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Add a new experimental generalized dependence query interface to

Browse Source 
AliasAnalysis, and some code for implementing the new query on top of
existing implementations by making standard alias and getModRefInfo
queries.


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@113329 91177308-0d34-0410-b5e6-96231b3b80d8
This commit is contained in:
Dan Gohman 2010-09-08 01:32:20 +00:00
parent 0cfcf93c95
commit 65924111bf
3 changed files with 296 additions and 0 deletions
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84
include/llvm/Analysis/AliasAnalysis.h
View File

@ -277,6 +277,81 @@ public:
virtual ModRefResult getModRefInfo(ImmutableCallSite CS1,
ImmutableCallSite CS2);
//===--------------------------------------------------------------------===//
/// Dependence queries.
///
/// DependenceResult - These are the return values for getDependence queries.
/// They are defined in terms of "memory", but they are also used to model
/// other side effects, such as I/O and volatility.
enum DependenceResult {
/// ReadThenRead - The instructions are ReadThenReadSome and the second
/// instruction reads from exactly the same memory read from by the first.
ReadThenRead,
/// ReadThenReadSome - The instructions are Independent, both are read-only,
/// and the second instruction reads from a subset of the memory read from
/// by the first.
ReadThenReadSome,
/// Independent - Neither instruction reads from or writes to memory written
/// to by the other. All enum values lower than this one are special cases
/// of Indepenent.
Independent,
/// WriteThenRead - The instructions are WriteThenReadSome and the second
/// instruction reads from exactly the same memory written by the first.
WriteThenRead,
/// WriteThenReadSome - The first instruction is write-only, the second
/// instruction is read-only, and the second only reads from memory
/// written to by the first.
WriteThenReadSome,
/// ReadThenWrite - The instructions are ReadThenWriteSome and the second
/// instruction writes to exactly the same memory read from by the first.
ReadThenWrite,
/// WriteThenWrite - The instructions are WriteThenWriteSome, and the
/// second instruction writes to exactly the same memory written to by
/// the first.
WriteThenWrite,
/// WriteSomeThenWrite - Both instructions are write-only, and the second
/// instruction writes to a superset of the memory written to by the first.
WriteSomeThenWrite,
/// Unknown - The relationship between the instructions cannot be
/// determined or does not fit into any of the cases defined here.
Unknown
};
/// DependenceQueryFlags - Flags for refining dependence queries.
enum DependenceQueryFlags {
Default = 0,
IgnoreLoads = 1,
IgnoreStores = 2
};
/// getDependence - Determine the dependence relationship between the
/// instructions. This does not include "register" dependencies; it just
/// considers memory references and other side effects.
/// WARNING: This is an experimental interface.
DependenceResult getDependence(const Instruction *First,
const Instruction *Second) {
return getDependence(First, Default, Second, Default);
}
/// getDependence - Determine the dependence relationship between the
/// instructions. This does not include "register" dependencies; it just
/// considers memory references and other side effects. This overload
/// accepts additional flags to refine the query.
/// WARNING: This is an experimental interface.
virtual DependenceResult getDependence(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags);
//===--------------------------------------------------------------------===//
/// Higher level methods for querying mod/ref information.
///
@ -322,6 +397,15 @@ public:
copyValue(Old, New);
deleteValue(Old);
}
protected:
/// getDependenceViaModRefInfo - Helper function for implementing getDependence
/// in implementations which already have getModRefInfo implementations.
DependenceResult getDependenceViaModRefInfo(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags);
};
/// isNoAliasCall - Return true if this pointer is returned by a noalias

192
lib/Analysis/AliasAnalysis.cpp
View File

@ -188,6 +188,14 @@ AliasAnalysis::getModRefBehavior(const Function *F) {
return AA->getModRefBehavior(F);
}
AliasAnalysis::DependenceResult
AliasAnalysis::getDependence(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags) {
assert(AA && "AA didn't call InitializeAliasAnalyais in its run method!");
return AA->getDependence(First, FirstFlags, Second, SecondFlags);
}
//===----------------------------------------------------------------------===//
// AliasAnalysis non-virtual helper method implementation
@ -245,6 +253,190 @@ AliasAnalysis::getModRefInfo(const VAArgInst *V, const Value *P, unsigned Size)
return ModRef;
}
AliasAnalysis::DependenceResult
AliasAnalysis::getDependenceViaModRefInfo(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags) {
if (const LoadInst *L = dyn_cast<LoadInst>(First)) {
// Be over-conservative with volatile for now.
if (L->isVolatile())
return Unknown;
// Forward this query to getModRefInfo.
switch (getModRefInfo(Second,
L->getPointerOperand(),
getTypeStoreSize(L->getType()))) {
case NoModRef:
// Second doesn't reference First's memory, so they're independent.
return Independent;
case Ref:
// Second only reads from the memory read from by First. If it
// also writes to any other memory, be conservative.
if (Second->mayWriteToMemory())
return Unknown;
// If it's loading the same size from the same address, we can
// give a more precise result.
if (const LoadInst *SecondL = dyn_cast<LoadInst>(Second)) {
unsigned LSize = getTypeStoreSize(L->getType());
unsigned SecondLSize = getTypeStoreSize(SecondL->getType());
if (alias(L->getPointerOperand(), LSize,
SecondL->getPointerOperand(), SecondLSize) ==
MustAlias) {
// If the loads are the same size, it's ReadThenRead.
if (LSize == SecondLSize)
return ReadThenRead;
// If the second load is smaller, it's only ReadThenReadSome.
if (LSize > SecondLSize)
return ReadThenReadSome;
}
}
// Otherwise it's just two loads.
return Independent;
case Mod:
// Second only writes to the memory read from by First. If it
// also reads from any other memory, be conservative.
if (Second->mayReadFromMemory())
return Unknown;
// If it's storing the same size to the same address, we can
// give a more precise result.
if (const StoreInst *SecondS = dyn_cast<StoreInst>(Second)) {
unsigned LSize = getTypeStoreSize(L->getType());
unsigned SecondSSize = getTypeStoreSize(SecondS->getType());
if (alias(L->getPointerOperand(), LSize,
SecondS->getPointerOperand(), SecondSSize) ==
MustAlias) {
// If the load and the store are the same size, it's ReadThenWrite.
if (LSize == SecondSSize)
return ReadThenWrite;
}
}
// Otherwise we don't know if it could be writing to other memory.
return Unknown;
case ModRef:
// Second reads and writes to the memory read from by First.
// We don't have a way to express that.
return Unknown;
}
} else if (const StoreInst *S = dyn_cast<StoreInst>(First)) {
// Be over-conservative with volatile for now.
if (S->isVolatile())
return Unknown;
// Forward this query to getModRefInfo.
switch (getModRefInfo(Second,
S->getPointerOperand(),
getTypeStoreSize(S->getValueOperand()->getType()))) {
case NoModRef:
// Second doesn't reference First's memory, so they're independent.
return Independent;
case Ref:
// Second only reads from the memory written to by First. If it
// also writes to any other memory, be conservative.
if (Second->mayWriteToMemory())
return Unknown;
// If it's loading the same size from the same address, we can
// give a more precise result.
if (const LoadInst *SecondL = dyn_cast<LoadInst>(Second)) {
unsigned SSize = getTypeStoreSize(S->getValueOperand()->getType());
unsigned SecondLSize = getTypeStoreSize(SecondL->getType());
if (alias(S->getPointerOperand(), SSize,
SecondL->getPointerOperand(), SecondLSize) ==
MustAlias) {
// If the store and the load are the same size, it's WriteThenRead.
if (SSize == SecondLSize)
return WriteThenRead;
// If the load is smaller, it's only WriteThenReadSome.
if (SSize > SecondLSize)
return WriteThenReadSome;
}
}
// Otherwise we don't know if it could be reading from other memory.
return Unknown;
case Mod:
// Second only writes to the memory written to by First. If it
// also reads from any other memory, be conservative.
if (Second->mayReadFromMemory())
return Unknown;
// If it's storing the same size to the same address, we can
// give a more precise result.
if (const StoreInst *SecondS = dyn_cast<StoreInst>(Second)) {
unsigned SSize = getTypeStoreSize(S->getValueOperand()->getType());
unsigned SecondSSize = getTypeStoreSize(SecondS->getType());
if (alias(S->getPointerOperand(), SSize,
SecondS->getPointerOperand(), SecondSSize) ==
MustAlias) {
// If the stores are the same size, it's WriteThenWrite.
if (SSize == SecondSSize)
return WriteThenWrite;
// If the second store is larger, it's only WriteSomeThenWrite.
if (SSize < SecondSSize)
return WriteSomeThenWrite;
}
}
// Otherwise we don't know if it could be writing to other memory.
return Unknown;
case ModRef:
// Second reads and writes to the memory written to by First.
// We don't have a way to express that.
return Unknown;
}
} else if (const VAArgInst *V = dyn_cast<VAArgInst>(First)) {
// Forward this query to getModRefInfo.
if (getModRefInfo(Second, V->getOperand(0), UnknownSize) == NoModRef)
// Second doesn't reference First's memory, so they're independent.
return Independent;
} else if (ImmutableCallSite FirstCS = cast<Value>(First)) {
// If both instructions are calls/invokes we can use the two-callsite
// form of getModRefInfo.
if (ImmutableCallSite SecondCS = cast<Value>(Second))
// getModRefInfo's arguments are backwards from intuition.
switch (getModRefInfo(SecondCS, FirstCS)) {
case NoModRef:
// Second doesn't reference First's memory, so they're independent.
return Independent;
case Ref:
// If they're both read-only, there's no dependence.
if (FirstCS.onlyReadsMemory() && SecondCS.onlyReadsMemory())
return Independent;
// Otherwise it's not obvious what we can do here.
return Unknown;
case Mod:
// It's not obvious what we can do here.
return Unknown;
case ModRef:
// I know, right?
return Unknown;
}
}
// For anything else, be conservative.
return Unknown;
}
AliasAnalysis::ModRefBehavior
AliasAnalysis::getIntrinsicModRefBehavior(unsigned iid) {

20
lib/Analysis/BasicAliasAnalysis.cpp
View File

@ -171,6 +171,13 @@ namespace {
return ModRef;
}
virtual DependenceResult getDependence(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags) {
return Unknown;
}
virtual void deleteValue(Value *V) {}
virtual void copyValue(Value *From, Value *To) {}
@ -523,6 +530,11 @@ namespace {
/// For use when the call site is not known.
virtual ModRefBehavior getModRefBehavior(const Function *F);
virtual DependenceResult getDependence(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags);
/// getAdjustedAnalysisPointer - This method is used when a pass implements
/// an analysis interface through multiple inheritance. If needed, it
/// should override this to adjust the this pointer as needed for the
@ -734,6 +746,14 @@ BasicAliasAnalysis::getModRefInfo(ImmutableCallSite CS,
return AliasAnalysis::getModRefInfo(CS, P, Size);
}
AliasAnalysis::DependenceResult
BasicAliasAnalysis::getDependence(const Instruction *First,
DependenceQueryFlags FirstFlags,
const Instruction *Second,
DependenceQueryFlags SecondFlags) {
// We don't have anything special to say yet.
return getDependenceViaModRefInfo(First, FirstFlags, Second, SecondFlags);
}
/// aliasGEP - Provide a bunch of ad-hoc rules to disambiguate a GEP instruction
/// against another pointer. We know that V1 is a GEP, but we don't know