llvm-project/llvm/lib/Transforms/IPO/SimplifyLibCalls.cpp

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//===- SimplifyLibCalls.cpp - Optimize specific well-known library calls --===//
//
// The LLVM Compiler Infrastructure
//
// This file was developed by Reid Spencer and is distributed under the
// University of Illinois Open Source License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements a variety of small optimizations for calls to specific
// well-known (e.g. runtime library) function calls. For example, a call to the
// function "exit(3)" that occurs within the main() function can be transformed
// into a simple "return 3" instruction. Any optimization that takes this form
// (replace call to library function with simpler code that provides same
// result) belongs in this file.
//
//===----------------------------------------------------------------------===//
#define DEBUG_TYPE "simplify-libcalls"
#include "llvm/Constants.h"
#include "llvm/DerivedTypes.h"
#include "llvm/Instructions.h"
#include "llvm/Module.h"
#include "llvm/Pass.h"
#include "llvm/ADT/hash_map"
#include "llvm/ADT/Statistic.h"
#include "llvm/Support/Debug.h"
#include "llvm/Target/TargetData.h"
#include "llvm/Transforms/IPO.h"
#include <iostream>
using namespace llvm;
namespace {
Statistic<> SimplifiedLibCalls("simplified-lib-calls",
"Number of well-known library calls simplified");
/// This class is the base class for a set of small but important
/// optimizations of calls to well-known functions, such as those in the c
/// library. This class provides the basic infrastructure for handling
/// runOnModule. Subclasses register themselves and provide two methods:
/// RecognizeCall and OptimizeCall. Whenever this class finds a function call,
/// it asks the subclasses to recognize the call. If it is recognized, then
/// the OptimizeCall method is called on that subclass instance. In this way
/// the subclasses implement the calling conditions on which they trigger and
/// the action to perform, making it easy to add new optimizations of this
/// form.
/// @brief A ModulePass for optimizing well-known function calls
struct SimplifyLibCalls : public ModulePass {
/// We need some target data for accurate signature details that are
/// target dependent. So we require target data in our AnalysisUsage.
virtual void getAnalysisUsage(AnalysisUsage& Info) const;
/// For this pass, process all of the function calls in the module, calling
/// RecognizeCall and OptimizeCall as appropriate.
virtual bool runOnModule(Module &M);
};
RegisterOpt<SimplifyLibCalls>
X("simplify-libcalls","Simplify well-known library calls");
struct CallOptimizer
{
/// @brief Constructor that registers the optimization
CallOptimizer(const char * fname );
virtual ~CallOptimizer();
/// The implementation of this function in subclasses should determine if
/// \p F is suitable for the optimization. This method is called by
/// runOnModule to short circuit visiting all the call sites of such a
/// function if that function is not suitable in the first place.
/// If the called function is suitabe, this method should return true;
/// false, otherwise. This function should also perform any lazy
/// initialization that the CallOptimizer needs to do, if its to return
/// true. This avoids doing initialization until the optimizer is actually
/// going to be called upon to do some optimization.
virtual bool ValidateCalledFunction(
const Function* F, ///< The function that is the target of call sites
const TargetData& TD ///< Information about the target
) = 0;
/// The implementations of this function in subclasses is the heart of the
/// SimplifyLibCalls algorithm. Sublcasses of this class implement
/// OptimizeCall to determine if (a) the conditions are right for optimizing
/// the call and (b) to perform the optimization. If an action is taken
/// against ci, the subclass is responsible for returning true and ensuring
/// that ci is erased from its parent.
/// @param ci the call instruction under consideration
/// @param f the function that ci calls.
/// @brief Optimize a call, if possible.
virtual bool OptimizeCall(
CallInst* ci, ///< The call instruction that should be optimized.
const TargetData& TD ///< Information about the target
) = 0;
const char * getFunctionName() const { return func_name; }
#ifndef NDEBUG
void activate() { ++activations; }
#endif
private:
const char* func_name;
#ifndef NDEBUG
std::string stat_name;
Statistic<> activations;
#endif
};
/// @brief The list of optimizations deriving from CallOptimizer
hash_map<std::string,CallOptimizer*> optlist;
CallOptimizer::CallOptimizer(const char* fname)
: func_name(fname)
#ifndef NDEBUG
, stat_name(std::string("simplify-libcalls:")+fname)
, activations(stat_name.c_str(),"Number of calls simplified")
#endif
{
// Register this call optimizer
optlist[func_name] = this;
}
/// Make sure we get our virtual table in this file.
CallOptimizer::~CallOptimizer() { }
}
ModulePass *llvm::createSimplifyLibCallsPass()
{
return new SimplifyLibCalls();
}
void SimplifyLibCalls::getAnalysisUsage(AnalysisUsage& Info) const
{
// Ask that the TargetData analysis be performed before us so we can use
// the target data.
Info.addRequired<TargetData>();
}
bool SimplifyLibCalls::runOnModule(Module &M)
{
TargetData& TD = getAnalysis<TargetData>();
bool result = false;
// The call optimizations can be recursive. That is, the optimization might
// generate a call to another function which can also be optimized. This way
// we make the CallOptimizer instances very specific to the case they handle.
// It also means we need to keep running over the function calls in the module
// until we don't get any more optimizations possible.
bool found_optimization = false;
do
{
found_optimization = false;
for (Module::iterator FI = M.begin(), FE = M.end(); FI != FE; ++FI)
{
// All the "well-known" functions are external and have external linkage
// because they live in a runtime library somewhere and were (probably)
// not compiled by LLVM. So, we only act on external functions that have
// external linkage and non-empty uses.
if (!FI->isExternal() || !FI->hasExternalLinkage() || FI->use_empty())
continue;
// Get the optimization class that pertains to this function
CallOptimizer* CO = optlist[FI->getName().c_str()];
if (!CO)
continue;
// Make sure the called function is suitable for the optimization
if (!CO->ValidateCalledFunction(FI,TD))
continue;
// Loop over each of the uses of the function
for (Value::use_iterator UI = FI->use_begin(), UE = FI->use_end();
UI != UE ; )
{
// If the use of the function is a call instruction
if (CallInst* CI = dyn_cast<CallInst>(*UI++))
{
// Do the optimization on the CallOptimizer.
if (CO->OptimizeCall(CI,TD))
{
++SimplifiedLibCalls;
found_optimization = result = true;
#ifndef NDEBUG
CO->activate();
#endif
}
}
}
}
} while (found_optimization);
return result;
}
namespace {
/// Provide some functions for accessing standard library prototypes and
/// caching them so we don't have to keep recomputing them
FunctionType* get_strlen(const Type* IntPtrTy)
{
static FunctionType* strlen_type = 0;
if (!strlen_type)
{
std::vector<const Type*> args;
args.push_back(PointerType::get(Type::SByteTy));
strlen_type = FunctionType::get(IntPtrTy, args, false);
}
return strlen_type;
}
FunctionType* get_memcpy()
{
static FunctionType* memcpy_type = 0;
if (!memcpy_type)
{
// Note: this is for llvm.memcpy intrinsic
std::vector<const Type*> args;
args.push_back(PointerType::get(Type::SByteTy));
args.push_back(PointerType::get(Type::SByteTy));
args.push_back(Type::IntTy);
args.push_back(Type::IntTy);
memcpy_type = FunctionType::get(Type::VoidTy, args, false);
}
return memcpy_type;
}
/// A function to compute the length of a null-terminated string of integers.
/// This function can't rely on the size of the constant array because there
/// could be a null terminator in the middle of the array. We also have to
/// bail out if we find a non-integer constant initializer of one of the
/// elements or if there is no null-terminator. The logic below checks
bool getConstantStringLength(Value* V, uint64_t& len )
{
assert(V != 0 && "Invalid args to getConstantStringLength");
len = 0; // make sure we initialize this
User* GEP = 0;
// If the value is not a GEP instruction nor a constant expression with a
// GEP instruction, then return false because ConstantArray can't occur
// any other way
if (GetElementPtrInst* GEPI = dyn_cast<GetElementPtrInst>(V))
GEP = GEPI;
else if (ConstantExpr* CE = dyn_cast<ConstantExpr>(V))
if (CE->getOpcode() == Instruction::GetElementPtr)
GEP = CE;
else
return false;
else
return false;
// Make sure the GEP has exactly three arguments.
if (GEP->getNumOperands() != 3)
return false;
// Check to make sure that the first operand of the GEP is an integer and
// has value 0 so that we are sure we're indexing into the initializer.
if (ConstantInt* op1 = dyn_cast<ConstantInt>(GEP->getOperand(1)))
{
if (!op1->isNullValue())
return false;
}
else
return false;
// Ensure that the second operand is a ConstantInt. If it isn't then this
// GEP is wonky and we're not really sure what were referencing into and
// better of not optimizing it. While we're at it, get the second index
// value. We'll need this later for indexing the ConstantArray.
uint64_t start_idx = 0;
if (ConstantInt* CI = dyn_cast<ConstantInt>(GEP->getOperand(2)))
start_idx = CI->getRawValue();
else
return false;
// The GEP instruction, constant or instruction, must reference a global
// variable that is a constant and is initialized. The referenced constant
// initializer is the array that we'll use for optimization.
GlobalVariable* GV = dyn_cast<GlobalVariable>(GEP->getOperand(0));
if (!GV || !GV->isConstant() || !GV->hasInitializer())
return false;
// Get the initializer.
Constant* INTLZR = GV->getInitializer();
// Handle the ConstantAggregateZero case
if (ConstantAggregateZero* CAZ = dyn_cast<ConstantAggregateZero>(INTLZR))
{
// This is a degenerate case. The initializer is constant zero so the
// length of the string must be zero.
len = 0;
return true;
}
// Must be a Constant Array
ConstantArray* A = dyn_cast<ConstantArray>(INTLZR);
if (!A)
return false;
// Get the number of elements in the array
uint64_t max_elems = A->getType()->getNumElements();
// Traverse the constant array from start_idx (derived above) which is
// the place the GEP refers to in the array.
for ( len = start_idx; len < max_elems; len++)
{
if (ConstantInt* CI = dyn_cast<ConstantInt>(A->getOperand(len)))
{
// Check for the null terminator
if (CI->isNullValue())
break; // we found end of string
}
else
return false; // This array isn't suitable, non-int initializer
}
if (len >= max_elems)
return false; // This array isn't null terminated
// Subtract out the initial value from the length
len -= start_idx;
return true; // success!
}
/// This CallOptimizer will find instances of a call to "exit" that occurs
/// within the "main" function and change it to a simple "ret" instruction with
/// the same value as passed to the exit function. It assumes that the
/// instructions after the call to exit(3) can be deleted since they are
/// unreachable anyway.
/// @brief Replace calls to exit in main with a simple return
struct ExitInMainOptimization : public CallOptimizer
{
ExitInMainOptimization() : CallOptimizer("exit") {}
virtual ~ExitInMainOptimization() {}
// Make sure the called function looks like exit (int argument, int return
// type, external linkage, not varargs).
virtual bool ValidateCalledFunction(const Function* f, const TargetData& TD)
{
if (f->arg_size() >= 1)
if (f->arg_begin()->getType()->isInteger())
return true;
return false;
}
virtual bool OptimizeCall(CallInst* ci, const TargetData& TD)
{
// To be careful, we check that the call to exit is coming from "main", that
// main has external linkage, and the return type of main and the argument
// to exit have the same type.
Function *from = ci->getParent()->getParent();
if (from->hasExternalLinkage())
if (from->getReturnType() == ci->getOperand(1)->getType())
if (from->getName() == "main")
{
// Okay, time to actually do the optimization. First, get the basic
// block of the call instruction
BasicBlock* bb = ci->getParent();
// Create a return instruction that we'll replace the call with.
// Note that the argument of the return is the argument of the call
// instruction.
ReturnInst* ri = new ReturnInst(ci->getOperand(1), ci);
// Split the block at the call instruction which places it in a new
// basic block.
bb->splitBasicBlock(ci);
// The block split caused a branch instruction to be inserted into
// the end of the original block, right after the return instruction
// that we put there. That's not a valid block, so delete the branch
// instruction.
bb->getInstList().pop_back();
// Now we can finally get rid of the call instruction which now lives
// in the new basic block.
ci->eraseFromParent();
// Optimization succeeded, return true.
return true;
}
// We didn't pass the criteria for this optimization so return false
return false;
}
} ExitInMainOptimizer;
/// This CallOptimizer will simplify a call to the strcat library function. The
/// simplification is possible only if the string being concatenated is a
/// constant array or a constant expression that results in a constant array. In
/// this case, if the array is small, we can generate a series of inline store
/// instructions to effect the concatenation without calling strcat.
/// @brief Simplify the strcat library function.
struct StrCatOptimization : public CallOptimizer
{
private:
Function* strlen_func;
Function* memcpy_func;
public:
StrCatOptimization()
: CallOptimizer("strcat")
, strlen_func(0)
, memcpy_func(0)
{}
virtual ~StrCatOptimization() {}
inline Function* get_strlen_func(Module*M,const Type* IntPtrTy)
{
if (strlen_func)
return strlen_func;
return strlen_func = M->getOrInsertFunction("strlen",get_strlen(IntPtrTy));
}
inline Function* get_memcpy_func(Module* M)
{
if (memcpy_func)
return memcpy_func;
return memcpy_func = M->getOrInsertFunction("llvm.memcpy",get_memcpy());
}
/// @brief Make sure that the "strcat" function has the right prototype
virtual bool ValidateCalledFunction(const Function* f, const TargetData& TD)
{
if (f->getReturnType() == PointerType::get(Type::SByteTy))
if (f->arg_size() == 2)
{
Function::const_arg_iterator AI = f->arg_begin();
if (AI++->getType() == PointerType::get(Type::SByteTy))
if (AI->getType() == PointerType::get(Type::SByteTy))
{
// Invalidate the pre-computed strlen_func and memcpy_func Functions
// because, by definition, this method is only called when a new
// Module is being traversed. Invalidation causes re-computation for
// the new Module (if necessary).
strlen_func = 0;
memcpy_func = 0;
// Indicate this is a suitable call type.
return true;
}
}
return false;
}
/// Perform the optimization if the length of the string concatenated
/// is reasonably short and it is a constant array.
virtual bool OptimizeCall(CallInst* ci, const TargetData& TD)
{
// Extract the initializer (while making numerous checks) from the
// source operand of the call to strcat. If we get null back, one of
// a variety of checks in get_GVInitializer failed
uint64_t len = 0;
if (!getConstantStringLength(ci->getOperand(2),len))
return false;
// Handle the simple, do-nothing case
if (len == 0)
{
ci->replaceAllUsesWith(ci->getOperand(1));
ci->eraseFromParent();
return true;
}
// Increment the length because we actually want to memcpy the null
// terminator as well.
len++;
// Extract some information from the instruction
Module* M = ci->getParent()->getParent()->getParent();
// We need to find the end of the destination string. That's where the
// memory is to be moved to. We just generate a call to strlen (further
// optimized in another pass). Note that the get_strlen_func() call
// caches the Function* for us.
CallInst* strlen_inst =
new CallInst(get_strlen_func(M,TD.getIntPtrType()),
ci->getOperand(1),"",ci);
// Now that we have the destination's length, we must index into the
// destination's pointer to get the actual memcpy destination (end of
// the string .. we're concatenating).
std::vector<Value*> idx;
idx.push_back(strlen_inst);
GetElementPtrInst* gep =
new GetElementPtrInst(ci->getOperand(1),idx,"",ci);
// We have enough information to now generate the memcpy call to
// do the concatenation for us.
std::vector<Value*> vals;
vals.push_back(gep); // destination
vals.push_back(ci->getOperand(2)); // source
vals.push_back(ConstantSInt::get(Type::IntTy,len)); // length
vals.push_back(ConstantSInt::get(Type::IntTy,1)); // alignment
CallInst* memcpy_inst = new CallInst(get_memcpy_func(M), vals, "", ci);
// Finally, substitute the first operand of the strcat call for the
// strcat call itself since strcat returns its first operand; and,
// kill the strcat CallInst.
ci->replaceAllUsesWith(ci->getOperand(1));
ci->eraseFromParent();
return true;
}
} StrCatOptimizer;
/// This CallOptimizer will simplify a call to the strlen library function by
/// replacing it with a constant value if the string provided to it is a
/// constant array.
/// @brief Simplify the strlen library function.
struct StrLenOptimization : public CallOptimizer
{
StrLenOptimization() : CallOptimizer("strlen") {}
virtual ~StrLenOptimization() {}
/// @brief Make sure that the "strlen" function has the right prototype
virtual bool ValidateCalledFunction(const Function* f, const TargetData& TD)
{
if (f->getReturnType() == TD.getIntPtrType())
if (f->arg_size() == 1)
if (Function::const_arg_iterator AI = f->arg_begin())
if (AI->getType() == PointerType::get(Type::SByteTy))
return true;
return false;
}
/// @brief Perform the strlen optimization
virtual bool OptimizeCall(CallInst* ci, const TargetData& TD)
{
// Get the length of the string
uint64_t len = 0;
if (!getConstantStringLength(ci->getOperand(1),len))
return false;
ci->replaceAllUsesWith(ConstantInt::get(TD.getIntPtrType(),len));
ci->eraseFromParent();
return true;
}
} StrLenOptimizer;
/// This CallOptimizer will simplify a call to the memcpy library function by
/// expanding it out to a small set of stores if the copy source is a constant
/// array.
/// @brief Simplify the memcpy library function.
struct MemCpyOptimization : public CallOptimizer
{
MemCpyOptimization() : CallOptimizer("llvm.memcpy") {}
protected:
MemCpyOptimization(const char* fname) : CallOptimizer(fname) {}
public:
virtual ~MemCpyOptimization() {}
/// @brief Make sure that the "memcpy" function has the right prototype
virtual bool ValidateCalledFunction(const Function* f, const TargetData& TD)
{
// Just make sure this has 4 arguments per LLVM spec.
return (f->arg_size() == 4);
}
/// Because of alignment and instruction information that we don't have, we
/// leave the bulk of this to the code generators. The optimization here just
/// deals with a few degenerate cases where the length of the string and the
/// alignment match the sizes of our intrinsic types so we can do a load and
/// store instead of the memcpy call.
/// @brief Perform the memcpy optimization.
virtual bool OptimizeCall(CallInst* ci, const TargetData& TD)
{
// Make sure we have constant int values to work with
ConstantInt* LEN = dyn_cast<ConstantInt>(ci->getOperand(3));
if (!LEN)
return false;
ConstantInt* ALIGN = dyn_cast<ConstantInt>(ci->getOperand(4));
if (!ALIGN)
return false;
// If the length is larger than the alignment, we can't optimize
uint64_t len = LEN->getRawValue();
uint64_t alignment = ALIGN->getRawValue();
if (len > alignment)
return false;
Value* dest = ci->getOperand(1);
Value* src = ci->getOperand(2);
CastInst* SrcCast = 0;
CastInst* DestCast = 0;
switch (len)
{
case 0:
// The memcpy is a no-op so just dump its call.
ci->eraseFromParent();
return true;
case 1:
SrcCast = new CastInst(src,PointerType::get(Type::SByteTy),"",ci);
DestCast = new CastInst(dest,PointerType::get(Type::SByteTy),"",ci);
break;
case 2:
SrcCast = new CastInst(src,PointerType::get(Type::ShortTy),"",ci);
DestCast = new CastInst(dest,PointerType::get(Type::ShortTy),"",ci);
break;
case 4:
SrcCast = new CastInst(src,PointerType::get(Type::IntTy),"",ci);
DestCast = new CastInst(dest,PointerType::get(Type::IntTy),"",ci);
break;
case 8:
SrcCast = new CastInst(src,PointerType::get(Type::LongTy),"",ci);
DestCast = new CastInst(dest,PointerType::get(Type::LongTy),"",ci);
break;
default:
return false;
}
LoadInst* LI = new LoadInst(SrcCast,"",ci);
StoreInst* SI = new StoreInst(LI, DestCast, ci);
ci->eraseFromParent();
return true;
}
} MemCpyOptimizer;
/// This CallOptimizer will simplify a call to the memmove library function. It
/// is identical to MemCopyOptimization except for the name of the intrinsic.
/// @brief Simplify the memmove library function.
struct MemMoveOptimization : public MemCpyOptimization
{
MemMoveOptimization() : MemCpyOptimization("llvm.memmove") {}
} MemMoveOptimizer;
}