RepeatedPass<PassT>> {
public:
RepeatedPass(int Count, PassT &&P)
: Count(Count), P(std::forward<PassT>(P)) {}
template <typename IRUnitT, typename AnalysisManagerT, typename... Ts>
PreservedAnalyses run(IRUnitT &IR, AnalysisManagerT &AM, Ts &&... Args) {
// Request PassInstrumentation from analysis manager, will use it to run
// instrumenting callbacks for the passes later.
// Here we use std::tuple wrapper over getResult which helps to extract
// AnalysisManager's arguments out of the whole Args set.
PassInstrumentation PI =
detail::getAnalysisResult<PassInstrumentationAnalysis>(
AM, IR, std::tuple<Ts...>(Args...));
auto PA = PreservedAnalyses::all();
for (int i = 0; i < Count; ++i) {
// Check the PassInstrumentation's BeforePass callbacks before running the
// pass, skip its execution completely if asked to (callback returns
// false).
if (!PI.runBeforePass<IRUnitT>(P, IR))
continue;
PreservedAnalyses IterPA = P.run(IR, AM, std::forward<Ts>(Args)...);
PA.intersect(IterPA);
PI.runAfterPass(P, IR, IterPA);
}
return PA;
}
void printPipeline(raw_ostream &OS,
function_ref<StringRef(StringRef)> MapClassName2PassName) {
OS << "repeat<" << Count << ">(";
P.printPipeline(OS, MapClassName2PassName);
OS << ")";
}
private:
int Count;
PassT P;
};
template <typename PassT>
RepeatedPass<PassT> createRepeatedPass(int Count, PassT &&P) {
return RepeatedPass<PassT>(Count, std::forward<PassT>(P));
}
} // end namespace llvm
#endif // LLVM_IR_PASSMANAGER_H