Implement a more powerful, simpler, pass system. This pass system can figure

out how to run a collection of passes optimially given their behaviors and
charactaristics.

Convert code to use it.

llvm-svn: 1507
This commit is contained in:
Chris Lattner 2002-01-21 07:31:50 +00:00
parent e8d81d0819
commit 0686e435d1
32 changed files with 238 additions and 208 deletions

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@ -22,7 +22,7 @@
class PointerType;
struct FindUnsafePointerTypes : public Pass {
struct FindUnsafePointerTypes : public MethodPass {
// UnsafeTypes - Set of types that are not safe to transform.
std::set<PointerType*> UnsafeTypes;
public:
@ -32,11 +32,11 @@ public:
return UnsafeTypes;
}
// doPerMethodWork - Inspect the operations that the specified method does on
// runOnMethod - Inspect the operations that the specified method does on
// values of various types. If they are deemed to be 'unsafe' note that the
// type is not safe to transform.
//
virtual bool doPerMethodWork(Method *M);
virtual bool runOnMethod(Method *M);
// printResults - Loop over the results of the analysis, printing out unsafe
// types.

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@ -11,7 +11,7 @@
#include <set>
class SymbolTable;
class FindUsedTypes : public Pass {
class FindUsedTypes : public MethodPass {
std::set<const Type *> UsedTypes;
bool IncludeSymbolTables;
@ -45,14 +45,14 @@ private:
void IncorporateSymbolTable(const SymbolTable *ST);
public:
// doPassInitialization - This loops over global constants defined in the
// doInitialization - This loops over global constants defined in the
// module, converting them to their new type.
//
bool doPassInitialization(Module *M);
bool doInitialization(Module *M);
// doPerMethodWork - This incorporates all types used by the specified method
// runOnMethod - This incorporates all types used by the specified method
//
bool doPerMethodWork(Method *M);
bool runOnMethod(Method *M);
};
#endif

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@ -1,7 +1,9 @@
//===- llvm/Assembly/PrintModulePass.h - Printing Pass -----------*- C++ -*--=//
//
// This file defines a simple pass to print out methods of a module as they are
// processed.
// This file defines two passes to print out a module. The PrintModulePass
// pass simply prints out the entire module when it is executed. The
// PrintMethodPass class is designed to be pipelined with other MethodPass's,
// and prints out the methods of the class as they are processed.
//
//===----------------------------------------------------------------------===//
@ -13,36 +15,42 @@
#include <iostream>
class PrintModulePass : public Pass {
std::string Banner; // String to print before each method
std::ostream *Out; // ostream to print on
bool DeleteStream; // Delete the ostream in our dtor?
bool PrintPerMethod; // Print one method at a time rather than the whole?
public:
inline PrintModulePass(const std::string &B, std::ostream *o = &std::cout,
bool DS = false,
bool printPerMethod = true)
: Banner(B), Out(o), DeleteStream(DS), PrintPerMethod(printPerMethod) {
inline PrintModulePass(std::ostream *o = &std::cout, bool DS = false)
: Out(o), DeleteStream(DS) {
}
inline ~PrintModulePass() {
if (DeleteStream) delete Out;
}
// doPerMethodWork - This pass just prints a banner followed by the method as
// it's processed.
//
bool doPerMethodWork(Method *M) {
if (PrintPerMethod)
(*Out) << Banner << M;
bool run(Module *M) {
(*Out) << M;
return false;
}
};
// doPassFinalization - Virtual method overriden by subclasses to do any post
// processing needed after all passes have run.
class PrintMethodPass : public MethodPass {
std::string Banner; // String to print before each method
std::ostream *Out; // ostream to print on
bool DeleteStream; // Delete the ostream in our dtor?
public:
inline PrintMethodPass(const std::string &B, std::ostream *o = &std::cout,
bool DS = false)
: Banner(B), Out(o), DeleteStream(DS) {
}
inline ~PrintMethodPass() {
if (DeleteStream) delete Out;
}
// runOnMethod - This pass just prints a banner followed by the method as
// it's processed.
//
bool doPassFinalization(Module *M) {
if (! PrintPerMethod)
(*Out) << Banner << M;
bool runOnMethod(Method *M) {
(*Out) << Banner << M;
return false;
}
};

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@ -23,7 +23,7 @@ public:
if (DeleteStream) delete Out;
}
bool doPassFinalization(Module *M) {
bool run(Module *M) {
WriteBytecodeToFile(M, *Out);
return false;
}

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@ -13,7 +13,7 @@
#include "llvm/Pass.h"
class TargetData;
class LowerAllocations : public Pass {
class LowerAllocations : public MethodPass {
Method *MallocMeth; // Methods in the module we are processing
Method *FreeMeth; // Initialized by doPassInitializationVirt
@ -28,12 +28,12 @@ public:
//
// This function is always successful.
//
bool doPassInitialization(Module *M);
bool doInitialization(Module *M);
// doPerMethodWork - This method does the actual work of converting
// instructions over, assuming that the pass has already been initialized.
//
bool doPerMethodWork(Method *M);
bool runOnMethod(Method *M);
};
#endif

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@ -13,13 +13,13 @@ class CallInst;
namespace opt {
struct MethodInlining : public Pass {
struct MethodInlining : public MethodPass {
// DoMethodInlining - Use a heuristic based approach to inline methods that
// seem to look good.
//
static bool doMethodInlining(Method *M);
virtual bool doPerMethodWork(Method *M) {
virtual bool runOnMethod(Method *M) {
return doMethodInlining(M);
}
};

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@ -11,12 +11,12 @@
#include "llvm/Pass.h"
struct HoistPHIConstants : public Pass {
struct HoistPHIConstants : public MethodPass {
// doHoistPHIConstants - Hoist constants out of PHI instructions
//
static bool doHoistPHIConstants(Method *M);
virtual bool doPerMethodWork(Method *M) { return doHoistPHIConstants(M); }
virtual bool runOnMethod(Method *M) { return doHoistPHIConstants(M); }
};
#endif

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@ -8,7 +8,7 @@
#include "llvm/Analysis/FindUsedTypes.h"
class CleanupGCCOutput : public Pass {
class CleanupGCCOutput : public MethodPass {
Method *Malloc, *Free; // Pointers to external declarations, or null if none
FindUsedTypes FUT; // Use FUT to eliminate type names that are never used
public:
@ -27,14 +27,14 @@ public:
//
// Also, initialize instance variables.
//
bool doPassInitialization(Module *M);
bool doInitialization(Module *M);
// doPerMethodWork - This method simplifies the specified method hopefully.
//
bool doPerMethodWork(Method *M);
bool runOnMethod(Method *M);
// doPassFinalization - Strip out type names that are unused by the program
bool doPassFinalization(Module *M);
bool doFinalization(Module *M);
private:
bool doOneCleanupPass(Method *M);
};

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@ -22,7 +22,8 @@
class Constant;
class GlobalVariable;
class ConstantMerge : public Pass {
// FIXME: ConstantMerge should not be a methodPass!!!
class ConstantMerge : public MethodPass {
protected:
std::map<Constant*, GlobalVariable*> Constants;
unsigned LastConstantSeen;
@ -34,14 +35,16 @@ public:
//
static bool mergeDuplicateConstants(Module *M);
// doPassInitialization - For this pass, process all of the globals in the
// doInitialization - For this pass, process all of the globals in the
// module, eliminating duplicate constants.
//
bool doPassInitialization(Module *M);
bool doInitialization(Module *M);
// doPassFinalization - Clean up internal state for this module
bool runOnMethod(Method*) { return false; }
// doFinalization - Clean up internal state for this module
//
bool doPassFinalization(Module *M) {
bool doFinalization(Module *M) {
LastConstantSeen = 0;
Constants.clear();
return false;
@ -52,7 +55,7 @@ struct DynamicConstantMerge : public ConstantMerge {
// doPerMethodWork - Check to see if any globals have been added to the
// global list for the module. If so, eliminate them.
//
bool doPerMethodWork(Method *M);
bool runOnMethod(Method *M);
};
#endif

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@ -7,15 +7,17 @@
#ifndef LLVM_TRANSFORM_IPO_GLOBALDCE_H
#define LLVM_TRANSFORM_IPO_GLOBALDCE_H
#include "llvm/Pass.h"
namespace cfg { class CallGraph; }
class Module;
struct GlobalDCE {
struct GlobalDCE : public Pass {
// run - Do the GlobalDCE pass on the specified module, optionally updating
// the specified callgraph to reflect the changes.
//
bool run(Module *M, cfg::CallGraph *CG = 0);
bool run(Module *M);
};
#endif

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@ -1,22 +1,27 @@
//===- llvm/Transforms/SwapStructContents.h - Permute Structs ----*- C++ -*--=//
//===- llvm/Transforms/SimpleStructMutation.h - Permute Structs --*- C++ -*--=//
//
// This pass does a simple transformation that swaps all of the elements of the
// struct types in the program around.
// This pass does is a wrapper that can do a few simple structure mutation
// transformations.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_TRANSFORMS_SWAPSTRUCTCONTENTS_H
#define LLVM_TRANSFORMS_SWAPSTRUCTCONTENTS_H
#ifndef LLVM_TRANSFORMS_SIMPLESTRUCTMUTATION_H
#define LLVM_TRANSFORMS_SIMPLESTRUCTMUTATION_H
#include "llvm/Transforms/MutateStructTypes.h"
// FIXME: Move to correct location!
class PrebuiltStructMutation : public MutateStructTypes {
class SimpleStructMutation : public MutateStructTypes {
public:
enum Transform { SwapElements, SortElements };
enum Transform { SwapElements, SortElements } CurrentXForm;
PrebuiltStructMutation(Module *M, enum Transform XForm)
: MutateStructTypes(getTransforms(M, XForm)) {}
SimpleStructMutation(enum Transform XForm) : CurrentXForm(XForm) {}
virtual bool run(Module *M) {
setTransforms(getTransforms(M, CurrentXForm));
bool Changed = MutateStructTypes::run(M);
clearTransforms();
return Changed;
}
private:
static TransformsType getTransforms(Module *M, enum Transform);

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@ -11,7 +11,7 @@
#include "llvm/Pass.h"
class Method;
class InsertTraceCode : public Pass {
class InsertTraceCode : public MethodPass {
bool TraceBasicBlockExits, TraceMethodExits;
Method *PrintfMeth;
public:
@ -21,7 +21,7 @@ public:
// Add a prototype for printf if it is not already in the program.
//
bool doPassInitialization(Module *M);
bool doInitialization(Module *M);
//--------------------------------------------------------------------------
// Function InsertCodeToTraceValues
@ -32,9 +32,9 @@ public:
static bool doit(Method *M, bool traceBasicBlockExits,
bool traceMethodExits, Method *Printf);
// doPerMethodWork - This method does the work. Always successful.
// runOnMethod - This method does the work. Always successful.
//
bool doPerMethodWork(Method *M) {
bool runOnMethod(Method *M) {
return doit(M, TraceBasicBlockExits, TraceMethodExits, PrintfMeth);
}
};

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@ -51,25 +51,40 @@ public:
//
typedef std::map<const StructType*, std::vector<int> > TransformsType;
MutateStructTypes(const TransformsType &Transforms);
MutateStructTypes(const TransformsType &Transforms) {
setTransforms(Transforms);
}
// run - do the transformation
virtual bool run(Module *M);
// doPassInitialization - This loops over global constants defined in the
protected:
// Alternatively, it is valid to subclass this class and provide transforms
// this way. See SimpleStructMutation for an example.
//
MutateStructTypes() {}
void setTransforms(const TransformsType &Transforms);
void clearTransforms();
private:
// processGlobals - This loops over global constants defined in the
// module, converting them to their new type. Also this creates placeholder
// methods for methods than need to be copied because they have a new
// signature type.
//
bool doPassInitialization(Module *M);
void processGlobals(Module *M);
// doPerMethodWork - This transforms the instructions of the method to use the
// transformMethod - This transforms the instructions of the method to use the
// new types.
//
bool doPerMethodWork(Method *M);
void transformMethod(Method *M);
// doPassFinalization - This removes the old versions of methods that are no
// removeDeadGlobals - This removes the old versions of methods that are no
// longer needed.
//
virtual bool doPassFinalization(Module *M);
void removeDeadGlobals(Module *M);
private:
// ConvertType - Convert from the old type system to the new one...

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@ -15,10 +15,10 @@
// expressions as possible, by converting expressions to use getelementptr and
// friends.
//
struct RaisePointerReferences : public Pass {
struct RaisePointerReferences : public MethodPass {
static bool doit(Method *M);
virtual bool doPerMethodWork(Method *M) { return doit(M); }
virtual bool runOnMethod(Method *M) { return doit(M); }
};
@ -26,10 +26,10 @@ struct RaisePointerReferences : public Pass {
// converts all induction variables to reference a cannonical induction
// variable (which starts at 0 and counts by 1).
//
struct EliminateAuxillaryInductionVariables : public Pass {
struct EliminateAuxillaryInductionVariables : public MethodPass {
static bool doit(Method *M) { return false; } // TODO!
virtual bool doPerMethodWork(Method *M) { return doit(M); }
virtual bool runOnMethod(Method *M) { return doit(M); }
};
#endif

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@ -12,7 +12,7 @@ class TerminatorInst;
namespace opt {
struct ConstantPropogation : public Pass {
struct ConstantPropogation : public MethodPass {
// doConstantPropogation - Do trivial constant propogation and expression
// folding
static bool doConstantPropogation(Method *M);
@ -22,7 +22,7 @@ struct ConstantPropogation : public Pass {
//
static bool doConstantPropogation(BasicBlock *BB, BasicBlock::iterator &I);
inline bool doPerMethodWork(Method *M) {
inline bool runOnMethod(Method *M) {
return doConstantPropogation(M);
}
};
@ -39,10 +39,10 @@ bool ConstantFoldTerminator(TerminatorInst *T);
//===----------------------------------------------------------------------===//
// Sparse Conditional Constant Propogation Pass
//
struct SCCPPass : public Pass {
struct SCCPPass : public MethodPass {
static bool doSCCP(Method *M);
inline bool doPerMethodWork(Method *M) {
inline bool runOnMethod(Method *M) {
return doSCCP(M);
}
};

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@ -13,7 +13,7 @@
namespace opt {
struct DeadCodeElimination : public Pass {
struct DeadCodeElimination : public MethodPass {
// External Interface:
//
static bool doDCE(Method *M);
@ -33,23 +33,23 @@ struct DeadCodeElimination : public Pass {
static bool RemoveUnusedGlobalValues(Module *M);
// Pass Interface...
virtual bool doPassInitialization(Module *M) {
virtual bool doInitialization(Module *M) {
return RemoveUnusedGlobalValues(M);
}
virtual bool doPerMethodWork(Method *M) { return doDCE(M); }
virtual bool doPassFinalization(Module *M) {
virtual bool runOnMethod(Method *M) { return doDCE(M); }
virtual bool doFinalization(Module *M) {
return RemoveUnusedGlobalValues(M);
}
};
struct AgressiveDCE : public Pass {
struct AgressiveDCE : public MethodPass {
// DoADCE - Execute the Agressive Dead Code Elimination Algorithm
//
static bool doADCE(Method *M); // Defined in ADCE.cpp
virtual bool doPerMethodWork(Method *M) {
virtual bool runOnMethod(Method *M) {
return doADCE(M);
}
};

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@ -10,10 +10,10 @@
#include "llvm/Pass.h"
struct InductionVariableSimplify : public Pass {
struct InductionVariableSimplify : public MethodPass {
static bool doit(Method *M);
virtual bool doPerMethodWork(Method *M) { return doit(M); }
virtual bool runOnMethod(Method *M) { return doit(M); }
};
#endif

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@ -12,12 +12,12 @@
namespace opt {
struct InductionVariableCannonicalize : public Pass {
struct InductionVariableCannonicalize : public MethodPass {
// doInductionVariableCannonicalize - Simplify induction variables in loops
//
static bool doIt(Method *M);
virtual bool doPerMethodWork(Method *M) {
virtual bool runOnMethod(Method *M) {
return doIt(M);
}
};

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@ -17,11 +17,11 @@
#include "llvm/Pass.h"
struct InstructionCombining : public Pass {
struct InstructionCombining : public MethodPass {
static bool doit(Method *M);
static bool CombineInstruction(Instruction *I);
virtual bool doPerMethodWork(Method *M) { return doit(M); }
virtual bool runOnMethod(Method *M) { return doit(M); }
};
#endif

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@ -12,28 +12,28 @@
namespace opt {
struct SymbolStripping : public Pass {
struct SymbolStripping : public MethodPass {
// doSymbolStripping - Remove all symbolic information from a method
//
static bool doSymbolStripping(Method *M);
virtual bool doPerMethodWork(Method *M) {
virtual bool runOnMethod(Method *M) {
return doSymbolStripping(M);
}
};
struct FullSymbolStripping : public Pass {
struct FullSymbolStripping : public MethodPass {
// doStripGlobalSymbols - Remove all symbolic information from all methods
// in a module, and all module level symbols. (method names, etc...)
//
static bool doStripGlobalSymbols(Module *M);
virtual bool doPassInitialization(Module *M) {
virtual bool doInitialization(Module *M) {
return doStripGlobalSymbols(M);
}
virtual bool doPerMethodWork(Method *M) {
virtual bool runOnMethod(Method *M) {
return SymbolStripping::doSymbolStripping(M);
}
};

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@ -45,11 +45,11 @@ static inline bool isSafeInstruction(const Instruction *I) {
}
// doPerMethodWork - Inspect the operations that the specified method does on
// runOnMethod - Inspect the operations that the specified method does on
// values of various types. If they are deemed to be 'unsafe' note that the
// type is not safe to transform.
//
bool FindUnsafePointerTypes::doPerMethodWork(Method *Meth) {
bool FindUnsafePointerTypes::runOnMethod(Method *Meth) {
const Method *M = Meth; // We don't need/want write access
for (Method::const_inst_iterator I = M->inst_begin(), E = M->inst_end();
I != E; ++I) {

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@ -35,10 +35,10 @@ void FindUsedTypes::IncorporateSymbolTable(const SymbolTable *ST) {
}
// doPassInitialization - This loops over global constants defined in the
// doInitialization - This loops over global constants defined in the
// module, converting them to their new type.
//
bool FindUsedTypes::doPassInitialization(Module *m) {
bool FindUsedTypes::doInitialization(Module *m) {
const Module *M = m;
if (IncludeSymbolTables && M->hasSymbolTable())
IncorporateSymbolTable(M->getSymbolTable()); // Add symtab first...
@ -51,7 +51,7 @@ bool FindUsedTypes::doPassInitialization(Module *m) {
// doPerMethodWork - This incorporates all types used by the specified method
//
bool FindUsedTypes::doPerMethodWork(Method *m) {
bool FindUsedTypes::runOnMethod(Method *m) {
const Method *M = m;
if (IncludeSymbolTables && M->hasSymbolTable())
IncorporateSymbolTable(M->getSymbolTable()); // Add symtab first...

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@ -65,16 +65,16 @@ bool ConstantMerge::mergeDuplicateConstants(Module *M) {
}
// doPassInitialization - For this pass, process all of the globals in the
// doInitialization - For this pass, process all of the globals in the
// module, eliminating duplicate constants.
//
bool ConstantMerge::doPassInitialization(Module *M) {
bool ConstantMerge::doInitialization(Module *M) {
return ::mergeDuplicateConstants(M, LastConstantSeen, Constants);
}
// doPerMethodWork - Check to see if any globals have been added to the
// global list for the module. If so, eliminate them.
//
bool DynamicConstantMerge::doPerMethodWork(Method *M) {
bool DynamicConstantMerge::runOnMethod(Method *M) {
return ::mergeDuplicateConstants(M->getParent(), LastConstantSeen, Constants);
}

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@ -220,14 +220,14 @@ static inline bool ShouldNukeSymtabEntry(const std::pair<string, Value*> &E) {
return false;
}
// doPassInitialization - For this pass, it removes global symbol table
// doInitialization - For this pass, it removes global symbol table
// entries for primitive types. These are never used for linking in GCC and
// they make the output uglier to look at, so we nuke them.
//
bool CleanupGCCOutput::doPassInitialization(Module *M) {
bool CleanupGCCOutput::doInitialization(Module *M) {
bool Changed = false;
FUT.doPassInitialization(M);
FUT.doInitialization(M);
if (PtrSByte == 0)
PtrSByte = PointerType::get(Type::SByteTy);
@ -551,17 +551,17 @@ static bool fixLocalProblems(Method *M) {
// doPerMethodWork - This method simplifies the specified method hopefully.
//
bool CleanupGCCOutput::doPerMethodWork(Method *M) {
bool CleanupGCCOutput::runOnMethod(Method *M) {
bool Changed = fixLocalProblems(M);
while (doOneCleanupPass(M)) Changed = true;
FUT.doPerMethodWork(M);
FUT.runOnMethod(M);
return Changed;
}
bool CleanupGCCOutput::doPassFinalization(Module *M) {
bool CleanupGCCOutput::doFinalization(Module *M) {
bool Changed = false;
FUT.doPassFinalization(M);
FUT.doFinalization(M);
if (M->hasSymbolTable()) {
SymbolTable *ST = M->getSymbolTable();

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@ -11,10 +11,7 @@
#include "Support/DepthFirstIterator.h"
#include <set>
static bool RemoveUnreachableMethods(Module *M, cfg::CallGraph *CG) {
// Create a call graph if one is not already available...
cfg::CallGraph &CallGraph = CG ? *CG : *new cfg::CallGraph(M);
static bool RemoveUnreachableMethods(Module *M, cfg::CallGraph &CallGraph) {
// Calculate which methods are reachable from the external methods in the call
// graph.
//
@ -36,11 +33,7 @@ static bool RemoveUnreachableMethods(Module *M, cfg::CallGraph *CG) {
}
// Nothing to do if no unreachable methods have been found...
if (MethodsToDelete.empty()) {
// Free the created call graph if it was not passed in
if (&CallGraph != CG) delete &CallGraph;
return false;
}
if (MethodsToDelete.empty()) return false;
// Unreachables methods have been found and should have no references to them,
// delete them now.
@ -49,11 +42,12 @@ static bool RemoveUnreachableMethods(Module *M, cfg::CallGraph *CG) {
E = MethodsToDelete.end(); I != E; ++I)
delete CallGraph.removeMethodFromModule(*I);
// Free the created call graph if it was not passed in
if (&CallGraph != CG) delete &CallGraph;
return true;
}
bool GlobalDCE::run(Module *M, cfg::CallGraph *CG = 0) {
return RemoveUnreachableMethods(M, CG);
bool GlobalDCE::run(Module *M) {
// TODO: FIXME: GET THE CALL GRAPH FROM THE PASS!
// Create a call graph if one is not already available...
cfg::CallGraph CallGraph(M);
return RemoveUnreachableMethods(M, CallGraph);
}

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@ -20,9 +20,9 @@
#include "llvm/iMemory.h"
#include "llvm/iTerminators.h"
#include "llvm/iOther.h"
#include "Support/STLExtras.h"
#include <algorithm>
using std::map;
using std::make_pair;
using std::vector;
// To enable debugging, uncomment this...
@ -56,7 +56,7 @@ const Type *MutateStructTypes::ConvertType(const Type *Ty) {
const Type *DestTy = 0;
PATypeHolder<Type> PlaceHolder = OpaqueType::get();
TypeMap.insert(make_pair(Ty, PlaceHolder.get()));
TypeMap.insert(std::make_pair(Ty, PlaceHolder.get()));
switch (Ty->getPrimitiveID()) {
case Type::MethodTyID: {
@ -100,7 +100,7 @@ const Type *MutateStructTypes::ConvertType(const Type *Ty) {
// Refine our little placeholder value into a real type...
cast<DerivedType>(PlaceHolder.get())->refineAbstractTypeTo(DestTy);
TypeMap.insert(make_pair(Ty, PlaceHolder.get()));
TypeMap.insert(std::make_pair(Ty, PlaceHolder.get()));
return PlaceHolder.get();
}
@ -179,21 +179,20 @@ Value *MutateStructTypes::ConvertValue(const Value *V) {
}
// Ctor - Take a map that specifies what transformation to do for each field
// of the specified structure types. There is one element of the vector for
// each field of the structure. The value specified indicates which slot of
// setTransforms - Take a map that specifies what transformation to do for each
// field of the specified structure types. There is one element of the vector
// for each field of the structure. The value specified indicates which slot of
// the destination structure the field should end up in. A negative value
// indicates that the field should be deleted entirely.
//
MutateStructTypes::MutateStructTypes(const map<const StructType*,
vector<int> > &XForm) {
void MutateStructTypes::setTransforms(const TransformsType &XForm) {
// Loop over the types and insert dummy entries into the type map so that
// recursive types are resolved properly...
for (map<const StructType*, vector<int> >::const_iterator I = XForm.begin(),
E = XForm.end(); I != E; ++I) {
const StructType *OldTy = I->first;
TypeMap.insert(make_pair(OldTy, OpaqueType::get()));
TypeMap.insert(std::make_pair(OldTy, OpaqueType::get()));
}
// Loop over the type specified and figure out what types they should become
@ -229,17 +228,24 @@ MutateStructTypes::MutateStructTypes(const map<const StructType*,
cast<DerivedType>(OldTypeStub)->refineAbstractTypeTo(NSTy);
// Add the transformation to the Transforms map.
Transforms.insert(make_pair(OldTy, make_pair(NSTy, InVec)));
Transforms.insert(std::make_pair(OldTy, std::make_pair(NSTy, InVec)));
DEBUG_MST(cerr << "Mutate " << OldTy << "\nTo " << NSTy << endl);
}
}
void MutateStructTypes::clearTransforms() {
Transforms.clear();
TypeMap.clear();
GlobalMap.clear();
assert(LocalValueMap.empty() &&
"Local Value Map should always be empty between transformations!");
}
// doPassInitialization - This loops over global constants defined in the
// doInitialization - This loops over global constants defined in the
// module, converting them to their new type.
//
bool MutateStructTypes::doPassInitialization(Module *M) {
void MutateStructTypes::processGlobals(Module *M) {
// Loop through the methods in the module and create a new version of the
// method to contained the transformed code. Don't use an iterator, because
// we will be adding values to the end of the vector, and it could be
@ -285,14 +291,12 @@ bool MutateStructTypes::doPassInitialization(Module *M) {
}
}
}
return true;
}
// doPassFinalization - For this pass, all this does is remove the old versions
// removeDeadGlobals - For this pass, all this does is remove the old versions
// of the methods and global variables that we no longer need.
bool MutateStructTypes::doPassFinalization(Module *M) {
void MutateStructTypes::removeDeadGlobals(Module *M) {
// The first half of the methods in the module have to go.
//unsigned NumMethods = M->size();
//unsigned NumGVars = M->gsize();
@ -313,20 +317,18 @@ bool MutateStructTypes::doPassFinalization(Module *M) {
else
++I;
}
return true;
}
// doPerMethodWork - This transforms the instructions of the method to use the
// transformMethod - This transforms the instructions of the method to use the
// new types.
//
bool MutateStructTypes::doPerMethodWork(Method *m) {
void MutateStructTypes::transformMethod(Method *m) {
const Method *M = m;
map<const GlobalValue*, GlobalValue*>::iterator GMI = GlobalMap.find(M);
if (GMI == GlobalMap.end())
return false; // Do not affect one of our new methods that we are creating
return; // Do not affect one of our new methods that we are creating
Method *NewMeth = cast<Method>(GMI->second);
@ -501,5 +503,14 @@ bool MutateStructTypes::doPerMethodWork(Method *m) {
}
LocalValueMap.clear();
return true;
}
bool MutateStructTypes::run(Module *M) {
processGlobals(M);
for_each(M->begin(), M->end(),
bind_obj(this, &MutateStructTypes::transformMethod));
removeDeadGlobals(M);
}

View File

@ -58,18 +58,18 @@ static unsigned getIndex(const vector<pair<unsigned, unsigned> > &Vec,
static inline void GetTransformation(const StructType *ST,
vector<int> &Transform,
enum PrebuiltStructMutation::Transform XForm) {
enum SimpleStructMutation::Transform XForm) {
unsigned NumElements = ST->getElementTypes().size();
Transform.reserve(NumElements);
switch (XForm) {
case PrebuiltStructMutation::SwapElements:
case SimpleStructMutation::SwapElements:
// The transformation to do is: just simply swap the elements
for (unsigned i = 0; i < NumElements; ++i)
Transform.push_back(NumElements-i-1);
break;
case PrebuiltStructMutation::SortElements: {
case SimpleStructMutation::SortElements: {
vector<pair<unsigned, unsigned> > ElList;
// Build mapping from index to size
@ -87,26 +87,26 @@ static inline void GetTransformation(const StructType *ST,
}
}
// doPassInitialization - This does all of the work of the pass
//
PrebuiltStructMutation::TransformsType
PrebuiltStructMutation::getTransforms(Module *M, enum Transform XForm) {
SimpleStructMutation::TransformsType
SimpleStructMutation::getTransforms(Module *M, enum Transform XForm) {
// FIXME: These should be calculated by the Pass framework!
// We need to know which types to modify, and which types we CAN'T modify
FindUsedTypes FUT/*(true)*/; // TODO: Do symbol tables as well
FindUnsafePointerTypes FUPT;
FindUsedTypes *FUT = new FindUsedTypes(/*true*/); // TODO: Do symbol tables as well
FindUnsafePointerTypes *FUPT = new FindUnsafePointerTypes();
// Simutaneously find all of the types used, and all of the types that aren't
// safe.
//
vector<Pass*> Analyses;
Analyses.push_back(&FUT);
Analyses.push_back(&FUPT);
Pass::runAllPasses(M, Analyses); // Do analyses
PassManager Analyses;
Analyses.add(FUT);
Analyses.add(FUPT);
Analyses.run(M); // Do analyses
// Get the results out of the analyzers...
const set<PointerType*> &UnsafePTys = FUPT.getUnsafeTypes();
const set<const Type *> &UsedTypes = FUT.getTypes();
const set<PointerType*> &UnsafePTys = FUPT->getUnsafeTypes();
const set<const Type *> &UsedTypes = FUT->getTypes();
// Combine the two sets, weeding out non structure types. Closures in C++

View File

@ -23,7 +23,7 @@ using std::string;
// Add a prototype for printf if it is not already in the program.
//
bool InsertTraceCode::doPassInitialization(Module *M) {
bool InsertTraceCode::doInitialization(Module *M) {
SymbolTable *ST = M->getSymbolTable();
const Type *SBP = PointerType::get(Type::SByteTy);
const MethodType *MTy =

View File

@ -17,12 +17,12 @@
using std::vector;
// doPassInitialization - For the lower allocations pass, this ensures that a
// doInitialization - For the lower allocations pass, this ensures that a
// module contains a declaration for a malloc and a free function.
//
// This function is always successful.
//
bool LowerAllocations::doPassInitialization(Module *M) {
bool LowerAllocations::doInitialization(Module *M) {
bool Changed = false;
const MethodType *MallocType =
MethodType::get(PointerType::get(Type::SByteTy),
@ -55,10 +55,10 @@ bool LowerAllocations::doPassInitialization(Module *M) {
return Changed; // Always successful
}
// doPerMethodWork - This method does the actual work of converting
// runOnMethod - This method does the actual work of converting
// instructions over, assuming that the pass has already been initialized.
//
bool LowerAllocations::doPerMethodWork(Method *M) {
bool LowerAllocations::runOnMethod(Method *M) {
bool Changed = false;
assert(MallocMeth && FreeMeth && M && "Pass not initialized!");

View File

@ -63,19 +63,19 @@ int main(int argc, char **argv) {
// In addition to just parsing the input from GCC, we also want to spiff it up
// a little bit. Do this now.
//
std::vector<Pass*> Passes;
Passes.push_back(new opt::DeadCodeElimination()); // Remove Dead code/vars
Passes.push_back(new CleanupGCCOutput()); // Fix gccisms
Passes.push_back(new InductionVariableSimplify()); // Simplify indvars
Passes.push_back(new RaisePointerReferences()); // Eliminate casts
Passes.push_back(new ConstantMerge()); // Merge dup global consts
Passes.push_back(new InstructionCombining()); // Combine silly seq's
Passes.push_back(new opt::DeadCodeElimination()); // Remove Dead code/vars
PassManager Passes;
Passes.add(new opt::DeadCodeElimination()); // Remove Dead code/vars
Passes.add(new CleanupGCCOutput()); // Fix gccisms
Passes.add(new InductionVariableSimplify()); // Simplify indvars
Passes.add(new RaisePointerReferences()); // Eliminate casts
Passes.add(new ConstantMerge()); // Merge dup global consts
Passes.add(new InstructionCombining()); // Combine silly seq's
Passes.add(new opt::DeadCodeElimination()); // Remove Dead code/vars
// Run our queue of passes all at once now, efficiently. This form of
// runAllPasses frees the Pass objects after runAllPasses completes.
//
Pass::runAllPassesAndFree(M.get(), Passes);
Passes.run(M.get());
WriteBytecodeToFile(M.get(), *Out);
return 0;

View File

@ -52,21 +52,20 @@ static inline string GetFileNameRoot(const string &InputFilename) {
// Native code generation for a specified target.
//===---------------------------------------------------------------------===//
class GenerateCodeForTarget : public Pass {
class GenerateCodeForTarget : public MethodPass {
TargetMachine &Target;
public:
inline GenerateCodeForTarget(TargetMachine &T) : Target(T) {}
// doPerMethodWork - This method does the actual work of generating code for
// runOnMethod - This method does the actual work of generating code for
// the specified method.
//
bool doPerMethodWork(Method *M) {
bool runOnMethod(Method *M) {
if (!M->isExternal() && Target.compileMethod(M)) {
cerr << "Error compiling " << InputFilename << "!\n";
return true;
}
return false;
return true;
}
};
@ -85,8 +84,7 @@ public:
inline EmitAssembly(const TargetMachine &T, std::ostream *O, bool D)
: Target(T), Out(O), DeleteStream(D) {}
virtual bool doPassFinalization(Module *M) {
virtual bool run(Module *M) {
Target.emitAssembly(M, *Out);
if (DeleteStream) delete Out;
@ -95,6 +93,7 @@ public:
};
//===---------------------------------------------------------------------===//
// Function main()
//
@ -119,18 +118,18 @@ int main(int argc, char **argv) {
}
// Build up all of the passes that we want to do to the module...
std::vector<Pass*> Passes;
PassManager Passes;
// Hoist constants out of PHI nodes into predecessor BB's
Passes.push_back(new HoistPHIConstants());
Passes.add(new HoistPHIConstants());
if (TraceBBValues || TraceMethodValues) { // If tracing enabled...
// Insert trace code in all methods in the module
Passes.push_back(new InsertTraceCode(TraceBBValues,
TraceBBValues ||TraceMethodValues));
Passes.add(new InsertTraceCode(TraceBBValues,
TraceBBValues ||TraceMethodValues));
// Eliminate duplication in constant pool
Passes.push_back(new DynamicConstantMerge());
Passes.add(new DynamicConstantMerge());
// Then write out the module with tracing code before code generation
assert(InputFilename != "-" &&
@ -152,20 +151,20 @@ int main(int argc, char **argv) {
return 1;
}
Passes.push_back(new WriteBytecodePass(os, true));
Passes.add(new WriteBytecodePass(os, true));
}
// Replace malloc and free instructions with library calls.
// Do this after tracing until lli implements these lib calls.
// For now, it will emulate malloc and free internally.
Passes.push_back(new LowerAllocations(Target.DataLayout));
Passes.add(new LowerAllocations(Target.DataLayout));
// If LLVM dumping after transformations is requested, add it to the pipeline
if (DumpAsm)
Passes.push_back(new PrintModulePass("Code after xformations: \n",&cerr));
Passes.add(new PrintMethodPass("Code after xformations: \n",&cerr));
// Generate Target code...
Passes.push_back(new GenerateCodeForTarget(Target));
Passes.add(new GenerateCodeForTarget(Target));
if (!DoNotEmitAssembly) { // If asm output is enabled...
// Figure out where we are going to send the output...
@ -203,12 +202,11 @@ int main(int argc, char **argv) {
}
// Output assembly language to the .s file
Passes.push_back(new EmitAssembly(Target, Out, Out != &std::cout));
Passes.add(new EmitAssembly(Target, Out, Out != &std::cout));
}
// Run our queue of passes all at once now, efficiently. This form of
// runAllPasses frees the Pass objects after runAllPasses completes.
Pass::runAllPassesAndFree(M.get(), Passes);
// Run our queue of passes all at once now, efficiently.
Passes.run(M.get());
return 0;
}

View File

@ -34,14 +34,13 @@ enum Opts {
indvars, instcombine, sccp, adce, raise,
// Interprocedural optimizations...
globaldce, swapstructs,
globaldce, swapstructs, sortstructs,
};
struct {
enum Opts OptID;
Pass *ThePass;
} OptTable[] = {
{ swapstructs, 0 },
{ dce , new opt::DeadCodeElimination() },
{ constprop , new opt::ConstantPropogation() },
{ inlining , new opt::MethodInlining() },
@ -55,8 +54,11 @@ struct {
{ raise , new RaisePointerReferences() },
{ trace , new InsertTraceCode(true, true) },
{ tracem , new InsertTraceCode(false, true) },
{ print , new PrintModulePass("Current Method: \n",&cerr) },
{ print , new PrintMethodPass("Current Method: \n",&cerr) },
{ cleangcc , new CleanupGCCOutput() },
{ globaldce , new GlobalDCE() },
{ swapstructs, new SimpleStructMutation(SimpleStructMutation::SwapElements) },
{ sortstructs, new SimpleStructMutation(SimpleStructMutation::SortElements) },
};
cl::String InputFilename ("", "Load <arg> file to optimize", cl::NoFlags, "-");
@ -78,6 +80,7 @@ cl::EnumList<enum Opts> OptimizationList(cl::NoFlags,
clEnumVal(globaldce , "Remove unreachable globals"),
clEnumVal(swapstructs, "Swap structure types around"),
clEnumVal(sortstructs, "Sort structure elements"),
clEnumVal(cleangcc , "Cleanup GCC Output"),
clEnumVal(raise , "Raise to Higher Level"),
@ -95,18 +98,7 @@ static void RunOptimization(Module *M, enum Opts Opt) {
return;
}
// Special cases that haven't been fit into a consistent framework yet...
switch (Opt) {
case globaldce: {
GlobalDCE GDCE; GDCE.run(M); return;
}
case swapstructs: {
PrebuiltStructMutation SM(M, PrebuiltStructMutation::SortElements);
SM.run(M); return;
}
default:
cerr << "Optimization tables inconsistent!!\n";
}
cerr << "Optimization tables inconsistent!!\n";
}
int main(int argc, char **argv) {
@ -118,6 +110,8 @@ int main(int argc, char **argv) {
return 1;
}
PassManager Passes;
// Run all of the optimizations specified on the command line
for (unsigned i = 0; i < OptimizationList.size(); ++i)
RunOptimization(M.get(), OptimizationList[i]);