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llvm-mirror/include/llvm/Analysis/LazyCallGraph.h
Chandler Carruth 042041bdf3 [PM/LCG] Teach the LazyCallGraph how to replace a function without
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
2017-02-09 23:24:13 +00:00

1246 lines
47 KiB
C++

//===- LazyCallGraph.h - Analysis of a Module's call graph ------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
/// \file
///
/// Implements a lazy call graph analysis and related passes for the new pass
/// manager.
///
/// NB: This is *not* a traditional call graph! It is a graph which models both
/// the current calls and potential calls. As a consequence there are many
/// edges in this call graph that do not correspond to a 'call' or 'invoke'
/// instruction.
///
/// The primary use cases of this graph analysis is to facilitate iterating
/// across the functions of a module in ways that ensure all callees are
/// visited prior to a caller (given any SCC constraints), or vice versa. As
/// such is it particularly well suited to organizing CGSCC optimizations such
/// as inlining, outlining, argument promotion, etc. That is its primary use
/// case and motivates the design. It may not be appropriate for other
/// purposes. The use graph of functions or some other conservative analysis of
/// call instructions may be interesting for optimizations and subsequent
/// analyses which don't work in the context of an overly specified
/// potential-call-edge graph.
///
/// To understand the specific rules and nature of this call graph analysis,
/// see the documentation of the \c LazyCallGraph below.
///
//===----------------------------------------------------------------------===//
#ifndef LLVM_ANALYSIS_LAZYCALLGRAPH_H
#define LLVM_ANALYSIS_LAZYCALLGRAPH_H
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/PointerUnion.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/iterator.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/Module.h"
#include "llvm/IR/PassManager.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/raw_ostream.h"
#include <iterator>
#include <utility>
namespace llvm {
class PreservedAnalyses;
class raw_ostream;
/// A lazily constructed view of the call graph of a module.
///
/// With the edges of this graph, the motivating constraint that we are
/// attempting to maintain is that function-local optimization, CGSCC-local
/// optimizations, and optimizations transforming a pair of functions connected
/// by an edge in the graph, do not invalidate a bottom-up traversal of the SCC
/// DAG. That is, no optimizations will delete, remove, or add an edge such
/// that functions already visited in a bottom-up order of the SCC DAG are no
/// longer valid to have visited, or such that functions not yet visited in
/// a bottom-up order of the SCC DAG are not required to have already been
/// visited.
///
/// Within this constraint, the desire is to minimize the merge points of the
/// SCC DAG. The greater the fanout of the SCC DAG and the fewer merge points
/// in the SCC DAG, the more independence there is in optimizing within it.
/// There is a strong desire to enable parallelization of optimizations over
/// the call graph, and both limited fanout and merge points will (artificially
/// in some cases) limit the scaling of such an effort.
///
/// To this end, graph represents both direct and any potential resolution to
/// an indirect call edge. Another way to think about it is that it represents
/// both the direct call edges and any direct call edges that might be formed
/// through static optimizations. Specifically, it considers taking the address
/// of a function to be an edge in the call graph because this might be
/// forwarded to become a direct call by some subsequent function-local
/// optimization. The result is that the graph closely follows the use-def
/// edges for functions. Walking "up" the graph can be done by looking at all
/// of the uses of a function.
///
/// The roots of the call graph are the external functions and functions
/// escaped into global variables. Those functions can be called from outside
/// of the module or via unknowable means in the IR -- we may not be able to
/// form even a potential call edge from a function body which may dynamically
/// load the function and call it.
///
/// This analysis still requires updates to remain valid after optimizations
/// which could potentially change the set of potential callees. The
/// constraints it operates under only make the traversal order remain valid.
///
/// The entire analysis must be re-computed if full interprocedural
/// optimizations run at any point. For example, globalopt completely
/// invalidates the information in this analysis.
///
/// FIXME: This class is named LazyCallGraph in a lame attempt to distinguish
/// it from the existing CallGraph. At some point, it is expected that this
/// will be the only call graph and it will be renamed accordingly.
class LazyCallGraph {
public:
class Node;
class EdgeSequence;
class SCC;
class RefSCC;
class edge_iterator;
class call_edge_iterator;
/// A class used to represent edges in the call graph.
///
/// The lazy call graph models both *call* edges and *reference* edges. Call
/// edges are much what you would expect, and exist when there is a 'call' or
/// 'invoke' instruction of some function. Reference edges are also tracked
/// along side these, and exist whenever any instruction (transitively
/// through its operands) references a function. All call edges are
/// inherently reference edges, and so the reference graph forms a superset
/// of the formal call graph.
///
/// All of these forms of edges are fundamentally represented as outgoing
/// edges. The edges are stored in the source node and point at the target
/// node. This allows the edge structure itself to be a very compact data
/// structure: essentially a tagged pointer.
class Edge {
public:
/// The kind of edge in the graph.
enum Kind : bool { Ref = false, Call = true };
Edge();
explicit Edge(Node &N, Kind K);
/// Test whether the edge is null.
///
/// This happens when an edge has been deleted. We leave the edge objects
/// around but clear them.
explicit operator bool() const;
/// Returnss the \c Kind of the edge.
Kind getKind() const;
/// Test whether the edge represents a direct call to a function.
///
/// This requires that the edge is not null.
bool isCall() const;
/// Get the call graph node referenced by this edge.
///
/// This requires that the edge is not null.
Node &getNode() const;
/// Get the function referenced by this edge.
///
/// This requires that the edge is not null.
Function &getFunction() const;
private:
friend class LazyCallGraph::EdgeSequence;
friend class LazyCallGraph::RefSCC;
PointerIntPair<Node *, 1, Kind> Value;
void setKind(Kind K) { Value.setInt(K); }
};
/// The edge sequence object.
///
/// This typically exists entirely within the node but is exposed as
/// a separate type because a node doesn't initially have edges. An explicit
/// population step is required to produce this sequence at first and it is
/// then cached in the node. It is also used to represent edges entering the
/// graph from outside the module to model the graph's roots.
///
/// The sequence itself both iterable and indexable. The indexes remain
/// stable even as the sequence mutates (including removal).
class EdgeSequence {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
friend class LazyCallGraph::RefSCC;
typedef SmallVector<Edge, 4> VectorT;
typedef SmallVectorImpl<Edge> VectorImplT;
public:
/// An iterator used for the edges to both entry nodes and child nodes.
class iterator
: public iterator_adaptor_base<iterator, VectorImplT::iterator,
std::forward_iterator_tag> {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
VectorImplT::iterator E;
// Build the iterator for a specific position in the edge list.
iterator(VectorImplT::iterator BaseI, VectorImplT::iterator E)
: iterator_adaptor_base(BaseI), E(E) {
while (I != E && !*I)
++I;
}
public:
iterator() {}
using iterator_adaptor_base::operator++;
iterator &operator++() {
do {
++I;
} while (I != E && !*I);
return *this;
}
};
/// An iterator over specifically call edges.
///
/// This has the same iteration properties as the \c iterator, but
/// restricts itself to edges which represent actual calls.
class call_iterator
: public iterator_adaptor_base<call_iterator, VectorImplT::iterator,
std::forward_iterator_tag> {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
VectorImplT::iterator E;
/// Advance the iterator to the next valid, call edge.
void advanceToNextEdge() {
while (I != E && (!*I || !I->isCall()))
++I;
}
// Build the iterator for a specific position in the edge list.
call_iterator(VectorImplT::iterator BaseI, VectorImplT::iterator E)
: iterator_adaptor_base(BaseI), E(E) {
advanceToNextEdge();
}
public:
call_iterator() {}
using iterator_adaptor_base::operator++;
call_iterator &operator++() {
++I;
advanceToNextEdge();
return *this;
}
};
iterator begin() { return iterator(Edges.begin(), Edges.end()); }
iterator end() { return iterator(Edges.end(), Edges.end()); }
Edge &operator[](int i) { return Edges[i]; }
Edge &operator[](Node &N) {
assert(EdgeIndexMap.find(&N) != EdgeIndexMap.end() && "No such edge!");
return Edges[EdgeIndexMap.find(&N)->second];
}
Edge *lookup(Node &N) {
auto EI = EdgeIndexMap.find(&N);
return EI != EdgeIndexMap.end() ? &Edges[EI->second] : nullptr;
}
call_iterator call_begin() {
return call_iterator(Edges.begin(), Edges.end());
}
call_iterator call_end() { return call_iterator(Edges.end(), Edges.end()); }
iterator_range<call_iterator> calls() {
return make_range(call_begin(), call_end());
}
bool empty() {
for (auto &E : Edges)
if (E)
return false;
return true;
}
private:
VectorT Edges;
DenseMap<Node *, int> EdgeIndexMap;
EdgeSequence() = default;
/// Internal helper to insert an edge to a node.
void insertEdgeInternal(Node &ChildN, Edge::Kind EK);
/// Internal helper to change an edge kind.
void setEdgeKind(Node &ChildN, Edge::Kind EK);
/// Internal helper to remove the edge to the given function.
bool removeEdgeInternal(Node &ChildN);
/// Internal helper to replace an edge key with a new one.
///
/// This should be used when the function for a particular node in the
/// graph gets replaced and we are updating all of the edges to that node
/// to use the new function as the key.
void replaceEdgeKey(Function &OldTarget, Function &NewTarget);
};
/// A node in the call graph.
///
/// This represents a single node. It's primary roles are to cache the list of
/// callees, de-duplicate and provide fast testing of whether a function is
/// a callee, and facilitate iteration of child nodes in the graph.
///
/// The node works much like an optional in order to lazily populate the
/// edges of each node. Until populated, there are no edges. Once populated,
/// you can access the edges by dereferencing the node or using the `->`
/// operator as if the node was an `Optional<EdgeSequence>`.
class Node {
friend class LazyCallGraph;
friend class LazyCallGraph::RefSCC;
public:
LazyCallGraph &getGraph() const { return *G; }
Function &getFunction() const { return *F; }
StringRef getName() const { return F->getName(); }
/// Equality is defined as address equality.
bool operator==(const Node &N) const { return this == &N; }
bool operator!=(const Node &N) const { return !operator==(N); }
/// Tests whether the node has been populated with edges.
operator bool() const { return Edges.hasValue(); }
// We allow accessing the edges by dereferencing or using the arrow
// operator, essentially wrapping the internal optional.
EdgeSequence &operator*() const {
// Rip const off because the node itself isn't changing here.
return const_cast<EdgeSequence &>(*Edges);
}
EdgeSequence *operator->() const { return &**this; }
/// Populate the edges of this node if necessary.
///
/// The first time this is called it will populate the edges for this node
/// in the graph. It does this by scanning the underlying function, so once
/// this is done, any changes to that function must be explicitly reflected
/// in updates to the graph.
///
/// \returns the populated \c EdgeSequence to simplify walking it.
///
/// This will not update or re-scan anything if called repeatedly. Instead,
/// the edge sequence is cached and returned immediately on subsequent
/// calls.
EdgeSequence &populate() {
if (Edges)
return *Edges;
return populateSlow();
}
private:
LazyCallGraph *G;
Function *F;
// We provide for the DFS numbering and Tarjan walk lowlink numbers to be
// stored directly within the node. These are both '-1' when nodes are part
// of an SCC (or RefSCC), or '0' when not yet reached in a DFS walk.
int DFSNumber;
int LowLink;
Optional<EdgeSequence> Edges;
/// Basic constructor implements the scanning of F into Edges and
/// EdgeIndexMap.
Node(LazyCallGraph &G, Function &F)
: G(&G), F(&F), DFSNumber(0), LowLink(0) {}
/// Implementation of the scan when populating.
EdgeSequence &populateSlow();
/// Internal helper to directly replace the function with a new one.
///
/// This is used to facilitate tranfsormations which need to replace the
/// formal Function object but directly move the body and users from one to
/// the other.
void replaceFunction(Function &NewF);
void clear() { Edges.reset(); }
/// Print the name of this node's function.
friend raw_ostream &operator<<(raw_ostream &OS, const Node &N) {
return OS << N.F->getName();
}
/// Dump the name of this node's function to stderr.
void dump() const;
};
/// An SCC of the call graph.
///
/// This represents a Strongly Connected Component of the direct call graph
/// -- ignoring indirect calls and function references. It stores this as
/// a collection of call graph nodes. While the order of nodes in the SCC is
/// stable, it is not any particular order.
///
/// The SCCs are nested within a \c RefSCC, see below for details about that
/// outer structure. SCCs do not support mutation of the call graph, that
/// must be done through the containing \c RefSCC in order to fully reason
/// about the ordering and connections of the graph.
class SCC {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
RefSCC *OuterRefSCC;
SmallVector<Node *, 1> Nodes;
template <typename NodeRangeT>
SCC(RefSCC &OuterRefSCC, NodeRangeT &&Nodes)
: OuterRefSCC(&OuterRefSCC), Nodes(std::forward<NodeRangeT>(Nodes)) {}
void clear() {
OuterRefSCC = nullptr;
Nodes.clear();
}
/// Print a short descrtiption useful for debugging or logging.
///
/// We print the function names in the SCC wrapped in '()'s and skipping
/// the middle functions if there are a large number.
//
// Note: this is defined inline to dodge issues with GCC's interpretation
// of enclosing namespaces for friend function declarations.
friend raw_ostream &operator<<(raw_ostream &OS, const SCC &C) {
OS << '(';
int i = 0;
for (LazyCallGraph::Node &N : C) {
if (i > 0)
OS << ", ";
// Elide the inner elements if there are too many.
if (i > 8) {
OS << "..., " << *C.Nodes.back();
break;
}
OS << N;
++i;
}
OS << ')';
return OS;
}
/// Dump a short description of this SCC to stderr.
void dump() const;
#ifndef NDEBUG
/// Verify invariants about the SCC.
///
/// This will attempt to validate all of the basic invariants within an
/// SCC, but not that it is a strongly connected componet per-se. Primarily
/// useful while building and updating the graph to check that basic
/// properties are in place rather than having inexplicable crashes later.
void verify();
#endif
public:
typedef pointee_iterator<SmallVectorImpl<Node *>::const_iterator> iterator;
iterator begin() const { return Nodes.begin(); }
iterator end() const { return Nodes.end(); }
int size() const { return Nodes.size(); }
RefSCC &getOuterRefSCC() const { return *OuterRefSCC; }
/// Test if this SCC is a parent of \a C.
///
/// Note that this is linear in the number of edges departing the current
/// SCC.
bool isParentOf(const SCC &C) const;
/// Test if this SCC is an ancestor of \a C.
///
/// Note that in the worst case this is linear in the number of edges
/// departing the current SCC and every SCC in the entire graph reachable
/// from this SCC. Thus this very well may walk every edge in the entire
/// call graph! Do not call this in a tight loop!
bool isAncestorOf(const SCC &C) const;
/// Test if this SCC is a child of \a C.
///
/// See the comments for \c isParentOf for detailed notes about the
/// complexity of this routine.
bool isChildOf(const SCC &C) const { return C.isParentOf(*this); }
/// Test if this SCC is a descendant of \a C.
///
/// See the comments for \c isParentOf for detailed notes about the
/// complexity of this routine.
bool isDescendantOf(const SCC &C) const { return C.isAncestorOf(*this); }
/// Provide a short name by printing this SCC to a std::string.
///
/// This copes with the fact that we don't have a name per-se for an SCC
/// while still making the use of this in debugging and logging useful.
std::string getName() const {
std::string Name;
raw_string_ostream OS(Name);
OS << *this;
OS.flush();
return Name;
}
};
/// A RefSCC of the call graph.
///
/// This models a Strongly Connected Component of function reference edges in
/// the call graph. As opposed to actual SCCs, these can be used to scope
/// subgraphs of the module which are independent from other subgraphs of the
/// module because they do not reference it in any way. This is also the unit
/// where we do mutation of the graph in order to restrict mutations to those
/// which don't violate this independence.
///
/// A RefSCC contains a DAG of actual SCCs. All the nodes within the RefSCC
/// are necessarily within some actual SCC that nests within it. Since
/// a direct call *is* a reference, there will always be at least one RefSCC
/// around any SCC.
class RefSCC {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
LazyCallGraph *G;
SmallPtrSet<RefSCC *, 1> Parents;
/// A postorder list of the inner SCCs.
SmallVector<SCC *, 4> SCCs;
/// A map from SCC to index in the postorder list.
SmallDenseMap<SCC *, int, 4> SCCIndices;
/// Fast-path constructor. RefSCCs should instead be constructed by calling
/// formRefSCCFast on the graph itself.
RefSCC(LazyCallGraph &G);
void clear() {
Parents.clear();
SCCs.clear();
SCCIndices.clear();
}
/// Print a short description useful for debugging or logging.
///
/// We print the SCCs wrapped in '[]'s and skipping the middle SCCs if
/// there are a large number.
//
// Note: this is defined inline to dodge issues with GCC's interpretation
// of enclosing namespaces for friend function declarations.
friend raw_ostream &operator<<(raw_ostream &OS, const RefSCC &RC) {
OS << '[';
int i = 0;
for (LazyCallGraph::SCC &C : RC) {
if (i > 0)
OS << ", ";
// Elide the inner elements if there are too many.
if (i > 4) {
OS << "..., " << *RC.SCCs.back();
break;
}
OS << C;
++i;
}
OS << ']';
return OS;
}
/// Dump a short description of this RefSCC to stderr.
void dump() const;
#ifndef NDEBUG
/// Verify invariants about the RefSCC and all its SCCs.
///
/// This will attempt to validate all of the invariants *within* the
/// RefSCC, but not that it is a strongly connected component of the larger
/// graph. This makes it useful even when partially through an update.
///
/// Invariants checked:
/// - SCCs and their indices match.
/// - The SCCs list is in fact in post-order.
void verify();
#endif
/// Handle any necessary parent set updates after inserting a trivial ref
/// or call edge.
void handleTrivialEdgeInsertion(Node &SourceN, Node &TargetN);
public:
typedef pointee_iterator<SmallVectorImpl<SCC *>::const_iterator> iterator;
typedef iterator_range<iterator> range;
typedef pointee_iterator<SmallPtrSetImpl<RefSCC *>::const_iterator>
parent_iterator;
iterator begin() const { return SCCs.begin(); }
iterator end() const { return SCCs.end(); }
ssize_t size() const { return SCCs.size(); }
SCC &operator[](int Idx) { return *SCCs[Idx]; }
iterator find(SCC &C) const {
return SCCs.begin() + SCCIndices.find(&C)->second;
}
parent_iterator parent_begin() const { return Parents.begin(); }
parent_iterator parent_end() const { return Parents.end(); }
iterator_range<parent_iterator> parents() const {
return make_range(parent_begin(), parent_end());
}
/// Test if this RefSCC is a parent of \a C.
bool isParentOf(const RefSCC &C) const { return C.isChildOf(*this); }
/// Test if this RefSCC is an ancestor of \a C.
bool isAncestorOf(const RefSCC &C) const { return C.isDescendantOf(*this); }
/// Test if this RefSCC is a child of \a C.
bool isChildOf(const RefSCC &C) const {
return Parents.count(const_cast<RefSCC *>(&C));
}
/// Test if this RefSCC is a descendant of \a C.
bool isDescendantOf(const RefSCC &C) const;
/// Provide a short name by printing this RefSCC to a std::string.
///
/// This copes with the fact that we don't have a name per-se for an RefSCC
/// while still making the use of this in debugging and logging useful.
std::string getName() const {
std::string Name;
raw_string_ostream OS(Name);
OS << *this;
OS.flush();
return Name;
}
///@{
/// \name Mutation API
///
/// These methods provide the core API for updating the call graph in the
/// presence of (potentially still in-flight) DFS-found RefSCCs and SCCs.
///
/// Note that these methods sometimes have complex runtimes, so be careful
/// how you call them.
/// Make an existing internal ref edge into a call edge.
///
/// This may form a larger cycle and thus collapse SCCs into TargetN's SCC.
/// If that happens, the deleted SCC pointers are returned. These SCCs are
/// not in a valid state any longer but the pointers will remain valid
/// until destruction of the parent graph instance for the purpose of
/// clearing cached information.
///
/// After this operation, both SourceN's SCC and TargetN's SCC may move
/// position within this RefSCC's postorder list. Any SCCs merged are
/// merged into the TargetN's SCC in order to preserve reachability analyses
/// which took place on that SCC.
SmallVector<SCC *, 1> switchInternalEdgeToCall(Node &SourceN,
Node &TargetN);
/// Make an existing internal call edge between separate SCCs into a ref
/// edge.
///
/// If SourceN and TargetN in separate SCCs within this RefSCC, changing
/// the call edge between them to a ref edge is a trivial operation that
/// does not require any structural changes to the call graph.
void switchTrivialInternalEdgeToRef(Node &SourceN, Node &TargetN);
/// Make an existing internal call edge within a single SCC into a ref
/// edge.
///
/// Since SourceN and TargetN are part of a single SCC, this SCC may be
/// split up due to breaking a cycle in the call edges that formed it. If
/// that happens, then this routine will insert new SCCs into the postorder
/// list *before* the SCC of TargetN (previously the SCC of both). This
/// preserves postorder as the TargetN can reach all of the other nodes by
/// definition of previously being in a single SCC formed by the cycle from
/// SourceN to TargetN.
///
/// The newly added SCCs are added *immediately* and contiguously
/// prior to the TargetN SCC and return the range covering the new SCCs in
/// the RefSCC's postorder sequence. You can directly iterate the returned
/// range to observe all of the new SCCs in postorder.
///
/// Note that if SourceN and TargetN are in separate SCCs, the simpler
/// routine `switchTrivialInternalEdgeToRef` should be used instead.
iterator_range<iterator> switchInternalEdgeToRef(Node &SourceN,
Node &TargetN);
/// Make an existing outgoing ref edge into a call edge.
///
/// Note that this is trivial as there are no cyclic impacts and there
/// remains a reference edge.
void switchOutgoingEdgeToCall(Node &SourceN, Node &TargetN);
/// Make an existing outgoing call edge into a ref edge.
///
/// This is trivial as there are no cyclic impacts and there remains
/// a reference edge.
void switchOutgoingEdgeToRef(Node &SourceN, Node &TargetN);
/// Insert a ref edge from one node in this RefSCC to another in this
/// RefSCC.
///
/// This is always a trivial operation as it doesn't change any part of the
/// graph structure besides connecting the two nodes.
///
/// Note that we don't support directly inserting internal *call* edges
/// because that could change the graph structure and requires returning
/// information about what became invalid. As a consequence, the pattern
/// should be to first insert the necessary ref edge, and then to switch it
/// to a call edge if needed and handle any invalidation that results. See
/// the \c switchInternalEdgeToCall routine for details.
void insertInternalRefEdge(Node &SourceN, Node &TargetN);
/// Insert an edge whose parent is in this RefSCC and child is in some
/// child RefSCC.
///
/// There must be an existing path from the \p SourceN to the \p TargetN.
/// This operation is inexpensive and does not change the set of SCCs and
/// RefSCCs in the graph.
void insertOutgoingEdge(Node &SourceN, Node &TargetN, Edge::Kind EK);
/// Insert an edge whose source is in a descendant RefSCC and target is in
/// this RefSCC.
///
/// There must be an existing path from the target to the source in this
/// case.
///
/// NB! This is has the potential to be a very expensive function. It
/// inherently forms a cycle in the prior RefSCC DAG and we have to merge
/// RefSCCs to resolve that cycle. But finding all of the RefSCCs which
/// participate in the cycle can in the worst case require traversing every
/// RefSCC in the graph. Every attempt is made to avoid that, but passes
/// must still exercise caution calling this routine repeatedly.
///
/// Also note that this can only insert ref edges. In order to insert
/// a call edge, first insert a ref edge and then switch it to a call edge.
/// These are intentionally kept as separate interfaces because each step
/// of the operation invalidates a different set of data structures.
///
/// This returns all the RefSCCs which were merged into the this RefSCC
/// (the target's). This allows callers to invalidate any cached
/// information.
///
/// FIXME: We could possibly optimize this quite a bit for cases where the
/// caller and callee are very nearby in the graph. See comments in the
/// implementation for details, but that use case might impact users.
SmallVector<RefSCC *, 1> insertIncomingRefEdge(Node &SourceN,
Node &TargetN);
/// Remove an edge whose source is in this RefSCC and target is *not*.
///
/// This removes an inter-RefSCC edge. All inter-RefSCC edges originating
/// from this SCC have been fully explored by any in-flight DFS graph
/// formation, so this is always safe to call once you have the source
/// RefSCC.
///
/// This operation does not change the cyclic structure of the graph and so
/// is very inexpensive. It may change the connectivity graph of the SCCs
/// though, so be careful calling this while iterating over them.
void removeOutgoingEdge(Node &SourceN, Node &TargetN);
/// Remove a ref edge which is entirely within this RefSCC.
///
/// Both the \a SourceN and the \a TargetN must be within this RefSCC.
/// Removing such an edge may break cycles that form this RefSCC and thus
/// this operation may change the RefSCC graph significantly. In
/// particular, this operation will re-form new RefSCCs based on the
/// remaining connectivity of the graph. The following invariants are
/// guaranteed to hold after calling this method:
///
/// 1) This RefSCC is still a RefSCC in the graph.
/// 2) This RefSCC will be the parent of any new RefSCCs. Thus, this RefSCC
/// is preserved as the root of any new RefSCC DAG formed.
/// 3) No RefSCC other than this RefSCC has its member set changed (this is
/// inherent in the definition of removing such an edge).
/// 4) All of the parent links of the RefSCC graph will be updated to
/// reflect the new RefSCC structure.
/// 5) All RefSCCs formed out of this RefSCC, excluding this RefSCC, will
/// be returned in post-order.
/// 6) The order of the RefSCCs in the vector will be a valid postorder
/// traversal of the new RefSCCs.
///
/// These invariants are very important to ensure that we can build
/// optimization pipelines on top of the CGSCC pass manager which
/// intelligently update the RefSCC graph without invalidating other parts
/// of the RefSCC graph.
///
/// Note that we provide no routine to remove a *call* edge. Instead, you
/// must first switch it to a ref edge using \c switchInternalEdgeToRef.
/// This split API is intentional as each of these two steps can invalidate
/// a different aspect of the graph structure and needs to have the
/// invalidation handled independently.
///
/// The runtime complexity of this method is, in the worst case, O(V+E)
/// where V is the number of nodes in this RefSCC and E is the number of
/// edges leaving the nodes in this RefSCC. Note that E includes both edges
/// within this RefSCC and edges from this RefSCC to child RefSCCs. Some
/// effort has been made to minimize the overhead of common cases such as
/// self-edges and edge removals which result in a spanning tree with no
/// more cycles. There are also detailed comments within the implementation
/// on techniques which could substantially improve this routine's
/// efficiency.
SmallVector<RefSCC *, 1> removeInternalRefEdge(Node &SourceN,
Node &TargetN);
/// A convenience wrapper around the above to handle trivial cases of
/// inserting a new call edge.
///
/// This is trivial whenever the target is in the same SCC as the source or
/// the edge is an outgoing edge to some descendant SCC. In these cases
/// there is no change to the cyclic structure of SCCs or RefSCCs.
///
/// To further make calling this convenient, it also handles inserting
/// already existing edges.
void insertTrivialCallEdge(Node &SourceN, Node &TargetN);
/// A convenience wrapper around the above to handle trivial cases of
/// inserting a new ref edge.
///
/// This is trivial whenever the target is in the same RefSCC as the source
/// or the edge is an outgoing edge to some descendant RefSCC. In these
/// cases there is no change to the cyclic structure of the RefSCCs.
///
/// To further make calling this convenient, it also handles inserting
/// already existing edges.
void insertTrivialRefEdge(Node &SourceN, Node &TargetN);
/// Directly replace a node's function with a new function.
///
/// This should be used when moving the body and users of a function to
/// a new formal function object but not otherwise changing the call graph
/// structure in any way.
///
/// It requires that the old function in the provided node have zero uses
/// and the new function must have calls and references to it establishing
/// an equivalent graph.
void replaceNodeFunction(Node &N, Function &NewF);
///@}
};
/// A post-order depth-first RefSCC iterator over the call graph.
///
/// This iterator walks the cached post-order sequence of RefSCCs. However,
/// it trades stability for flexibility. It is restricted to a forward
/// iterator but will survive mutations which insert new RefSCCs and continue
/// to point to the same RefSCC even if it moves in the post-order sequence.
class postorder_ref_scc_iterator
: public iterator_facade_base<postorder_ref_scc_iterator,
std::forward_iterator_tag, RefSCC> {
friend class LazyCallGraph;
friend class LazyCallGraph::Node;
/// Nonce type to select the constructor for the end iterator.
struct IsAtEndT {};
LazyCallGraph *G;
RefSCC *RC;
/// Build the begin iterator for a node.
postorder_ref_scc_iterator(LazyCallGraph &G) : G(&G), RC(getRC(G, 0)) {}
/// Build the end iterator for a node. This is selected purely by overload.
postorder_ref_scc_iterator(LazyCallGraph &G, IsAtEndT /*Nonce*/)
: G(&G), RC(nullptr) {}
/// Get the post-order RefSCC at the given index of the postorder walk,
/// populating it if necessary.
static RefSCC *getRC(LazyCallGraph &G, int Index) {
if (Index == (int)G.PostOrderRefSCCs.size())
// We're at the end.
return nullptr;
return G.PostOrderRefSCCs[Index];
}
public:
bool operator==(const postorder_ref_scc_iterator &Arg) const {
return G == Arg.G && RC == Arg.RC;
}
reference operator*() const { return *RC; }
using iterator_facade_base::operator++;
postorder_ref_scc_iterator &operator++() {
assert(RC && "Cannot increment the end iterator!");
RC = getRC(*G, G->RefSCCIndices.find(RC)->second + 1);
return *this;
}
};
/// Construct a graph for the given module.
///
/// This sets up the graph and computes all of the entry points of the graph.
/// No function definitions are scanned until their nodes in the graph are
/// requested during traversal.
LazyCallGraph(Module &M);
LazyCallGraph(LazyCallGraph &&G);
LazyCallGraph &operator=(LazyCallGraph &&RHS);
EdgeSequence::iterator begin() { return EntryEdges.begin(); }
EdgeSequence::iterator end() { return EntryEdges.end(); }
void buildRefSCCs();
postorder_ref_scc_iterator postorder_ref_scc_begin() {
if (!EntryEdges.empty())
assert(!PostOrderRefSCCs.empty() &&
"Must form RefSCCs before iterating them!");
return postorder_ref_scc_iterator(*this);
}
postorder_ref_scc_iterator postorder_ref_scc_end() {
if (!EntryEdges.empty())
assert(!PostOrderRefSCCs.empty() &&
"Must form RefSCCs before iterating them!");
return postorder_ref_scc_iterator(*this,
postorder_ref_scc_iterator::IsAtEndT());
}
iterator_range<postorder_ref_scc_iterator> postorder_ref_sccs() {
return make_range(postorder_ref_scc_begin(), postorder_ref_scc_end());
}
/// Lookup a function in the graph which has already been scanned and added.
Node *lookup(const Function &F) const { return NodeMap.lookup(&F); }
/// Lookup a function's SCC in the graph.
///
/// \returns null if the function hasn't been assigned an SCC via the RefSCC
/// iterator walk.
SCC *lookupSCC(Node &N) const { return SCCMap.lookup(&N); }
/// Lookup a function's RefSCC in the graph.
///
/// \returns null if the function hasn't been assigned a RefSCC via the
/// RefSCC iterator walk.
RefSCC *lookupRefSCC(Node &N) const {
if (SCC *C = lookupSCC(N))
return &C->getOuterRefSCC();
return nullptr;
}
/// Get a graph node for a given function, scanning it to populate the graph
/// data as necessary.
Node &get(Function &F) {
Node *&N = NodeMap[&F];
if (N)
return *N;
return insertInto(F, N);
}
///@{
/// \name Pre-SCC Mutation API
///
/// These methods are only valid to call prior to forming any SCCs for this
/// call graph. They can be used to update the core node-graph during
/// a node-based inorder traversal that precedes any SCC-based traversal.
///
/// Once you begin manipulating a call graph's SCCs, most mutation of the
/// graph must be performed via a RefSCC method. There are some exceptions
/// below.
/// Update the call graph after inserting a new edge.
void insertEdge(Node &SourceN, Node &TargetN, Edge::Kind EK);
/// Update the call graph after inserting a new edge.
void insertEdge(Function &Source, Function &Target, Edge::Kind EK) {
return insertEdge(get(Source), get(Target), EK);
}
/// Update the call graph after deleting an edge.
void removeEdge(Node &SourceN, Node &TargetN);
/// Update the call graph after deleting an edge.
void removeEdge(Function &Source, Function &Target) {
return removeEdge(get(Source), get(Target));
}
///@}
///@{
/// \name General Mutation API
///
/// There are a very limited set of mutations allowed on the graph as a whole
/// once SCCs have started to be formed. These routines have strict contracts
/// but may be called at any point.
/// Remove a dead function from the call graph (typically to delete it).
///
/// Note that the function must have an empty use list, and the call graph
/// must be up-to-date prior to calling this. That means it is by itself in
/// a maximal SCC which is by itself in a maximal RefSCC, etc. No structural
/// changes result from calling this routine other than potentially removing
/// entry points into the call graph.
///
/// If SCC formation has begun, this function must not be part of the current
/// DFS in order to call this safely. Typically, the function will have been
/// fully visited by the DFS prior to calling this routine.
void removeDeadFunction(Function &F);
///@}
///@{
/// \name Static helpers for code doing updates to the call graph.
///
/// These helpers are used to implement parts of the call graph but are also
/// useful to code doing updates or otherwise wanting to walk the IR in the
/// same patterns as when we build the call graph.
/// Recursively visits the defined functions whose address is reachable from
/// every constant in the \p Worklist.
///
/// Doesn't recurse through any constants already in the \p Visited set, and
/// updates that set with every constant visited.
///
/// For each defined function, calls \p Callback with that function.
template <typename CallbackT>
static void visitReferences(SmallVectorImpl<Constant *> &Worklist,
SmallPtrSetImpl<Constant *> &Visited,
CallbackT Callback) {
while (!Worklist.empty()) {
Constant *C = Worklist.pop_back_val();
if (Function *F = dyn_cast<Function>(C)) {
if (!F->isDeclaration())
Callback(*F);
continue;
}
if (BlockAddress *BA = dyn_cast<BlockAddress>(C)) {
// The blockaddress constant expression is a weird special case, we
// can't generically walk its operands the way we do for all other
// constants.
if (Visited.insert(BA->getFunction()).second)
Worklist.push_back(BA->getFunction());
continue;
}
for (Value *Op : C->operand_values())
if (Visited.insert(cast<Constant>(Op)).second)
Worklist.push_back(cast<Constant>(Op));
}
}
///@}
private:
typedef SmallVectorImpl<Node *>::reverse_iterator node_stack_iterator;
typedef iterator_range<node_stack_iterator> node_stack_range;
/// Allocator that holds all the call graph nodes.
SpecificBumpPtrAllocator<Node> BPA;
/// Maps function->node for fast lookup.
DenseMap<const Function *, Node *> NodeMap;
/// The entry edges into the graph.
///
/// These edges are from "external" sources. Put another way, they
/// escape at the module scope.
EdgeSequence EntryEdges;
/// Allocator that holds all the call graph SCCs.
SpecificBumpPtrAllocator<SCC> SCCBPA;
/// Maps Function -> SCC for fast lookup.
DenseMap<Node *, SCC *> SCCMap;
/// Allocator that holds all the call graph RefSCCs.
SpecificBumpPtrAllocator<RefSCC> RefSCCBPA;
/// The post-order sequence of RefSCCs.
///
/// This list is lazily formed the first time we walk the graph.
SmallVector<RefSCC *, 16> PostOrderRefSCCs;
/// A map from RefSCC to the index for it in the postorder sequence of
/// RefSCCs.
DenseMap<RefSCC *, int> RefSCCIndices;
/// The leaf RefSCCs of the graph.
///
/// These are all of the RefSCCs which have no children.
SmallVector<RefSCC *, 4> LeafRefSCCs;
/// Helper to insert a new function, with an already looked-up entry in
/// the NodeMap.
Node &insertInto(Function &F, Node *&MappedN);
/// Helper to update pointers back to the graph object during moves.
void updateGraphPtrs();
/// Allocates an SCC and constructs it using the graph allocator.
///
/// The arguments are forwarded to the constructor.
template <typename... Ts> SCC *createSCC(Ts &&... Args) {
return new (SCCBPA.Allocate()) SCC(std::forward<Ts>(Args)...);
}
/// Allocates a RefSCC and constructs it using the graph allocator.
///
/// The arguments are forwarded to the constructor.
template <typename... Ts> RefSCC *createRefSCC(Ts &&... Args) {
return new (RefSCCBPA.Allocate()) RefSCC(std::forward<Ts>(Args)...);
}
/// Common logic for building SCCs from a sequence of roots.
///
/// This is a very generic implementation of the depth-first walk and SCC
/// formation algorithm. It uses a generic sequence of roots and generic
/// callbacks for each step. This is designed to be used to implement both
/// the RefSCC formation and SCC formation with shared logic.
///
/// Currently this is a relatively naive implementation of Tarjan's DFS
/// algorithm to form the SCCs.
///
/// FIXME: We should consider newer variants such as Nuutila.
template <typename RootsT, typename GetBeginT, typename GetEndT,
typename GetNodeT, typename FormSCCCallbackT>
static void buildGenericSCCs(RootsT &&Roots, GetBeginT &&GetBegin,
GetEndT &&GetEnd, GetNodeT &&GetNode,
FormSCCCallbackT &&FormSCC);
/// Build the SCCs for a RefSCC out of a list of nodes.
void buildSCCs(RefSCC &RC, node_stack_range Nodes);
/// Connect a RefSCC into the larger graph.
///
/// This walks the edges to connect the RefSCC to its children's parent set,
/// and updates the root leaf list.
void connectRefSCC(RefSCC &RC);
/// Get the index of a RefSCC within the postorder traversal.
///
/// Requires that this RefSCC is a valid one in the (perhaps partial)
/// postorder traversed part of the graph.
int getRefSCCIndex(RefSCC &RC) {
auto IndexIt = RefSCCIndices.find(&RC);
assert(IndexIt != RefSCCIndices.end() && "RefSCC doesn't have an index!");
assert(PostOrderRefSCCs[IndexIt->second] == &RC &&
"Index does not point back at RC!");
return IndexIt->second;
}
};
inline LazyCallGraph::Edge::Edge() : Value() {}
inline LazyCallGraph::Edge::Edge(Node &N, Kind K) : Value(&N, K) {}
inline LazyCallGraph::Edge::operator bool() const { return Value.getPointer(); }
inline LazyCallGraph::Edge::Kind LazyCallGraph::Edge::getKind() const {
assert(*this && "Queried a null edge!");
return Value.getInt();
}
inline bool LazyCallGraph::Edge::isCall() const {
assert(*this && "Queried a null edge!");
return getKind() == Call;
}
inline LazyCallGraph::Node &LazyCallGraph::Edge::getNode() const {
assert(*this && "Queried a null edge!");
return *Value.getPointer();
}
inline Function &LazyCallGraph::Edge::getFunction() const {
assert(*this && "Queried a null edge!");
return getNode().getFunction();
}
// Provide GraphTraits specializations for call graphs.
template <> struct GraphTraits<LazyCallGraph::Node *> {
typedef LazyCallGraph::Node *NodeRef;
typedef LazyCallGraph::EdgeSequence::iterator ChildIteratorType;
static NodeRef getEntryNode(NodeRef N) { return N; }
static ChildIteratorType child_begin(NodeRef N) { return (*N)->begin(); }
static ChildIteratorType child_end(NodeRef N) { return (*N)->end(); }
};
template <> struct GraphTraits<LazyCallGraph *> {
typedef LazyCallGraph::Node *NodeRef;
typedef LazyCallGraph::EdgeSequence::iterator ChildIteratorType;
static NodeRef getEntryNode(NodeRef N) { return N; }
static ChildIteratorType child_begin(NodeRef N) { return (*N)->begin(); }
static ChildIteratorType child_end(NodeRef N) { return (*N)->end(); }
};
/// An analysis pass which computes the call graph for a module.
class LazyCallGraphAnalysis : public AnalysisInfoMixin<LazyCallGraphAnalysis> {
friend AnalysisInfoMixin<LazyCallGraphAnalysis>;
static AnalysisKey Key;
public:
/// Inform generic clients of the result type.
typedef LazyCallGraph Result;
/// Compute the \c LazyCallGraph for the module \c M.
///
/// This just builds the set of entry points to the call graph. The rest is
/// built lazily as it is walked.
LazyCallGraph run(Module &M, ModuleAnalysisManager &) {
return LazyCallGraph(M);
}
};
/// A pass which prints the call graph to a \c raw_ostream.
///
/// This is primarily useful for testing the analysis.
class LazyCallGraphPrinterPass
: public PassInfoMixin<LazyCallGraphPrinterPass> {
raw_ostream &OS;
public:
explicit LazyCallGraphPrinterPass(raw_ostream &OS);
PreservedAnalyses run(Module &M, ModuleAnalysisManager &AM);
};
/// A pass which prints the call graph as a DOT file to a \c raw_ostream.
///
/// This is primarily useful for visualization purposes.
class LazyCallGraphDOTPrinterPass
: public PassInfoMixin<LazyCallGraphDOTPrinterPass> {
raw_ostream &OS;
public:
explicit LazyCallGraphDOTPrinterPass(raw_ostream &OS);
PreservedAnalyses run(Module &M, ModuleAnalysisManager &AM);
};
}
#endif