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| //===-- IRForTarget.h ---------------------------------------------*- C++
//-*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#ifndef liblldb_IRForTarget_h_
#define liblldb_IRForTarget_h_
#include "lldb/Core/ClangForward.h"
#include "lldb/Symbol/TaggedASTType.h"
#include "lldb/Utility/ConstString.h"
#include "lldb/Utility/Status.h"
#include "lldb/Utility/Stream.h"
#include "lldb/Utility/StreamString.h"
#include "lldb/lldb-public.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/Pass.h"
#include <functional>
#include <map>
namespace llvm {
class BasicBlock;
class CallInst;
class Constant;
class ConstantInt;
class Function;
class GlobalValue;
class GlobalVariable;
class Instruction;
class Module;
class StoreInst;
class DataLayout;
class Value;
}
namespace lldb_private {
class ClangExpressionDeclMap;
class IRExecutionUnit;
class IRMemoryMap;
}
/// \class IRForTarget IRForTarget.h "lldb/Expression/IRForTarget.h"
/// Transforms the IR for a function to run in the target
///
/// Once an expression has been parsed and converted to IR, it can run in two
/// contexts: interpreted by LLDB as a DWARF location expression, or compiled
/// by the JIT and inserted into the target process for execution.
///
/// IRForTarget makes the second possible, by applying a series of
/// transformations to the IR which make it relocatable. These
/// transformations are discussed in more detail next to their relevant
/// functions.
class IRForTarget : public llvm::ModulePass {
public:
enum class LookupResult { Success, Fail, Ignore };
/// Constructor
///
/// \param[in] decl_map
/// The list of externally-referenced variables for the expression,
/// for use in looking up globals and allocating the argument
/// struct. See the documentation for ClangExpressionDeclMap.
///
/// \param[in] resolve_vars
/// True if the external variable references (including persistent
/// variables) should be resolved. If not, only external functions
/// are resolved.
///
/// \param[in] execution_policy
/// Determines whether an IR interpreter can be used to statically
/// evaluate the expression.
///
/// \param[in] const_result
/// This variable is populated with the statically-computed result
/// of the function, if it has no side-effects and the result can
/// be computed statically.
///
/// \param[in] execution_unit
/// The holder for raw data associated with the expression.
///
/// \param[in] error_stream
/// If non-NULL, a stream on which errors can be printed.
///
/// \param[in] func_name
/// The name of the function to prepare for execution in the target.
IRForTarget(lldb_private::ClangExpressionDeclMap *decl_map, bool resolve_vars,
lldb_private::IRExecutionUnit &execution_unit,
lldb_private::Stream &error_stream,
const char *func_name = "$__lldb_expr");
/// Destructor
~IRForTarget() override;
/// Run this IR transformer on a single module
///
/// Implementation of the llvm::ModulePass::runOnModule() function.
///
/// \param[in] llvm_module
/// The module to run on. This module is searched for the function
/// $__lldb_expr, and that function is passed to the passes one by
/// one.
///
/// \param[in] interpreter_error
/// An error. If the expression fails to be interpreted, this error
/// is set to a reason why.
///
/// \return
/// True on success; false otherwise
bool runOnModule(llvm::Module &llvm_module) override;
/// Interface stub
///
/// Implementation of the llvm::ModulePass::assignPassManager() function.
void assignPassManager(llvm::PMStack &pass_mgr_stack,
llvm::PassManagerType pass_mgr_type =
llvm::PMT_ModulePassManager) override;
/// Returns PMT_ModulePassManager
///
/// Implementation of the llvm::ModulePass::getPotentialPassManagerType()
/// function.
llvm::PassManagerType getPotentialPassManagerType() const override;
private:
/// Ensures that the current function's linkage is set to external.
/// Otherwise the JIT may not return an address for it.
///
/// \param[in] llvm_function
/// The function whose linkage is to be fixed.
///
/// \return
/// True on success; false otherwise.
bool FixFunctionLinkage(llvm::Function &llvm_function);
/// A module-level pass to replace all function pointers with their
/// integer equivalents.
/// The top-level pass implementation
///
/// \param[in] llvm_module
/// The module currently being processed.
///
/// \param[in] llvm_function
/// The function currently being processed.
///
/// \return
/// True on success; false otherwise.
bool HasSideEffects(llvm::Function &llvm_function);
/// A function-level pass to check whether the function has side
/// effects.
/// Get the address of a function, and a location to put the complete Value
/// of the function if one is available.
///
/// \param[in] function
/// The function to find the location of.
///
/// \param[out] ptr
/// The location of the function in the target.
///
/// \param[out] name
/// The resolved name of the function (matters for intrinsics).
///
/// \param[out] value_ptr
/// A variable to put the function's completed Value* in, or NULL
/// if the Value* shouldn't be stored anywhere.
///
/// \return
/// The pointer.
LookupResult GetFunctionAddress(llvm::Function *function, uint64_t &ptr,
lldb_private::ConstString &name,
llvm::Constant **&value_ptr);
/// A function-level pass to take the generated global value
/// $__lldb_expr_result and make it into a persistent variable. Also see
/// ASTResultSynthesizer.
/// Find the NamedDecl corresponding to a Value. This interface is exposed
/// for the IR interpreter.
///
/// \param[in] module
/// The module containing metadata to search
///
/// \param[in] global
/// The global entity to search for
///
/// \return
/// The corresponding variable declaration
public:
static clang::NamedDecl *DeclForGlobal(const llvm::GlobalValue *global_val,
llvm::Module *module);
private:
clang::NamedDecl *DeclForGlobal(llvm::GlobalValue *global);
/// Set the constant result variable m_const_result to the provided
/// constant, assuming it can be evaluated. The result variable will be
/// reset to NULL later if the expression has side effects.
///
/// \param[in] initializer
/// The constant initializer for the variable.
///
/// \param[in] name
/// The name of the result variable.
///
/// \param[in] type
/// The Clang type of the result variable.
void MaybeSetConstantResult(llvm::Constant *initializer,
lldb_private::ConstString name,
lldb_private::TypeFromParser type);
/// If the IR represents a cast of a variable, set m_const_result to the
/// result of the cast. The result variable will be reset to
/// NULL latger if the expression has side effects.
///
/// \param[in] type
/// The Clang type of the result variable.
void MaybeSetCastResult(lldb_private::TypeFromParser type);
/// The top-level pass implementation
///
/// \param[in] llvm_function
/// The function currently being processed.
///
/// \return
/// True on success; false otherwise
bool CreateResultVariable(llvm::Function &llvm_function);
/// A module-level pass to find Objective-C constant strings and
/// transform them to calls to CFStringCreateWithBytes.
/// Rewrite a single Objective-C constant string.
///
/// \param[in] NSStr
/// The constant NSString to be transformed
///
/// \param[in] CStr
/// The constant C string inside the NSString. This will be
/// passed as the bytes argument to CFStringCreateWithBytes.
///
/// \return
/// True on success; false otherwise
bool RewriteObjCConstString(llvm::GlobalVariable *NSStr,
llvm::GlobalVariable *CStr);
/// The top-level pass implementation
///
/// \return
/// True on success; false otherwise
bool RewriteObjCConstStrings();
/// A basic block-level pass to find all Objective-C method calls and
/// rewrite them to use sel_registerName instead of statically allocated
/// selectors. The reason is that the selectors are created on the
/// assumption that the Objective-C runtime will scan the appropriate
/// section and prepare them. This doesn't happen when code is copied into
/// the target, though, and there's no easy way to induce the runtime to
/// scan them. So instead we get our selectors from sel_registerName.
/// Replace a single selector reference
///
/// \param[in] selector_load
/// The load of the statically-allocated selector.
///
/// \return
/// True on success; false otherwise
bool RewriteObjCSelector(llvm::Instruction *selector_load);
/// The top-level pass implementation
///
/// \param[in] basic_block
/// The basic block currently being processed.
///
/// \return
/// True on success; false otherwise
bool RewriteObjCSelectors(llvm::BasicBlock &basic_block);
/// A basic block-level pass to find all Objective-C class references that
/// use the old-style Objective-C runtime and rewrite them to use
/// class_getClass instead of statically allocated class references.
/// Replace a single old-style class reference
///
/// \param[in] selector_load
/// The load of the statically-allocated selector.
///
/// \return
/// True on success; false otherwise
bool RewriteObjCClassReference(llvm::Instruction *class_load);
/// The top-level pass implementation
///
/// \param[in] basic_block
/// The basic block currently being processed.
///
/// \return
/// True on success; false otherwise
bool RewriteObjCClassReferences(llvm::BasicBlock &basic_block);
/// A basic block-level pass to find all newly-declared persistent
/// variables and register them with the ClangExprDeclMap. This allows them
/// to be materialized and dematerialized like normal external variables.
/// Before transformation, these persistent variables look like normal
/// locals, so they have an allocation. This pass excises these allocations
/// and makes references look like external references where they will be
/// resolved -- like all other external references -- by ResolveExternals().
/// Handle a single allocation of a persistent variable
///
/// \param[in] persistent_alloc
/// The allocation of the persistent variable.
///
/// \return
/// True on success; false otherwise
bool RewritePersistentAlloc(llvm::Instruction *persistent_alloc);
/// The top-level pass implementation
///
/// \param[in] basic_block
/// The basic block currently being processed.
bool RewritePersistentAllocs(llvm::BasicBlock &basic_block);
/// A function-level pass to find all external variables and functions
/// used in the IR. Each found external variable is added to the struct,
/// and each external function is resolved in place, its call replaced with
/// a call to a function pointer whose value is the address of the function
/// in the target process.
/// Handle a single externally-defined variable
///
/// \param[in] value
/// The variable.
///
/// \return
/// True on success; false otherwise
bool MaybeHandleVariable(llvm::Value *value);
/// Handle a single externally-defined symbol
///
/// \param[in] symbol
/// The symbol.
///
/// \return
/// True on success; false otherwise
bool HandleSymbol(llvm::Value *symbol);
/// Handle a single externally-defined Objective-C class
///
/// \param[in] classlist_reference
/// The reference, usually "01L_OBJC_CLASSLIST_REFERENCES_$_n"
/// where n (if present) is an index.
///
/// \return
/// True on success; false otherwise
bool HandleObjCClass(llvm::Value *classlist_reference);
/// Handle all the arguments to a function call
///
/// \param[in] C
/// The call instruction.
///
/// \return
/// True on success; false otherwise
bool MaybeHandleCallArguments(llvm::CallInst *call_inst);
/// Resolve variable references in calls to external functions
///
/// \param[in] basic_block
/// The basic block currently being processed.
///
/// \return
/// True on success; false otherwise
bool ResolveCalls(llvm::BasicBlock &basic_block);
/// Remove calls to __cxa_atexit, which should never be generated by
/// expressions.
///
/// \param[in] call_inst
/// The call instruction.
///
/// \return
/// True if the scan was successful; false if some operation
/// failed
bool RemoveCXAAtExit(llvm::BasicBlock &basic_block);
/// The top-level pass implementation
///
/// \param[in] basic_block
/// The function currently being processed.
///
/// \return
/// True on success; false otherwise
bool ResolveExternals(llvm::Function &llvm_function);
/// A basic block-level pass to excise guard variables from the code.
/// The result for the function is passed through Clang as a static
/// variable. Static variables normally have guard variables to ensure that
/// they are only initialized once.
/// Rewrite a load to a guard variable to return constant 0.
///
/// \param[in] guard_load
/// The load instruction to zero out.
void TurnGuardLoadIntoZero(llvm::Instruction *guard_load);
/// The top-level pass implementation
///
/// \param[in] basic_block
/// The basic block currently being processed.
///
/// \return
/// True on success; false otherwise
bool RemoveGuards(llvm::BasicBlock &basic_block);
/// A function-level pass to make all external variable references
/// point at the correct offsets from the void* passed into the function.
/// ClangExpressionDeclMap::DoStructLayout() must be called beforehand, so
/// that the offsets are valid.
/// The top-level pass implementation
///
/// \param[in] llvm_function
/// The function currently being processed.
///
/// \return
/// True on success; false otherwise
bool ReplaceVariables(llvm::Function &llvm_function);
/// Flags
bool m_resolve_vars; ///< True if external variable references and persistent
///variable references should be resolved
lldb_private::ConstString
m_func_name; ///< The name of the function to translate
lldb_private::ConstString
m_result_name; ///< The name of the result variable ($0, $1, ...)
lldb_private::TypeFromParser
m_result_type; ///< The type of the result variable.
llvm::Module *m_module; ///< The module being processed, or NULL if that has
///not been determined yet.
std::unique_ptr<llvm::DataLayout> m_target_data; ///< The target data for the
///module being processed, or
///NULL if there is no
///module.
lldb_private::ClangExpressionDeclMap
*m_decl_map; ///< The DeclMap containing the Decls
llvm::FunctionCallee
m_CFStringCreateWithBytes; ///< The address of the function
/// CFStringCreateWithBytes, cast to the
/// appropriate function pointer type
llvm::FunctionCallee m_sel_registerName; ///< The address of the function
/// sel_registerName, cast to the
/// appropriate function pointer type
llvm::FunctionCallee m_objc_getClass; ///< The address of the function
/// objc_getClass, cast to the
/// appropriate function pointer type
llvm::IntegerType
*m_intptr_ty; ///< The type of an integer large enough to hold a pointer.
lldb_private::Stream
&m_error_stream; ///< The stream on which errors should be printed
lldb_private::IRExecutionUnit &
m_execution_unit; ///< The execution unit containing the IR being created.
llvm::StoreInst *m_result_store; ///< If non-NULL, the store instruction that
///writes to the result variable. If
/// m_has_side_effects is true, this is
/// NULL.
bool m_result_is_pointer; ///< True if the function's result in the AST is a
///pointer (see comments in
/// ASTResultSynthesizer::SynthesizeBodyResult)
llvm::GlobalVariable *m_reloc_placeholder; ///< A placeholder that will be
///replaced by a pointer to the
///final
/// location of the static allocation.
/// UnfoldConstant operates on a constant [Old] which has just been replaced
/// with a value [New]. We assume that new_value has been properly placed
/// early in the function, in front of the first instruction in the entry
/// basic block [FirstEntryInstruction].
///
/// UnfoldConstant reads through the uses of Old and replaces Old in those
/// uses with New. Where those uses are constants, the function generates
/// new instructions to compute the result of the new, non-constant
/// expression and places them before FirstEntryInstruction. These
/// instructions replace the constant uses, so UnfoldConstant calls itself
/// recursively for those.
///
/// \param[in] llvm_function
/// The function currently being processed.
///
/// \return
/// True on success; false otherwise
class FunctionValueCache {
public:
typedef std::function<llvm::Value *(llvm::Function *)> Maker;
FunctionValueCache(Maker const &maker);
~FunctionValueCache();
llvm::Value *GetValue(llvm::Function *function);
private:
Maker const m_maker;
typedef std::map<llvm::Function *, llvm::Value *> FunctionValueMap;
FunctionValueMap m_values;
};
FunctionValueCache m_entry_instruction_finder;
static bool UnfoldConstant(llvm::Constant *old_constant,
llvm::Function *llvm_function,
FunctionValueCache &value_maker,
FunctionValueCache &entry_instruction_finder,
lldb_private::Stream &error_stream);
/// Commit the allocation in m_data_allocator and use its final location to
/// replace m_reloc_placeholder.
///
/// \param[in] module
/// The module that m_data_allocator resides in
///
/// \return
/// True on success; false otherwise
bool CompleteDataAllocation();
};
#endif // liblldb_IRForTarget_h_
|