2002-03-28 18:08:31 +00:00
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//===-- PoolAllocate.cpp - Pool Allocation Pass ---------------------------===//
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//
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// This transform changes programs so that disjoint data structures are
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// allocated out of different pools of memory, increasing locality and shrinking
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// pointer size.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Transforms/IPO/PoolAllocate.h"
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#include "llvm/Analysis/DataStructure.h"
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#include "llvm/Pass.h"
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2002-03-29 03:40:59 +00:00
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#include "llvm/Module.h"
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#include "llvm/Function.h"
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#include "llvm/iMemory.h"
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2002-03-29 05:50:20 +00:00
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#include "llvm/iTerminators.h"
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#include "llvm/iOther.h"
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#include "llvm/ConstantVals.h"
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#include "llvm/Target/TargetData.h"
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#include "Support/STLExtras.h"
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2002-03-29 03:40:59 +00:00
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#include <algorithm>
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2002-03-28 18:08:31 +00:00
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2002-03-29 17:13:46 +00:00
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2002-03-29 05:50:20 +00:00
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// FIXME: This is dependant on the sparc backend layout conventions!!
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static TargetData TargetData("test");
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2002-03-28 18:08:31 +00:00
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namespace {
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2002-03-29 17:13:46 +00:00
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// ScalarInfo - Information about an LLVM value that we know points to some
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// datastructure we are processing.
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//
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struct ScalarInfo {
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Value *Val; // Scalar value in Current Function
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AllocDSNode *AllocNode; // Allocation node it points to
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Value *PoolHandle; // PoolTy* LLVM value
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ScalarInfo(Value *V, AllocDSNode *AN, Value *PH)
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: Val(V), AllocNode(AN), PoolHandle(PH) {}
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};
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// TransformFunctionInfo - Information about how a function eeds to be
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// transformed.
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//
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struct TransformFunctionInfo {
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// ArgInfo - Maintain information about the arguments that need to be
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// processed. Each pair corresponds to an argument (whose number is the
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// first element) that needs to have a pool pointer (the second element)
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// passed into the transformed function with it.
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//
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// As a special case, "argument" number -1 corresponds to the return value.
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//
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vector<pair<int, Value*> > ArgInfo;
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// Func - The function to be transformed...
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Function *Func;
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// default ctor...
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TransformFunctionInfo() : Func(0) {}
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inline bool operator<(const TransformFunctionInfo &TFI) const {
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return Func < TFI.Func || (Func == TFI.Func && ArgInfo < TFI.ArgInfo);
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}
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void finalizeConstruction() {
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// Sort the vector so that the return value is first, followed by the
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// argument records, in order.
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sort(ArgInfo.begin(), ArgInfo.end());
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}
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};
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// Define the pass class that we implement...
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class PoolAllocate : public Pass {
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// PoolTy - The type of a scalar value that contains a pool pointer.
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PointerType *PoolTy;
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public:
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PoolAllocate() {
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// Initialize the PoolTy instance variable, since the type never changes.
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vector<const Type*> PoolElements;
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PoolElements.push_back(PointerType::get(Type::SByteTy));
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PoolElements.push_back(Type::UIntTy);
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PoolTy = PointerType::get(StructType::get(PoolElements));
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// PoolTy = { sbyte*, uint }*
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CurModule = 0; DS = 0;
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PoolInit = PoolDestroy = PoolAlloc = PoolFree = 0;
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}
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bool run(Module *M);
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// getAnalysisUsageInfo - This function requires data structure information
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// to be able to see what is pool allocatable.
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//
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virtual void getAnalysisUsageInfo(Pass::AnalysisSet &Required,
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2002-03-29 03:40:59 +00:00
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Pass::AnalysisSet &,Pass::AnalysisSet &) {
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Required.push_back(DataStructure::ID);
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}
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private:
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// CurModule - The module being processed.
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Module *CurModule;
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// DS - The data structure graph for the module being processed.
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DataStructure *DS;
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// Prototypes that we add to support pool allocation...
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Function *PoolInit, *PoolDestroy, *PoolAlloc, *PoolFree;
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2002-03-29 17:13:46 +00:00
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// The map of already transformed functions...
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map<TransformFunctionInfo, Function*> TransformedFunctions;
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// getTransformedFunction - Get a transformed function, or return null if
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// the function specified hasn't been transformed yet.
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//
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Function *getTransformedFunction(TransformFunctionInfo &TFI) const {
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map<TransformFunctionInfo, Function*>::const_iterator I =
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TransformedFunctions.find(TFI);
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if (I != TransformedFunctions.end()) return I->second;
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return 0;
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}
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2002-03-29 03:40:59 +00:00
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// addPoolPrototypes - Add prototypes for the pool methods to the specified
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// module and update the Pool* instance variables to point to them.
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//
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void addPoolPrototypes(Module *M);
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2002-03-29 06:21:38 +00:00
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// CreatePools - Insert instructions into the function we are processing to
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// create all of the memory pool objects themselves. This also inserts
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// destruction code. Add an alloca for each pool that is allocated to the
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// PoolDescriptors vector.
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//
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void CreatePools(Function *F, const vector<AllocDSNode*> &Allocs,
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vector<AllocaInst*> &PoolDescriptors);
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2002-03-29 03:40:59 +00:00
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// processFunction - Convert a function to use pool allocation where
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// available.
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//
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bool processFunction(Function *F);
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2002-03-29 17:13:46 +00:00
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void transformFunctionBody(Function *F, vector<ScalarInfo> &Scalars);
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// transformFunction - Transform the specified function the specified way.
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// It we have already transformed that function that way, don't do anything.
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//
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void transformFunction(TransformFunctionInfo &TFI);
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2002-03-28 18:08:31 +00:00
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};
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}
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2002-03-29 03:40:59 +00:00
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2002-03-29 17:13:46 +00:00
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// isNotPoolableAlloc - This is a predicate that returns true if the specified
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2002-03-29 03:40:59 +00:00
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// allocation node in a data structure graph is eligable for pool allocation.
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//
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static bool isNotPoolableAlloc(const AllocDSNode *DS) {
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2002-03-29 05:50:20 +00:00
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if (DS->isAllocaNode()) return true; // Do not pool allocate alloca's.
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2002-03-29 03:40:59 +00:00
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MallocInst *MI = cast<MallocInst>(DS->getAllocation());
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if (MI->isArrayAllocation() && !isa<Constant>(MI->getArraySize()))
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2002-03-29 05:50:20 +00:00
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return true; // Do not allow variable size allocations...
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2002-03-29 03:40:59 +00:00
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2002-03-29 05:50:20 +00:00
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return false;
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2002-03-29 03:40:59 +00:00
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}
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// processFunction - Convert a function to use pool allocation where
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// available.
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//
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bool PoolAllocate::processFunction(Function *F) {
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// Get the closed datastructure graph for the current function... if there are
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// any allocations in this graph that are not escaping, we need to pool
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// allocate them here!
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//
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FunctionDSGraph &IPGraph = DS->getClosedDSGraph(F);
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// Get all of the allocations that do not escape the current function. Since
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// they are still live (they exist in the graph at all), this means we must
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// have scalar references to these nodes, but the scalars are never returned.
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//
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vector<AllocDSNode*> Allocs;
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IPGraph.getNonEscapingAllocations(Allocs);
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// Filter out allocations that we cannot handle. Currently, this includes
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// variable sized array allocations and alloca's (which we do not want to
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// pool allocate)
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//
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Allocs.erase(remove_if(Allocs.begin(), Allocs.end(), isNotPoolableAlloc),
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Allocs.end());
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if (Allocs.empty()) return false; // Nothing to do.
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2002-03-29 17:13:46 +00:00
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// Insert instructions into the function we are processing to create all of
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// the memory pool objects themselves. This also inserts destruction code.
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// This fills in the PoolDescriptors vector to be a array parallel with
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// Allocs, but containing the alloca instructions that allocate the pool ptr.
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//
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vector<AllocaInst*> PoolDescriptors;
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CreatePools(F, Allocs, PoolDescriptors);
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2002-03-29 03:40:59 +00:00
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// Loop through the value map looking for scalars that refer to nonescaping
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2002-03-29 17:13:46 +00:00
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// allocations. Add them to the Scalars vector. Note that we may have
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// multiple entries in the Scalars vector for each value if it points to more
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// than one object.
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2002-03-29 03:40:59 +00:00
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//
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map<Value*, PointerValSet> &ValMap = IPGraph.getValueMap();
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2002-03-29 17:13:46 +00:00
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vector<ScalarInfo> Scalars;
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for (map<Value*, PointerValSet>::iterator I = ValMap.begin(),
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E = ValMap.end(); I != E; ++I) {
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const PointerValSet &PVS = I->second; // Set of things pointed to by scalar
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2002-03-29 17:13:46 +00:00
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assert(PVS.size() == 1 &&
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"Only handle scalars that point to one thing so far!");
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2002-03-29 03:40:59 +00:00
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// Check to see if the scalar points to anything that is an allocation...
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for (unsigned i = 0, e = PVS.size(); i != e; ++i)
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if (AllocDSNode *Alloc = dyn_cast<AllocDSNode>(PVS[i].Node)) {
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assert(PVS[i].Index == 0 && "Nonzero not handled yet!");
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// If the allocation is in the nonescaping set...
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2002-03-29 17:13:46 +00:00
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vector<AllocDSNode*>::iterator AI =
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find(Allocs.begin(), Allocs.end(), Alloc);
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if (AI != Allocs.end()) {
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unsigned IDX = AI-Allocs.begin();
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2002-03-29 03:40:59 +00:00
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// Add it to the list of scalars we have
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2002-03-29 17:13:46 +00:00
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Scalars.push_back(ScalarInfo(I->first, Alloc, PoolDescriptors[IDX]));
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}
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2002-03-29 03:40:59 +00:00
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}
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}
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2002-03-29 17:13:46 +00:00
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// Now we need to figure out what called methods we need to transform, and
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// how. To do this, we look at all of the scalars, seeing which functions are
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// either used as a scalar value (so they return a data structure), or are
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// passed one of our scalar values.
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//
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transformFunctionBody(F, Scalars);
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return true;
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}
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static void addCallInfo(TransformFunctionInfo &TFI, CallInst *CI, int Arg,
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Value *PoolHandle) {
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assert(CI->getCalledFunction() && "Cannot handle indirect calls yet!");
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TFI.ArgInfo.push_back(make_pair(Arg, PoolHandle));
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assert(TFI.Func == 0 || TFI.Func == CI->getCalledFunction() &&
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"Function call record should always call the same function!");
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TFI.Func = CI->getCalledFunction();
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}
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void PoolAllocate::transformFunctionBody(Function *F,
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vector<ScalarInfo> &Scalars) {
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cerr << "In '" << F->getName()
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<< "': Found the following values that point to poolable nodes:\n";
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for (unsigned i = 0, e = Scalars.size(); i != e; ++i)
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Scalars[i].Val->dump();
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// CallMap - Contain an entry for every call instruction that needs to be
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// transformed. Each entry in the map contains information about what we need
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// to do to each call site to change it to work.
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//
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map<CallInst*, TransformFunctionInfo> CallMap;
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// Now we need to figure out what called methods we need to transform, and
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// how. To do this, we look at all of the scalars, seeing which functions are
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// either used as a scalar value (so they return a data structure), or are
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// passed one of our scalar values.
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//
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for (unsigned i = 0, e = Scalars.size(); i != e; ++i) {
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Value *ScalarVal = Scalars[i].Val;
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// Check to see if the scalar _IS_ a call...
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if (CallInst *CI = dyn_cast<CallInst>(ScalarVal))
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// If so, add information about the pool it will be returning...
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addCallInfo(CallMap[CI], CI, -1, Scalars[i].PoolHandle);
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// Check to see if the scalar is an operand to a call...
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for (Value::use_iterator UI = ScalarVal->use_begin(),
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UE = ScalarVal->use_end(); UI != UE; ++UI) {
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if (CallInst *CI = dyn_cast<CallInst>(*UI)) {
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// Find out which operand this is to the call instruction...
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User::op_iterator OI = find(CI->op_begin(), CI->op_end(), ScalarVal);
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assert(OI != CI->op_end() && "Call on use list but not an operand!?");
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assert(OI != CI->op_begin() && "Pointer operand is call destination?");
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// FIXME: This is broken if the same pointer is passed to a call more
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// than once! It will get multiple entries for the first pointer.
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// Add the operand number and pool handle to the call table...
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addCallInfo(CallMap[CI], CI, OI-CI->op_begin(), Scalars[i].PoolHandle);
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}
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}
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}
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// Print out call map...
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for (map<CallInst*, TransformFunctionInfo>::iterator I = CallMap.begin();
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I != CallMap.end(); ++I) {
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cerr << "\nFor call: ";
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I->first->dump();
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I->second.finalizeConstruction();
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cerr << " must pass pool pointer for arg #";
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for (unsigned i = 0; i < I->second.ArgInfo.size(); ++i)
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cerr << I->second.ArgInfo[i].first << " ";
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cerr << "\n";
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}
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// Loop through all of the call nodes, recursively creating the new functions
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// that we want to call... This uses a map to prevent infinite recursion and
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// to avoid duplicating functions unneccesarily.
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//
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for (map<CallInst*, TransformFunctionInfo>::iterator I = CallMap.begin(),
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E = CallMap.end(); I != E; ++I) {
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// Make sure the entries are sorted.
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I->second.finalizeConstruction();
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transformFunction(I->second);
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}
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}
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// transformFunction - Transform the specified function the specified way.
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// It we have already transformed that function that way, don't do anything.
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//
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void PoolAllocate::transformFunction(TransformFunctionInfo &TFI) {
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if (getTransformedFunction(TFI)) return; // Function xformation already done?
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2002-03-29 05:50:20 +00:00
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2002-03-29 06:21:38 +00:00
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}
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// CreatePools - Insert instructions into the function we are processing to
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// create all of the memory pool objects themselves. This also inserts
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// destruction code. Add an alloca for each pool that is allocated to the
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// PoolDescriptors vector.
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//
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void PoolAllocate::CreatePools(Function *F, const vector<AllocDSNode*> &Allocs,
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vector<AllocaInst*> &PoolDescriptors) {
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2002-03-29 05:50:20 +00:00
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// FIXME: This should use an IP version of the UnifyAllExits pass!
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vector<BasicBlock*> ReturnNodes;
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for (Function::iterator I = F->begin(), E = F->end(); I != E; ++I)
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if (isa<ReturnInst>((*I)->getTerminator()))
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ReturnNodes.push_back(*I);
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// Create the code that goes in the entry and exit nodes for the method...
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vector<Instruction*> EntryNodeInsts;
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for (unsigned i = 0, e = Allocs.size(); i != e; ++i) {
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// Add an allocation and a free for each pool...
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AllocaInst *PoolAlloc = new AllocaInst(PoolTy, 0, "pool");
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EntryNodeInsts.push_back(PoolAlloc);
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2002-03-29 17:13:46 +00:00
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PoolDescriptors.push_back(PoolAlloc); // Keep track of pool allocas
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2002-03-29 05:50:20 +00:00
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AllocationInst *AI = Allocs[i]->getAllocation();
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// Initialize the pool. We need to know how big each allocation is. For
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// our purposes here, we assume we are allocating a scalar, or array of
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// constant size.
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//
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unsigned ElSize = TargetData.getTypeSize(AI->getAllocatedType());
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ElSize *= cast<ConstantUInt>(AI->getArraySize())->getValue();
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vector<Value*> Args;
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Args.push_back(PoolAlloc); // Pool to initialize
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Args.push_back(ConstantUInt::get(Type::UIntTy, ElSize));
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EntryNodeInsts.push_back(new CallInst(PoolInit, Args));
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// Destroy the pool...
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Args.pop_back();
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for (unsigned EN = 0, ENE = ReturnNodes.size(); EN != ENE; ++EN) {
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Instruction *Destroy = new CallInst(PoolDestroy, Args);
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// Insert it before the return instruction...
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BasicBlock *RetNode = ReturnNodes[EN];
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RetNode->getInstList().insert(RetNode->end()-1, Destroy);
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}
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}
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// Insert the entry node code into the entry block...
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F->getEntryNode()->getInstList().insert(F->getEntryNode()->begin()+1,
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EntryNodeInsts.begin(),
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EntryNodeInsts.end());
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2002-03-29 03:40:59 +00:00
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}
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// addPoolPrototypes - Add prototypes for the pool methods to the specified
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// module and update the Pool* instance variables to point to them.
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//
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void PoolAllocate::addPoolPrototypes(Module *M) {
|
2002-03-29 05:50:20 +00:00
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// Get PoolInit function...
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vector<const Type*> Args;
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Args.push_back(PoolTy); // Pool to initialize
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|
Args.push_back(Type::UIntTy); // Num bytes per element
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FunctionType *PoolInitTy = FunctionType::get(Type::VoidTy, Args, false);
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PoolInit = M->getOrInsertFunction("poolinit", PoolInitTy);
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|
// Get pooldestroy function...
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|
Args.pop_back(); // Only takes a pool...
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|
FunctionType *PoolDestroyTy = FunctionType::get(Type::VoidTy, Args, false);
|
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|
|
PoolDestroy = M->getOrInsertFunction("pooldestroy", PoolDestroyTy);
|
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|
|
const Type *PtrVoid = PointerType::get(Type::SByteTy);
|
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|
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|
|
// Get the poolalloc function...
|
|
|
|
FunctionType *PoolAllocTy = FunctionType::get(PtrVoid, Args, false);
|
|
|
|
PoolAlloc = M->getOrInsertFunction("poolalloc", PoolAllocTy);
|
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|
|
// Get the poolfree function...
|
|
|
|
Args.push_back(PtrVoid);
|
|
|
|
FunctionType *PoolFreeTy = FunctionType::get(Type::VoidTy, Args, false);
|
|
|
|
PoolFree = M->getOrInsertFunction("poolfree", PoolFreeTy);
|
|
|
|
|
|
|
|
// Add the %PoolTy type to the symbol table of the module...
|
|
|
|
M->addTypeName("PoolTy", PoolTy->getElementType());
|
2002-03-29 03:40:59 +00:00
|
|
|
}
|
|
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|
|
|
|
|
|
|
|
bool PoolAllocate::run(Module *M) {
|
|
|
|
addPoolPrototypes(M);
|
|
|
|
CurModule = M;
|
|
|
|
|
|
|
|
DS = &getAnalysis<DataStructure>();
|
|
|
|
bool Changed = false;
|
|
|
|
for (Module::iterator I = M->begin(); I != M->end(); ++I)
|
|
|
|
if (!(*I)->isExternal())
|
|
|
|
Changed |= processFunction(*I);
|
|
|
|
|
|
|
|
CurModule = 0;
|
|
|
|
DS = 0;
|
|
|
|
return false;
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
|
|
// createPoolAllocatePass - Global function to access the functionality of this
|
|
|
|
// pass...
|
|
|
|
//
|
2002-03-28 18:08:31 +00:00
|
|
|
Pass *createPoolAllocatePass() { return new PoolAllocate(); }
|