248 lines
9.5 KiB
C++
248 lines
9.5 KiB
C++
//===- AbstractCallSite.h - Abstract call sites -----------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the AbstractCallSite class, which is a is a wrapper that
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// allows treating direct, indirect, and callback calls the same.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_IR_ABSTRACTCALLSITE_H
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#define LLVM_IR_ABSTRACTCALLSITE_H
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#include "llvm/IR/Function.h"
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#include "llvm/IR/InstrTypes.h"
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#include "llvm/IR/Instruction.h"
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#include "llvm/IR/Use.h"
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#include "llvm/IR/User.h"
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#include "llvm/IR/Value.h"
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#include "llvm/Support/Casting.h"
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#include <cassert>
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namespace llvm {
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/// AbstractCallSite
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///
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/// An abstract call site is a wrapper that allows to treat direct,
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/// indirect, and callback calls the same. If an abstract call site
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/// represents a direct or indirect call site it behaves like a stripped
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/// down version of a normal call site object. The abstract call site can
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/// also represent a callback call, thus the fact that the initially
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/// called function (=broker) may invoke a third one (=callback callee).
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/// In this case, the abstract call site hides the middle man, hence the
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/// broker function. The result is a representation of the callback call,
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/// inside the broker, but in the context of the original call to the broker.
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///
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/// There are up to three functions involved when we talk about callback call
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/// sites. The caller (1), which invokes the broker function. The broker
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/// function (2), that will invoke the callee zero or more times. And finally
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/// the callee (3), which is the target of the callback call.
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///
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/// The abstract call site will handle the mapping from parameters to arguments
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/// depending on the semantic of the broker function. However, it is important
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/// to note that the mapping is often partial. Thus, some arguments of the
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/// call/invoke instruction are mapped to parameters of the callee while others
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/// are not.
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class AbstractCallSite {
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public:
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/// The encoding of a callback with regards to the underlying instruction.
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struct CallbackInfo {
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/// For direct/indirect calls the parameter encoding is empty. If it is not,
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/// the abstract call site represents a callback. In that case, the first
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/// element of the encoding vector represents which argument of the call
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/// site CB is the callback callee. The remaining elements map parameters
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/// (identified by their position) to the arguments that will be passed
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/// through (also identified by position but in the call site instruction).
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///
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/// NOTE that we use LLVM argument numbers (starting at 0) and not
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/// clang/source argument numbers (starting at 1). The -1 entries represent
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/// unknown values that are passed to the callee.
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using ParameterEncodingTy = SmallVector<int, 0>;
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ParameterEncodingTy ParameterEncoding;
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};
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private:
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/// The underlying call site:
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/// caller -> callee, if this is a direct or indirect call site
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/// caller -> broker function, if this is a callback call site
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CallBase *CB;
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/// The encoding of a callback with regards to the underlying instruction.
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CallbackInfo CI;
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public:
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/// Sole constructor for abstract call sites (ACS).
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///
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/// An abstract call site can only be constructed through a llvm::Use because
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/// each operand (=use) of an instruction could potentially be a different
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/// abstract call site. Furthermore, even if the value of the llvm::Use is the
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/// same, and the user is as well, the abstract call sites might not be.
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///
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/// If a use is not associated with an abstract call site the constructed ACS
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/// will evaluate to false if converted to a boolean.
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///
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/// If the use is the callee use of a call or invoke instruction, the
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/// constructed abstract call site will behave as a llvm::CallSite would.
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///
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/// If the use is not a callee use of a call or invoke instruction, the
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/// callback metadata is used to determine the argument <-> parameter mapping
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/// as well as the callee of the abstract call site.
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AbstractCallSite(const Use *U);
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/// Add operand uses of \p CB that represent callback uses into
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/// \p CallbackUses.
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///
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/// All uses added to \p CallbackUses can be used to create abstract call
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/// sites for which AbstractCallSite::isCallbackCall() will return true.
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static void getCallbackUses(const CallBase &CB,
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SmallVectorImpl<const Use *> &CallbackUses);
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/// Conversion operator to conveniently check for a valid/initialized ACS.
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explicit operator bool() const { return CB != nullptr; }
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/// Return the underlying instruction.
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CallBase *getInstruction() const { return CB; }
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/// Return true if this ACS represents a direct call.
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bool isDirectCall() const {
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return !isCallbackCall() && !CB->isIndirectCall();
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}
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/// Return true if this ACS represents an indirect call.
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bool isIndirectCall() const {
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return !isCallbackCall() && CB->isIndirectCall();
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}
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/// Return true if this ACS represents a callback call.
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bool isCallbackCall() const {
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// For a callback call site the callee is ALWAYS stored first in the
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// transitive values vector. Thus, a non-empty vector indicates a callback.
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return !CI.ParameterEncoding.empty();
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}
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/// Return true if @p UI is the use that defines the callee of this ACS.
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bool isCallee(Value::const_user_iterator UI) const {
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return isCallee(&UI.getUse());
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}
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/// Return true if @p U is the use that defines the callee of this ACS.
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bool isCallee(const Use *U) const {
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if (isDirectCall())
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return CB->isCallee(U);
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assert(!CI.ParameterEncoding.empty() &&
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"Callback without parameter encoding!");
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// If the use is actually in a constant cast expression which itself
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// has only one use, we look through the constant cast expression.
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if (auto *CE = dyn_cast<ConstantExpr>(U->getUser()))
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if (CE->hasOneUse() && CE->isCast())
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U = &*CE->use_begin();
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return (int)CB->getArgOperandNo(U) == CI.ParameterEncoding[0];
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}
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/// Return the number of parameters of the callee.
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unsigned getNumArgOperands() const {
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if (isDirectCall())
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return CB->getNumArgOperands();
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// Subtract 1 for the callee encoding.
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return CI.ParameterEncoding.size() - 1;
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}
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/// Return the operand index of the underlying instruction associated with @p
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/// Arg.
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int getCallArgOperandNo(Argument &Arg) const {
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return getCallArgOperandNo(Arg.getArgNo());
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}
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/// Return the operand index of the underlying instruction associated with
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/// the function parameter number @p ArgNo or -1 if there is none.
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int getCallArgOperandNo(unsigned ArgNo) const {
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if (isDirectCall())
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return ArgNo;
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// Add 1 for the callee encoding.
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return CI.ParameterEncoding[ArgNo + 1];
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}
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/// Return the operand of the underlying instruction associated with @p Arg.
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Value *getCallArgOperand(Argument &Arg) const {
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return getCallArgOperand(Arg.getArgNo());
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}
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/// Return the operand of the underlying instruction associated with the
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/// function parameter number @p ArgNo or nullptr if there is none.
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Value *getCallArgOperand(unsigned ArgNo) const {
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if (isDirectCall())
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return CB->getArgOperand(ArgNo);
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// Add 1 for the callee encoding.
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return CI.ParameterEncoding[ArgNo + 1] >= 0
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? CB->getArgOperand(CI.ParameterEncoding[ArgNo + 1])
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: nullptr;
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}
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/// Return the operand index of the underlying instruction associated with the
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/// callee of this ACS. Only valid for callback calls!
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int getCallArgOperandNoForCallee() const {
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assert(isCallbackCall());
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assert(CI.ParameterEncoding.size() && CI.ParameterEncoding[0] >= 0);
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return CI.ParameterEncoding[0];
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}
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/// Return the use of the callee value in the underlying instruction. Only
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/// valid for callback calls!
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const Use &getCalleeUseForCallback() const {
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int CalleeArgIdx = getCallArgOperandNoForCallee();
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assert(CalleeArgIdx >= 0 &&
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unsigned(CalleeArgIdx) < getInstruction()->getNumOperands());
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return getInstruction()->getOperandUse(CalleeArgIdx);
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}
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/// Return the pointer to function that is being called.
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Value *getCalledOperand() const {
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if (isDirectCall())
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return CB->getCalledOperand();
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return CB->getArgOperand(getCallArgOperandNoForCallee());
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}
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/// Return the function being called if this is a direct call, otherwise
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/// return null (if it's an indirect call).
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Function *getCalledFunction() const {
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Value *V = getCalledOperand();
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return V ? dyn_cast<Function>(V->stripPointerCasts()) : nullptr;
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}
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};
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/// Apply function Func to each CB's callback call site.
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template <typename UnaryFunction>
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void forEachCallbackCallSite(const CallBase &CB, UnaryFunction Func) {
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SmallVector<const Use *, 4u> CallbackUses;
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AbstractCallSite::getCallbackUses(CB, CallbackUses);
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for (const Use *U : CallbackUses) {
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AbstractCallSite ACS(U);
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assert(ACS && ACS.isCallbackCall() && "must be a callback call");
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Func(ACS);
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}
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}
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/// Apply function Func to each CB's callback function.
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template <typename UnaryFunction>
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void forEachCallbackFunction(const CallBase &CB, UnaryFunction Func) {
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forEachCallbackCallSite(CB, [&Func](AbstractCallSite &ACS) {
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if (Function *Callback = ACS.getCalledFunction())
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Func(Callback);
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});
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}
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} // end namespace llvm
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#endif // LLVM_IR_ABSTRACTCALLSITE_H
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