//===-- IRForTarget.cpp -----------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/Expression/IRForTarget.h" #include "llvm/Support/raw_ostream.h" #include "llvm/IR/Constants.h" #include "llvm/IR/DataLayout.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/Intrinsics.h" #include "llvm/IR/Module.h" #include "llvm/PassManager.h" #include "llvm/Transforms/IPO.h" #include "llvm/IR/ValueSymbolTable.h" #include "clang/AST/ASTContext.h" #include "lldb/Core/dwarf.h" #include "lldb/Core/ConstString.h" #include "lldb/Core/DataBufferHeap.h" #include "lldb/Core/Log.h" #include "lldb/Core/Scalar.h" #include "lldb/Core/StreamString.h" #include "lldb/Expression/ClangExpressionDeclMap.h" #include "lldb/Expression/IRExecutionUnit.h" #include "lldb/Expression/IRInterpreter.h" #include "lldb/Host/Endian.h" #include "lldb/Symbol/ClangASTContext.h" #include "lldb/Symbol/ClangASTType.h" #include <map> using namespace llvm; static char ID; IRForTarget::StaticDataAllocator::StaticDataAllocator(lldb_private::IRExecutionUnit &execution_unit) : m_execution_unit(execution_unit), m_stream_string(lldb_private::Stream::eBinary, execution_unit.GetAddressByteSize(), execution_unit.GetByteOrder()), m_allocation(LLDB_INVALID_ADDRESS) { } IRForTarget::FunctionValueCache::FunctionValueCache(Maker const &maker) : m_maker(maker), m_values() { } IRForTarget::FunctionValueCache::~FunctionValueCache() { } llvm::Value *IRForTarget::FunctionValueCache::GetValue(llvm::Function *function) { if (!m_values.count(function)) { llvm::Value *ret = m_maker(function); m_values[function] = ret; return ret; } return m_values[function]; } lldb::addr_t IRForTarget::StaticDataAllocator::Allocate() { lldb_private::Error err; if (m_allocation != LLDB_INVALID_ADDRESS) { m_execution_unit.FreeNow(m_allocation); m_allocation = LLDB_INVALID_ADDRESS; } m_allocation = m_execution_unit.WriteNow((const uint8_t*)m_stream_string.GetData(), m_stream_string.GetSize(), err); return m_allocation; } static llvm::Value *FindEntryInstruction (llvm::Function *function) { if (function->empty()) return NULL; return function->getEntryBlock().getFirstNonPHIOrDbg(); } IRForTarget::IRForTarget (lldb_private::ClangExpressionDeclMap *decl_map, bool resolve_vars, lldb_private::IRExecutionUnit &execution_unit, lldb_private::Stream *error_stream, const char *func_name) : ModulePass(ID), m_resolve_vars(resolve_vars), m_func_name(func_name), m_module(NULL), m_decl_map(decl_map), m_data_allocator(execution_unit), m_CFStringCreateWithBytes(NULL), m_sel_registerName(NULL), m_error_stream(error_stream), m_result_store(NULL), m_result_is_pointer(false), m_reloc_placeholder(NULL), m_entry_instruction_finder (FindEntryInstruction) { } /* Handy utility functions used at several places in the code */ static std::string PrintValue(const Value *value, bool truncate = false) { std::string s; if (value) { raw_string_ostream rso(s); value->print(rso); rso.flush(); if (truncate) s.resize(s.length() - 1); } return s; } static std::string PrintType(const llvm::Type *type, bool truncate = false) { std::string s; raw_string_ostream rso(s); type->print(rso); rso.flush(); if (truncate) s.resize(s.length() - 1); return s; } IRForTarget::~IRForTarget() { } bool IRForTarget::FixFunctionLinkage(llvm::Function &llvm_function) { llvm_function.setLinkage(GlobalValue::ExternalLinkage); std::string name = llvm_function.getName().str(); return true; } bool IRForTarget::GetFunctionAddress (llvm::Function *fun, uint64_t &fun_addr, lldb_private::ConstString &name, Constant **&value_ptr) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); fun_addr = LLDB_INVALID_ADDRESS; name.Clear(); value_ptr = NULL; if (fun->isIntrinsic()) { Intrinsic::ID intrinsic_id = (Intrinsic::ID)fun->getIntrinsicID(); switch (intrinsic_id) { default: if (log) log->Printf("Unresolved intrinsic \"%s\"", Intrinsic::getName(intrinsic_id).c_str()); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Call to unhandled compiler intrinsic '%s'\n", Intrinsic::getName(intrinsic_id).c_str()); return false; case Intrinsic::memcpy: { static lldb_private::ConstString g_memcpy_str ("memcpy"); name = g_memcpy_str; } break; case Intrinsic::memset: { static lldb_private::ConstString g_memset_str ("memset"); name = g_memset_str; } break; } if (log && name) log->Printf("Resolved intrinsic name \"%s\"", name.GetCString()); } else { name.SetCStringWithLength (fun->getName().data(), fun->getName().size()); } // Find the address of the function. clang::NamedDecl *fun_decl = DeclForGlobal (fun); if (fun_decl) { if (!m_decl_map->GetFunctionInfo (fun_decl, fun_addr)) { lldb_private::ConstString altnernate_name; bool found_it = m_decl_map->GetFunctionAddress (name, fun_addr); if (!found_it) { // Check for an alternate mangling for "std::basic_string<char>" // that is part of the itanium C++ name mangling scheme const char *name_cstr = name.GetCString(); if (name_cstr && strncmp(name_cstr, "_ZNKSbIcE", strlen("_ZNKSbIcE")) == 0) { std::string alternate_mangling("_ZNKSs"); alternate_mangling.append (name_cstr + strlen("_ZNKSbIcE")); altnernate_name.SetCString(alternate_mangling.c_str()); found_it = m_decl_map->GetFunctionAddress (altnernate_name, fun_addr); } } if (!found_it) { lldb_private::Mangled mangled_name(name); lldb_private::Mangled alt_mangled_name(altnernate_name); if (log) { if (alt_mangled_name) log->Printf("Function \"%s\" (alternate name \"%s\") has no address", mangled_name.GetName().GetCString(), alt_mangled_name.GetName().GetCString()); else log->Printf("Function \"%s\" had no address", mangled_name.GetName().GetCString()); } if (m_error_stream) { if (alt_mangled_name) m_error_stream->Printf("error: call to a function '%s' (alternate name '%s') that is not present in the target\n", mangled_name.GetName().GetCString(), alt_mangled_name.GetName().GetCString()); else if (mangled_name.GetMangledName()) m_error_stream->Printf("error: call to a function '%s' ('%s') that is not present in the target\n", mangled_name.GetName().GetCString(), mangled_name.GetMangledName().GetCString()); else m_error_stream->Printf("error: call to a function '%s' that is not present in the target\n", mangled_name.GetName().GetCString()); } return false; } } } else { if (!m_decl_map->GetFunctionAddress (name, fun_addr)) { if (log) log->Printf ("Metadataless function \"%s\" had no address", name.GetCString()); if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Call to a symbol-only function '%s' that is not present in the target\n", name.GetCString()); return false; } } if (log) log->Printf("Found \"%s\" at 0x%" PRIx64, name.GetCString(), fun_addr); return true; } llvm::Constant * IRForTarget::BuildFunctionPointer (llvm::Type *type, uint64_t ptr) { IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); PointerType *fun_ptr_ty = PointerType::getUnqual(type); Constant *fun_addr_int = ConstantInt::get(intptr_ty, ptr, false); return ConstantExpr::getIntToPtr(fun_addr_int, fun_ptr_ty); } void IRForTarget::RegisterFunctionMetadata(LLVMContext &context, llvm::Value *function_ptr, const char *name) { for (Value::use_iterator i = function_ptr->use_begin(), e = function_ptr->use_end(); i != e; ++i) { Value *user = *i; if (Instruction *user_inst = dyn_cast<Instruction>(user)) { MDString* md_name = MDString::get(context, StringRef(name)); MDNode *metadata = MDNode::get(context, md_name); user_inst->setMetadata("lldb.call.realName", metadata); } else { RegisterFunctionMetadata (context, user, name); } } } bool IRForTarget::ResolveFunctionPointers(llvm::Module &llvm_module) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); for (llvm::Module::iterator fi = llvm_module.begin(); fi != llvm_module.end(); ++fi) { Function *fun = fi; bool is_decl = fun->isDeclaration(); if (log) log->Printf("Examining %s function %s", (is_decl ? "declaration" : "non-declaration"), fun->getName().str().c_str()); if (!is_decl) continue; if (fun->hasNUses(0)) continue; // ignore uint64_t addr = LLDB_INVALID_ADDRESS; lldb_private::ConstString name; Constant **value_ptr = NULL; if (!GetFunctionAddress(fun, addr, name, value_ptr)) return false; // GetFunctionAddress reports its own errors Constant *value = BuildFunctionPointer(fun->getFunctionType(), addr); RegisterFunctionMetadata (llvm_module.getContext(), fun, name.AsCString()); if (value_ptr) *value_ptr = value; // If we are replacing a function with the nobuiltin attribute, it may // be called with the builtin attribute on call sites. Remove any such // attributes since it's illegal to have a builtin call to something // other than a nobuiltin function. if (fun->hasFnAttribute(Attribute::NoBuiltin)) { Attribute builtin = Attribute::get(fun->getContext(), Attribute::Builtin); for (auto u = fun->use_begin(), e = fun->use_end(); u != e; ++u) { if (auto call = dyn_cast<CallInst>(*u)) { call->removeAttribute(AttributeSet::FunctionIndex, builtin); } } } fun->replaceAllUsesWith(value); } return true; } clang::NamedDecl * IRForTarget::DeclForGlobal (const GlobalValue *global_val, Module *module) { NamedMDNode *named_metadata = module->getNamedMetadata("clang.global.decl.ptrs"); if (!named_metadata) return NULL; unsigned num_nodes = named_metadata->getNumOperands(); unsigned node_index; for (node_index = 0; node_index < num_nodes; ++node_index) { MDNode *metadata_node = named_metadata->getOperand(node_index); if (!metadata_node) return NULL; if (metadata_node->getNumOperands() != 2) continue; if (metadata_node->getOperand(0) != global_val) continue; ConstantInt *constant_int = dyn_cast<ConstantInt>(metadata_node->getOperand(1)); if (!constant_int) return NULL; uintptr_t ptr = constant_int->getZExtValue(); return reinterpret_cast<clang::NamedDecl *>(ptr); } return NULL; } clang::NamedDecl * IRForTarget::DeclForGlobal (GlobalValue *global_val) { return DeclForGlobal(global_val, m_module); } bool IRForTarget::CreateResultVariable (llvm::Function &llvm_function) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); if (!m_resolve_vars) return true; // Find the result variable. If it doesn't exist, we can give up right here. ValueSymbolTable& value_symbol_table = m_module->getValueSymbolTable(); std::string result_name_str; const char *result_name = NULL; for (ValueSymbolTable::iterator vi = value_symbol_table.begin(), ve = value_symbol_table.end(); vi != ve; ++vi) { result_name_str = vi->first().str(); const char *value_name = result_name_str.c_str(); if (strstr(value_name, "$__lldb_expr_result_ptr") && strncmp(value_name, "_ZGV", 4)) { result_name = value_name; m_result_is_pointer = true; break; } if (strstr(value_name, "$__lldb_expr_result") && strncmp(value_name, "_ZGV", 4)) { result_name = value_name; m_result_is_pointer = false; break; } } if (!result_name) { if (log) log->PutCString("Couldn't find result variable"); return true; } if (log) log->Printf("Result name: \"%s\"", result_name); Value *result_value = m_module->getNamedValue(result_name); if (!result_value) { if (log) log->PutCString("Result variable had no data"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Result variable's name (%s) exists, but not its definition\n", result_name); return false; } if (log) log->Printf("Found result in the IR: \"%s\"", PrintValue(result_value, false).c_str()); GlobalVariable *result_global = dyn_cast<GlobalVariable>(result_value); if (!result_global) { if (log) log->PutCString("Result variable isn't a GlobalVariable"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Result variable (%s) is defined, but is not a global variable\n", result_name); return false; } clang::NamedDecl *result_decl = DeclForGlobal (result_global); if (!result_decl) { if (log) log->PutCString("Result variable doesn't have a corresponding Decl"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Result variable (%s) does not have a corresponding Clang entity\n", result_name); return false; } if (log) { std::string decl_desc_str; raw_string_ostream decl_desc_stream(decl_desc_str); result_decl->print(decl_desc_stream); decl_desc_stream.flush(); log->Printf("Found result decl: \"%s\"", decl_desc_str.c_str()); } clang::VarDecl *result_var = dyn_cast<clang::VarDecl>(result_decl); if (!result_var) { if (log) log->PutCString("Result variable Decl isn't a VarDecl"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Result variable (%s)'s corresponding Clang entity isn't a variable\n", result_name); return false; } // Get the next available result name from m_decl_map and create the persistent // variable for it // If the result is an Lvalue, it is emitted as a pointer; see // ASTResultSynthesizer::SynthesizeBodyResult. if (m_result_is_pointer) { clang::QualType pointer_qual_type = result_var->getType(); const clang::Type *pointer_type = pointer_qual_type.getTypePtr(); const clang::PointerType *pointer_pointertype = pointer_type->getAs<clang::PointerType>(); const clang::ObjCObjectPointerType *pointer_objcobjpointertype = pointer_type->getAs<clang::ObjCObjectPointerType>(); if (pointer_pointertype) { clang::QualType element_qual_type = pointer_pointertype->getPointeeType(); m_result_type = lldb_private::TypeFromParser(element_qual_type.getAsOpaquePtr(), &result_decl->getASTContext()); } else if (pointer_objcobjpointertype) { clang::QualType element_qual_type = clang::QualType(pointer_objcobjpointertype->getObjectType(), 0); m_result_type = lldb_private::TypeFromParser(element_qual_type.getAsOpaquePtr(), &result_decl->getASTContext()); } else { if (log) log->PutCString("Expected result to have pointer type, but it did not"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Lvalue result (%s) is not a pointer variable\n", result_name); return false; } } else { m_result_type = lldb_private::TypeFromParser(result_var->getType().getAsOpaquePtr(), &result_decl->getASTContext()); } if (m_result_type.GetBitSize() == 0) { lldb_private::StreamString type_desc_stream; m_result_type.DumpTypeDescription(&type_desc_stream); if (log) log->Printf("Result type has size 0"); if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Size of result type '%s' couldn't be determined\n", type_desc_stream.GetData()); return false; } if (log) { lldb_private::StreamString type_desc_stream; m_result_type.DumpTypeDescription(&type_desc_stream); log->Printf("Result decl type: \"%s\"", type_desc_stream.GetData()); } m_result_name = lldb_private::ConstString("$RESULT_NAME"); if (log) log->Printf("Creating a new result global: \"%s\" with size 0x%" PRIx64, m_result_name.GetCString(), m_result_type.GetByteSize()); // Construct a new result global and set up its metadata GlobalVariable *new_result_global = new GlobalVariable((*m_module), result_global->getType()->getElementType(), false, /* not constant */ GlobalValue::ExternalLinkage, NULL, /* no initializer */ m_result_name.GetCString ()); // It's too late in compilation to create a new VarDecl for this, but we don't // need to. We point the metadata at the old VarDecl. This creates an odd // anomaly: a variable with a Value whose name is something like $0 and a // Decl whose name is $__lldb_expr_result. This condition is handled in // ClangExpressionDeclMap::DoMaterialize, and the name of the variable is // fixed up. ConstantInt *new_constant_int = ConstantInt::get(llvm::Type::getInt64Ty(m_module->getContext()), reinterpret_cast<uint64_t>(result_decl), false); llvm::Value* values[2]; values[0] = new_result_global; values[1] = new_constant_int; ArrayRef<Value*> value_ref(values, 2); MDNode *persistent_global_md = MDNode::get(m_module->getContext(), value_ref); NamedMDNode *named_metadata = m_module->getNamedMetadata("clang.global.decl.ptrs"); named_metadata->addOperand(persistent_global_md); if (log) log->Printf("Replacing \"%s\" with \"%s\"", PrintValue(result_global).c_str(), PrintValue(new_result_global).c_str()); if (result_global->hasNUses(0)) { // We need to synthesize a store for this variable, because otherwise // there's nothing to put into its equivalent persistent variable. BasicBlock &entry_block(llvm_function.getEntryBlock()); Instruction *first_entry_instruction(entry_block.getFirstNonPHIOrDbg()); if (!first_entry_instruction) return false; if (!result_global->hasInitializer()) { if (log) log->Printf("Couldn't find initializer for unused variable"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Result variable (%s) has no writes and no initializer\n", result_name); return false; } Constant *initializer = result_global->getInitializer(); StoreInst *synthesized_store = new StoreInst(initializer, new_result_global, first_entry_instruction); if (log) log->Printf("Synthesized result store \"%s\"\n", PrintValue(synthesized_store).c_str()); } else { result_global->replaceAllUsesWith(new_result_global); } if (!m_decl_map->AddPersistentVariable(result_decl, m_result_name, m_result_type, true, m_result_is_pointer)) return false; result_global->eraseFromParent(); return true; } #if 0 static void DebugUsers(Log *log, Value *value, uint8_t depth) { if (!depth) return; depth--; if (log) log->Printf(" <Begin %d users>", value->getNumUses()); for (Value::use_iterator ui = value->use_begin(), ue = value->use_end(); ui != ue; ++ui) { if (log) log->Printf(" <Use %p> %s", *ui, PrintValue(*ui).c_str()); DebugUsers(log, *ui, depth); } if (log) log->Printf(" <End uses>"); } #endif bool IRForTarget::RewriteObjCConstString (llvm::GlobalVariable *ns_str, llvm::GlobalVariable *cstr) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); Type *ns_str_ty = ns_str->getType(); Type *i8_ptr_ty = Type::getInt8PtrTy(m_module->getContext()); IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); Type *i32_ty = Type::getInt32Ty(m_module->getContext()); Type *i8_ty = Type::getInt8Ty(m_module->getContext()); if (!m_CFStringCreateWithBytes) { lldb::addr_t CFStringCreateWithBytes_addr; static lldb_private::ConstString g_CFStringCreateWithBytes_str ("CFStringCreateWithBytes"); if (!m_decl_map->GetFunctionAddress (g_CFStringCreateWithBytes_str, CFStringCreateWithBytes_addr)) { if (log) log->PutCString("Couldn't find CFStringCreateWithBytes in the target"); if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Rewriting an Objective-C constant string requires CFStringCreateWithBytes\n"); return false; } if (log) log->Printf("Found CFStringCreateWithBytes at 0x%" PRIx64, CFStringCreateWithBytes_addr); // Build the function type: // // CFStringRef CFStringCreateWithBytes ( // CFAllocatorRef alloc, // const UInt8 *bytes, // CFIndex numBytes, // CFStringEncoding encoding, // Boolean isExternalRepresentation // ); // // We make the following substitutions: // // CFStringRef -> i8* // CFAllocatorRef -> i8* // UInt8 * -> i8* // CFIndex -> long (i32 or i64, as appropriate; we ask the module for its pointer size for now) // CFStringEncoding -> i32 // Boolean -> i8 Type *arg_type_array[5]; arg_type_array[0] = i8_ptr_ty; arg_type_array[1] = i8_ptr_ty; arg_type_array[2] = intptr_ty; arg_type_array[3] = i32_ty; arg_type_array[4] = i8_ty; ArrayRef<Type *> CFSCWB_arg_types(arg_type_array, 5); llvm::Type *CFSCWB_ty = FunctionType::get(ns_str_ty, CFSCWB_arg_types, false); // Build the constant containing the pointer to the function PointerType *CFSCWB_ptr_ty = PointerType::getUnqual(CFSCWB_ty); Constant *CFSCWB_addr_int = ConstantInt::get(intptr_ty, CFStringCreateWithBytes_addr, false); m_CFStringCreateWithBytes = ConstantExpr::getIntToPtr(CFSCWB_addr_int, CFSCWB_ptr_ty); } ConstantDataSequential *string_array = NULL; if (cstr) string_array = dyn_cast<ConstantDataSequential>(cstr->getInitializer()); Constant *alloc_arg = Constant::getNullValue(i8_ptr_ty); Constant *bytes_arg = cstr ? ConstantExpr::getBitCast(cstr, i8_ptr_ty) : Constant::getNullValue(i8_ptr_ty); Constant *numBytes_arg = ConstantInt::get(intptr_ty, cstr ? string_array->getNumElements() - 1 : 0, false); Constant *encoding_arg = ConstantInt::get(i32_ty, 0x0600, false); /* 0x0600 is kCFStringEncodingASCII */ Constant *isExternal_arg = ConstantInt::get(i8_ty, 0x0, false); /* 0x0 is false */ Value *argument_array[5]; argument_array[0] = alloc_arg; argument_array[1] = bytes_arg; argument_array[2] = numBytes_arg; argument_array[3] = encoding_arg; argument_array[4] = isExternal_arg; ArrayRef <Value *> CFSCWB_arguments(argument_array, 5); FunctionValueCache CFSCWB_Caller ([this, &CFSCWB_arguments] (llvm::Function *function)->llvm::Value * { return CallInst::Create(m_CFStringCreateWithBytes, CFSCWB_arguments, "CFStringCreateWithBytes", llvm::cast<Instruction>(m_entry_instruction_finder.GetValue(function))); }); if (!UnfoldConstant(ns_str, CFSCWB_Caller, m_entry_instruction_finder)) { if (log) log->PutCString("Couldn't replace the NSString with the result of the call"); if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Couldn't replace an Objective-C constant string with a dynamic string\n"); return false; } ns_str->eraseFromParent(); return true; } bool IRForTarget::RewriteObjCConstStrings() { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); ValueSymbolTable& value_symbol_table = m_module->getValueSymbolTable(); for (ValueSymbolTable::iterator vi = value_symbol_table.begin(), ve = value_symbol_table.end(); vi != ve; ++vi) { std::string value_name = vi->first().str(); const char *value_name_cstr = value_name.c_str(); if (strstr(value_name_cstr, "_unnamed_cfstring_")) { Value *nsstring_value = vi->second; GlobalVariable *nsstring_global = dyn_cast<GlobalVariable>(nsstring_value); if (!nsstring_global) { if (log) log->PutCString("NSString variable is not a GlobalVariable"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string is not a global variable\n"); return false; } if (!nsstring_global->hasInitializer()) { if (log) log->PutCString("NSString variable does not have an initializer"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string does not have an initializer\n"); return false; } ConstantStruct *nsstring_struct = dyn_cast<ConstantStruct>(nsstring_global->getInitializer()); if (!nsstring_struct) { if (log) log->PutCString("NSString variable's initializer is not a ConstantStruct"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string is not a structure constant\n"); return false; } // We expect the following structure: // // struct { // int *isa; // int flags; // char *str; // long length; // }; if (nsstring_struct->getNumOperands() != 4) { if (log) log->Printf("NSString variable's initializer structure has an unexpected number of members. Should be 4, is %d", nsstring_struct->getNumOperands()); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: The struct for an Objective-C constant string is not as expected\n"); return false; } Constant *nsstring_member = nsstring_struct->getOperand(2); if (!nsstring_member) { if (log) log->PutCString("NSString initializer's str element was empty"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string does not have a string initializer\n"); return false; } ConstantExpr *nsstring_expr = dyn_cast<ConstantExpr>(nsstring_member); if (!nsstring_expr) { if (log) log->PutCString("NSString initializer's str element is not a ConstantExpr"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer is not constant\n"); return false; } if (nsstring_expr->getOpcode() != Instruction::GetElementPtr) { if (log) log->Printf("NSString initializer's str element is not a GetElementPtr expression, it's a %s", nsstring_expr->getOpcodeName()); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer is not an array\n"); return false; } Constant *nsstring_cstr = nsstring_expr->getOperand(0); GlobalVariable *cstr_global = dyn_cast<GlobalVariable>(nsstring_cstr); if (!cstr_global) { if (log) log->PutCString("NSString initializer's str element is not a GlobalVariable"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer doesn't point to a global\n"); return false; } if (!cstr_global->hasInitializer()) { if (log) log->PutCString("NSString initializer's str element does not have an initializer"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer doesn't point to initialized data\n"); return false; } /* if (!cstr_array) { if (log) log->PutCString("NSString initializer's str element is not a ConstantArray"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer doesn't point to an array\n"); return false; } if (!cstr_array->isCString()) { if (log) log->PutCString("NSString initializer's str element is not a C string array"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: An Objective-C constant string's string initializer doesn't point to a C string\n"); return false; } */ ConstantDataArray *cstr_array = dyn_cast<ConstantDataArray>(cstr_global->getInitializer()); if (log) { if (cstr_array) log->Printf("Found NSString constant %s, which contains \"%s\"", value_name_cstr, cstr_array->getAsString().str().c_str()); else log->Printf("Found NSString constant %s, which contains \"\"", value_name_cstr); } if (!cstr_array) cstr_global = NULL; if (!RewriteObjCConstString(nsstring_global, cstr_global)) { if (log) log->PutCString("Error rewriting the constant string"); // We don't print an error message here because RewriteObjCConstString has done so for us. return false; } } } for (ValueSymbolTable::iterator vi = value_symbol_table.begin(), ve = value_symbol_table.end(); vi != ve; ++vi) { std::string value_name = vi->first().str(); const char *value_name_cstr = value_name.c_str(); if (!strcmp(value_name_cstr, "__CFConstantStringClassReference")) { GlobalVariable *gv = dyn_cast<GlobalVariable>(vi->second); if (!gv) { if (log) log->PutCString("__CFConstantStringClassReference is not a global variable"); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Found a CFConstantStringClassReference, but it is not a global object\n"); return false; } gv->eraseFromParent(); break; } } return true; } static bool IsObjCSelectorRef (Value *value) { GlobalVariable *global_variable = dyn_cast<GlobalVariable>(value); if (!global_variable || !global_variable->hasName() || !global_variable->getName().startswith("\01L_OBJC_SELECTOR_REFERENCES_")) return false; return true; } // This function does not report errors; its callers are responsible. bool IRForTarget::RewriteObjCSelector (Instruction* selector_load) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); LoadInst *load = dyn_cast<LoadInst>(selector_load); if (!load) return false; // Unpack the message name from the selector. In LLVM IR, an objc_msgSend gets represented as // // %tmp = load i8** @"\01L_OBJC_SELECTOR_REFERENCES_" ; <i8*> // %call = call i8* (i8*, i8*, ...)* @objc_msgSend(i8* %obj, i8* %tmp, ...) ; <i8*> // // where %obj is the object pointer and %tmp is the selector. // // @"\01L_OBJC_SELECTOR_REFERENCES_" is a pointer to a character array called @"\01L_OBJC_llvm_moduleETH_VAR_NAllvm_moduleE_". // @"\01L_OBJC_llvm_moduleETH_VAR_NAllvm_moduleE_" contains the string. // Find the pointer's initializer (a ConstantExpr with opcode GetElementPtr) and get the string from its target GlobalVariable *_objc_selector_references_ = dyn_cast<GlobalVariable>(load->getPointerOperand()); if (!_objc_selector_references_ || !_objc_selector_references_->hasInitializer()) return false; Constant *osr_initializer = _objc_selector_references_->getInitializer(); ConstantExpr *osr_initializer_expr = dyn_cast<ConstantExpr>(osr_initializer); if (!osr_initializer_expr || osr_initializer_expr->getOpcode() != Instruction::GetElementPtr) return false; Value *osr_initializer_base = osr_initializer_expr->getOperand(0); if (!osr_initializer_base) return false; // Find the string's initializer (a ConstantArray) and get the string from it GlobalVariable *_objc_meth_var_name_ = dyn_cast<GlobalVariable>(osr_initializer_base); if (!_objc_meth_var_name_ || !_objc_meth_var_name_->hasInitializer()) return false; Constant *omvn_initializer = _objc_meth_var_name_->getInitializer(); ConstantDataArray *omvn_initializer_array = dyn_cast<ConstantDataArray>(omvn_initializer); if (!omvn_initializer_array->isString()) return false; std::string omvn_initializer_string = omvn_initializer_array->getAsString(); if (log) log->Printf("Found Objective-C selector reference \"%s\"", omvn_initializer_string.c_str()); // Construct a call to sel_registerName if (!m_sel_registerName) { lldb::addr_t sel_registerName_addr; static lldb_private::ConstString g_sel_registerName_str ("sel_registerName"); if (!m_decl_map->GetFunctionAddress (g_sel_registerName_str, sel_registerName_addr)) return false; if (log) log->Printf("Found sel_registerName at 0x%" PRIx64, sel_registerName_addr); // Build the function type: struct objc_selector *sel_registerName(uint8_t*) // The below code would be "more correct," but in actuality what's required is uint8_t* //Type *sel_type = StructType::get(m_module->getContext()); //Type *sel_ptr_type = PointerType::getUnqual(sel_type); Type *sel_ptr_type = Type::getInt8PtrTy(m_module->getContext()); Type *type_array[1]; type_array[0] = llvm::Type::getInt8PtrTy(m_module->getContext()); ArrayRef<Type *> srN_arg_types(type_array, 1); llvm::Type *srN_type = FunctionType::get(sel_ptr_type, srN_arg_types, false); // Build the constant containing the pointer to the function IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); PointerType *srN_ptr_ty = PointerType::getUnqual(srN_type); Constant *srN_addr_int = ConstantInt::get(intptr_ty, sel_registerName_addr, false); m_sel_registerName = ConstantExpr::getIntToPtr(srN_addr_int, srN_ptr_ty); } Value *argument_array[1]; Constant *omvn_pointer = ConstantExpr::getBitCast(_objc_meth_var_name_, Type::getInt8PtrTy(m_module->getContext())); argument_array[0] = omvn_pointer; ArrayRef<Value *> srN_arguments(argument_array, 1); CallInst *srN_call = CallInst::Create(m_sel_registerName, srN_arguments, "sel_registerName", selector_load); // Replace the load with the call in all users selector_load->replaceAllUsesWith(srN_call); selector_load->eraseFromParent(); return true; } bool IRForTarget::RewriteObjCSelectors (BasicBlock &basic_block) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); BasicBlock::iterator ii; typedef SmallVector <Instruction*, 2> InstrList; typedef InstrList::iterator InstrIterator; InstrList selector_loads; for (ii = basic_block.begin(); ii != basic_block.end(); ++ii) { Instruction &inst = *ii; if (LoadInst *load = dyn_cast<LoadInst>(&inst)) if (IsObjCSelectorRef(load->getPointerOperand())) selector_loads.push_back(&inst); } InstrIterator iter; for (iter = selector_loads.begin(); iter != selector_loads.end(); ++iter) { if (!RewriteObjCSelector(*iter)) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't change a static reference to an Objective-C selector to a dynamic reference\n"); if (log) log->PutCString("Couldn't rewrite a reference to an Objective-C selector"); return false; } } return true; } // This function does not report errors; its callers are responsible. bool IRForTarget::RewritePersistentAlloc (llvm::Instruction *persistent_alloc) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); AllocaInst *alloc = dyn_cast<AllocaInst>(persistent_alloc); MDNode *alloc_md = alloc->getMetadata("clang.decl.ptr"); if (!alloc_md || !alloc_md->getNumOperands()) return false; ConstantInt *constant_int = dyn_cast<ConstantInt>(alloc_md->getOperand(0)); if (!constant_int) return false; // We attempt to register this as a new persistent variable with the DeclMap. uintptr_t ptr = constant_int->getZExtValue(); clang::VarDecl *decl = reinterpret_cast<clang::VarDecl *>(ptr); lldb_private::TypeFromParser result_decl_type (decl->getType().getAsOpaquePtr(), &decl->getASTContext()); StringRef decl_name (decl->getName()); lldb_private::ConstString persistent_variable_name (decl_name.data(), decl_name.size()); if (!m_decl_map->AddPersistentVariable(decl, persistent_variable_name, result_decl_type, false, false)) return false; GlobalVariable *persistent_global = new GlobalVariable((*m_module), alloc->getType(), false, /* not constant */ GlobalValue::ExternalLinkage, NULL, /* no initializer */ alloc->getName().str().c_str()); // What we're going to do here is make believe this was a regular old external // variable. That means we need to make the metadata valid. NamedMDNode *named_metadata = m_module->getOrInsertNamedMetadata("clang.global.decl.ptrs"); llvm::Value* values[2]; values[0] = persistent_global; values[1] = constant_int; ArrayRef<llvm::Value*> value_ref(values, 2); MDNode *persistent_global_md = MDNode::get(m_module->getContext(), value_ref); named_metadata->addOperand(persistent_global_md); // Now, since the variable is a pointer variable, we will drop in a load of that // pointer variable. LoadInst *persistent_load = new LoadInst (persistent_global, "", alloc); if (log) log->Printf("Replacing \"%s\" with \"%s\"", PrintValue(alloc).c_str(), PrintValue(persistent_load).c_str()); alloc->replaceAllUsesWith(persistent_load); alloc->eraseFromParent(); return true; } bool IRForTarget::RewritePersistentAllocs(llvm::BasicBlock &basic_block) { if (!m_resolve_vars) return true; lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); BasicBlock::iterator ii; typedef SmallVector <Instruction*, 2> InstrList; typedef InstrList::iterator InstrIterator; InstrList pvar_allocs; for (ii = basic_block.begin(); ii != basic_block.end(); ++ii) { Instruction &inst = *ii; if (AllocaInst *alloc = dyn_cast<AllocaInst>(&inst)) { llvm::StringRef alloc_name = alloc->getName(); if (alloc_name.startswith("$") && !alloc_name.startswith("$__lldb")) { if (alloc_name.find_first_of("0123456789") == 1) { if (log) log->Printf("Rejecting a numeric persistent variable."); if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Names starting with $0, $1, ... are reserved for use as result names\n"); return false; } pvar_allocs.push_back(alloc); } } } InstrIterator iter; for (iter = pvar_allocs.begin(); iter != pvar_allocs.end(); ++iter) { if (!RewritePersistentAlloc(*iter)) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't rewrite the creation of a persistent variable\n"); if (log) log->PutCString("Couldn't rewrite the creation of a persistent variable"); return false; } } return true; } bool IRForTarget::MaterializeInitializer (uint8_t *data, Constant *initializer) { if (!initializer) return true; lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); if (log && log->GetVerbose()) log->Printf(" MaterializeInitializer(%p, %s)", data, PrintValue(initializer).c_str()); Type *initializer_type = initializer->getType(); if (ConstantInt *int_initializer = dyn_cast<ConstantInt>(initializer)) { memcpy (data, int_initializer->getValue().getRawData(), m_target_data->getTypeStoreSize(initializer_type)); return true; } else if (ConstantDataArray *array_initializer = dyn_cast<ConstantDataArray>(initializer)) { if (array_initializer->isString()) { std::string array_initializer_string = array_initializer->getAsString(); memcpy (data, array_initializer_string.c_str(), m_target_data->getTypeStoreSize(initializer_type)); } else { ArrayType *array_initializer_type = array_initializer->getType(); Type *array_element_type = array_initializer_type->getElementType(); size_t element_size = m_target_data->getTypeAllocSize(array_element_type); for (unsigned i = 0; i < array_initializer->getNumOperands(); ++i) { Value *operand_value = array_initializer->getOperand(i); Constant *operand_constant = dyn_cast<Constant>(operand_value); if (!operand_constant) return false; if (!MaterializeInitializer(data + (i * element_size), operand_constant)) return false; } } return true; } else if (ConstantStruct *struct_initializer = dyn_cast<ConstantStruct>(initializer)) { StructType *struct_initializer_type = struct_initializer->getType(); const StructLayout *struct_layout = m_target_data->getStructLayout(struct_initializer_type); for (unsigned i = 0; i < struct_initializer->getNumOperands(); ++i) { if (!MaterializeInitializer(data + struct_layout->getElementOffset(i), struct_initializer->getOperand(i))) return false; } return true; } else if (isa<ConstantAggregateZero>(initializer)) { memset(data, 0, m_target_data->getTypeStoreSize(initializer_type)); return true; } return false; } bool IRForTarget::MaterializeInternalVariable (GlobalVariable *global_variable) { if (GlobalVariable::isExternalLinkage(global_variable->getLinkage())) return false; if (global_variable == m_reloc_placeholder) return true; uint64_t offset = m_data_allocator.GetStream().GetSize(); llvm::Type *variable_type = global_variable->getType(); Constant *initializer = global_variable->getInitializer(); llvm::Type *initializer_type = initializer->getType(); size_t size = m_target_data->getTypeAllocSize(initializer_type); size_t align = m_target_data->getPrefTypeAlignment(initializer_type); const size_t mask = (align - 1); uint64_t aligned_offset = (offset + mask) & ~mask; m_data_allocator.GetStream().PutNHex8(aligned_offset - offset, 0); offset = aligned_offset; lldb_private::DataBufferHeap data(size, '\0'); if (initializer) if (!MaterializeInitializer(data.GetBytes(), initializer)) return false; m_data_allocator.GetStream().Write(data.GetBytes(), data.GetByteSize()); Constant *new_pointer = BuildRelocation(variable_type, offset); global_variable->replaceAllUsesWith(new_pointer); global_variable->eraseFromParent(); return true; } // This function does not report errors; its callers are responsible. bool IRForTarget::MaybeHandleVariable (Value *llvm_value_ptr) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); if (log) log->Printf("MaybeHandleVariable (%s)", PrintValue(llvm_value_ptr).c_str()); if (ConstantExpr *constant_expr = dyn_cast<ConstantExpr>(llvm_value_ptr)) { switch (constant_expr->getOpcode()) { default: break; case Instruction::GetElementPtr: case Instruction::BitCast: Value *s = constant_expr->getOperand(0); if (!MaybeHandleVariable(s)) return false; } } else if (GlobalVariable *global_variable = dyn_cast<GlobalVariable>(llvm_value_ptr)) { if (!GlobalValue::isExternalLinkage(global_variable->getLinkage())) return MaterializeInternalVariable(global_variable); clang::NamedDecl *named_decl = DeclForGlobal(global_variable); if (!named_decl) { if (IsObjCSelectorRef(llvm_value_ptr)) return true; if (!global_variable->hasExternalLinkage()) return true; if (log) log->Printf("Found global variable \"%s\" without metadata", global_variable->getName().str().c_str()); return false; } std::string name (named_decl->getName().str()); clang::ValueDecl *value_decl = dyn_cast<clang::ValueDecl>(named_decl); if (value_decl == NULL) return false; lldb_private::ClangASTType clang_type(&value_decl->getASTContext(), value_decl->getType()); const Type *value_type = NULL; if (name[0] == '$') { // The $__lldb_expr_result name indicates the the return value has allocated as // a static variable. Per the comment at ASTResultSynthesizer::SynthesizeBodyResult, // accesses to this static variable need to be redirected to the result of dereferencing // a pointer that is passed in as one of the arguments. // // Consequently, when reporting the size of the type, we report a pointer type pointing // to the type of $__lldb_expr_result, not the type itself. // // We also do this for any user-declared persistent variables. clang_type = clang_type.GetPointerType(); value_type = PointerType::get(global_variable->getType(), 0); } else { value_type = global_variable->getType(); } const uint64_t value_size = clang_type.GetByteSize(); off_t value_alignment = (clang_type.GetTypeBitAlign() + 7ull) / 8ull; if (log) { log->Printf("Type of \"%s\" is [clang \"%s\", llvm \"%s\"] [size %" PRIu64 ", align %" PRId64 "]", name.c_str(), clang_type.GetQualType().getAsString().c_str(), PrintType(value_type).c_str(), value_size, value_alignment); } if (named_decl && !m_decl_map->AddValueToStruct(named_decl, lldb_private::ConstString (name.c_str()), llvm_value_ptr, value_size, value_alignment)) { if (!global_variable->hasExternalLinkage()) return true; else if (HandleSymbol (global_variable)) return true; else return false; } } else if (dyn_cast<llvm::Function>(llvm_value_ptr)) { if (log) log->Printf("Function pointers aren't handled right now"); return false; } return true; } // This function does not report errors; its callers are responsible. bool IRForTarget::HandleSymbol (Value *symbol) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); lldb_private::ConstString name(symbol->getName().str().c_str()); lldb::addr_t symbol_addr = m_decl_map->GetSymbolAddress (name, lldb::eSymbolTypeAny); if (symbol_addr == LLDB_INVALID_ADDRESS) { if (log) log->Printf ("Symbol \"%s\" had no address", name.GetCString()); return false; } if (log) log->Printf("Found \"%s\" at 0x%" PRIx64, name.GetCString(), symbol_addr); Type *symbol_type = symbol->getType(); IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); Constant *symbol_addr_int = ConstantInt::get(intptr_ty, symbol_addr, false); Value *symbol_addr_ptr = ConstantExpr::getIntToPtr(symbol_addr_int, symbol_type); if (log) log->Printf("Replacing %s with %s", PrintValue(symbol).c_str(), PrintValue(symbol_addr_ptr).c_str()); symbol->replaceAllUsesWith(symbol_addr_ptr); return true; } bool IRForTarget::MaybeHandleCallArguments (CallInst *Old) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); if (log) log->Printf("MaybeHandleCallArguments(%s)", PrintValue(Old).c_str()); for (unsigned op_index = 0, num_ops = Old->getNumArgOperands(); op_index < num_ops; ++op_index) if (!MaybeHandleVariable(Old->getArgOperand(op_index))) // conservatively believe that this is a store { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't rewrite one of the arguments of a function call.\n"); return false; } return true; } bool IRForTarget::HandleObjCClass(Value *classlist_reference) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); GlobalVariable *global_variable = dyn_cast<GlobalVariable>(classlist_reference); if (!global_variable) return false; Constant *initializer = global_variable->getInitializer(); if (!initializer) return false; if (!initializer->hasName()) return false; StringRef name(initializer->getName()); lldb_private::ConstString name_cstr(name.str().c_str()); lldb::addr_t class_ptr = m_decl_map->GetSymbolAddress(name_cstr, lldb::eSymbolTypeObjCClass); if (log) log->Printf("Found reference to Objective-C class %s (0x%llx)", name_cstr.AsCString(), (unsigned long long)class_ptr); if (class_ptr == LLDB_INVALID_ADDRESS) return false; if (global_variable->use_begin() == global_variable->use_end()) return false; SmallVector<LoadInst *, 2> load_instructions; for (Value::use_iterator i = global_variable->use_begin(), e = global_variable->use_end(); i != e; ++i) { if (LoadInst *load_instruction = dyn_cast<LoadInst>(*i)) load_instructions.push_back(load_instruction); } if (load_instructions.empty()) return false; IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); Constant *class_addr = ConstantInt::get(intptr_ty, (uint64_t)class_ptr); for (LoadInst *load_instruction : load_instructions) { Constant *class_bitcast = ConstantExpr::getIntToPtr(class_addr, load_instruction->getType()); load_instruction->replaceAllUsesWith(class_bitcast); load_instruction->eraseFromParent(); } return true; } bool IRForTarget::RemoveCXAAtExit (BasicBlock &basic_block) { BasicBlock::iterator ii; std::vector<CallInst *> calls_to_remove; for (ii = basic_block.begin(); ii != basic_block.end(); ++ii) { Instruction &inst = *ii; CallInst *call = dyn_cast<CallInst>(&inst); // MaybeHandleCallArguments handles error reporting; we are silent here if (!call) continue; bool remove = false; llvm::Function *func = call->getCalledFunction(); if (func && func->getName() == "__cxa_atexit") remove = true; llvm::Value *val = call->getCalledValue(); if (val && val->getName() == "__cxa_atexit") remove = true; if (remove) calls_to_remove.push_back(call); } for (std::vector<CallInst *>::iterator ci = calls_to_remove.begin(), ce = calls_to_remove.end(); ci != ce; ++ci) { (*ci)->eraseFromParent(); } return true; } bool IRForTarget::ResolveCalls(BasicBlock &basic_block) { ///////////////////////////////////////////////////////////////////////// // Prepare the current basic block for execution in the remote process // BasicBlock::iterator ii; for (ii = basic_block.begin(); ii != basic_block.end(); ++ii) { Instruction &inst = *ii; CallInst *call = dyn_cast<CallInst>(&inst); // MaybeHandleCallArguments handles error reporting; we are silent here if (call && !MaybeHandleCallArguments(call)) return false; } return true; } bool IRForTarget::ResolveExternals (Function &llvm_function) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); for (Module::global_iterator global = m_module->global_begin(), end = m_module->global_end(); global != end; ++global) { if (!global) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: global variable is NULL"); return false; } std::string global_name = (*global).getName().str(); if (log) log->Printf("Examining %s, DeclForGlobalValue returns %p", global_name.c_str(), DeclForGlobal(global)); if (global_name.find("OBJC_IVAR") == 0) { if (!HandleSymbol(global)) { if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Couldn't find Objective-C indirect ivar symbol %s\n", global_name.c_str()); return false; } } else if (global_name.find("OBJC_CLASSLIST_REFERENCES_$") != global_name.npos) { if (!HandleObjCClass(global)) { if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Couldn't resolve the class for an Objective-C static method call\n"); return false; } } else if (global_name.find("OBJC_CLASSLIST_SUP_REFS_$") != global_name.npos) { if (!HandleObjCClass(global)) { if (m_error_stream) m_error_stream->Printf("Error [IRForTarget]: Couldn't resolve the class for an Objective-C static method call\n"); return false; } } else if (DeclForGlobal(global)) { if (!MaybeHandleVariable (global)) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't rewrite external variable %s\n", global_name.c_str()); return false; } } } return true; } bool IRForTarget::ReplaceStrings () { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); typedef std::map <GlobalVariable *, size_t> OffsetsTy; OffsetsTy offsets; for (Module::global_iterator gi = m_module->global_begin(), ge = m_module->global_end(); gi != ge; ++gi) { GlobalVariable *gv = gi; if (!gv->hasInitializer()) continue; Constant *gc = gv->getInitializer(); std::string str; if (gc->isNullValue()) { Type *gc_type = gc->getType(); ArrayType *gc_array_type = dyn_cast<ArrayType>(gc_type); if (!gc_array_type) continue; Type *gc_element_type = gc_array_type->getElementType(); IntegerType *gc_integer_type = dyn_cast<IntegerType>(gc_element_type); if (gc_integer_type->getBitWidth() != 8) continue; str = ""; } else { ConstantDataArray *gc_array = dyn_cast<ConstantDataArray>(gc); if (!gc_array) continue; if (!gc_array->isCString()) continue; if (log) log->Printf("Found a GlobalVariable with string initializer %s", PrintValue(gc).c_str()); str = gc_array->getAsString(); } offsets[gv] = m_data_allocator.GetStream().GetSize(); m_data_allocator.GetStream().Write(str.c_str(), str.length() + 1); } Type *char_ptr_ty = Type::getInt8PtrTy(m_module->getContext()); for (OffsetsTy::iterator oi = offsets.begin(), oe = offsets.end(); oi != oe; ++oi) { GlobalVariable *gv = oi->first; size_t offset = oi->second; Constant *new_initializer = BuildRelocation(char_ptr_ty, offset); if (log) log->Printf("Replacing GV %s with %s", PrintValue(gv).c_str(), PrintValue(new_initializer).c_str()); for (GlobalVariable::use_iterator ui = gv->use_begin(), ue = gv->use_end(); ui != ue; ++ui) { if (log) log->Printf("Found use %s", PrintValue(*ui).c_str()); ConstantExpr *const_expr = dyn_cast<ConstantExpr>(*ui); StoreInst *store_inst = dyn_cast<StoreInst>(*ui); if (const_expr) { if (const_expr->getOpcode() != Instruction::GetElementPtr) { if (log) log->Printf("Use (%s) of string variable is not a GetElementPtr constant", PrintValue(const_expr).c_str()); return false; } Constant *bit_cast = ConstantExpr::getBitCast(new_initializer, const_expr->getOperand(0)->getType()); Constant *new_gep = const_expr->getWithOperandReplaced(0, bit_cast); const_expr->replaceAllUsesWith(new_gep); } else if (store_inst) { Constant *bit_cast = ConstantExpr::getBitCast(new_initializer, store_inst->getValueOperand()->getType()); store_inst->setOperand(0, bit_cast); } else { if (log) log->Printf("Use (%s) of string variable is neither a constant nor a store", PrintValue(const_expr).c_str()); return false; } } gv->eraseFromParent(); } return true; } bool IRForTarget::ReplaceStaticLiterals (llvm::BasicBlock &basic_block) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); typedef SmallVector <Value*, 2> ConstantList; typedef SmallVector <llvm::Instruction*, 2> UserList; typedef ConstantList::iterator ConstantIterator; typedef UserList::iterator UserIterator; ConstantList static_constants; UserList static_users; for (BasicBlock::iterator ii = basic_block.begin(), ie = basic_block.end(); ii != ie; ++ii) { llvm::Instruction &inst = *ii; for (Instruction::op_iterator oi = inst.op_begin(), oe = inst.op_end(); oi != oe; ++oi) { Value *operand_val = oi->get(); ConstantFP *operand_constant_fp = dyn_cast<ConstantFP>(operand_val); if (operand_constant_fp/* && operand_constant_fp->getType()->isX86_FP80Ty()*/) { static_constants.push_back(operand_val); static_users.push_back(ii); } } } ConstantIterator constant_iter; UserIterator user_iter; for (constant_iter = static_constants.begin(), user_iter = static_users.begin(); constant_iter != static_constants.end(); ++constant_iter, ++user_iter) { Value *operand_val = *constant_iter; llvm::Instruction *inst = *user_iter; ConstantFP *operand_constant_fp = dyn_cast<ConstantFP>(operand_val); if (operand_constant_fp) { Type *operand_type = operand_constant_fp->getType(); APFloat operand_apfloat = operand_constant_fp->getValueAPF(); APInt operand_apint = operand_apfloat.bitcastToAPInt(); const uint8_t* operand_raw_data = (const uint8_t*)operand_apint.getRawData(); size_t operand_data_size = operand_apint.getBitWidth() / 8; if (log) { std::string s; raw_string_ostream ss(s); for (size_t index = 0; index < operand_data_size; ++index) { ss << (uint32_t)operand_raw_data[index]; ss << " "; } ss.flush(); log->Printf("Found ConstantFP with size %lu and raw data %s", operand_data_size, s.c_str()); } lldb_private::DataBufferHeap data(operand_data_size, 0); if (lldb::endian::InlHostByteOrder() != m_data_allocator.GetStream().GetByteOrder()) { uint8_t *data_bytes = data.GetBytes(); for (size_t index = 0; index < operand_data_size; ++index) { data_bytes[index] = operand_raw_data[operand_data_size - (1 + index)]; } } else { memcpy(data.GetBytes(), operand_raw_data, operand_data_size); } uint64_t offset = m_data_allocator.GetStream().GetSize(); size_t align = m_target_data->getPrefTypeAlignment(operand_type); const size_t mask = (align - 1); uint64_t aligned_offset = (offset + mask) & ~mask; m_data_allocator.GetStream().PutNHex8(aligned_offset - offset, 0); offset = aligned_offset; m_data_allocator.GetStream().Write(data.GetBytes(), operand_data_size); llvm::Type *fp_ptr_ty = operand_constant_fp->getType()->getPointerTo(); Constant *new_pointer = BuildRelocation(fp_ptr_ty, aligned_offset); llvm::LoadInst *fp_load = new llvm::LoadInst(new_pointer, "fp_load", inst); operand_constant_fp->replaceAllUsesWith(fp_load); } } return true; } static bool isGuardVariableRef(Value *V) { Constant *Old = NULL; if (!(Old = dyn_cast<Constant>(V))) return false; ConstantExpr *CE = NULL; if ((CE = dyn_cast<ConstantExpr>(V))) { if (CE->getOpcode() != Instruction::BitCast) return false; Old = CE->getOperand(0); } GlobalVariable *GV = dyn_cast<GlobalVariable>(Old); if (!GV || !GV->hasName() || !GV->getName().startswith("_ZGV")) return false; return true; } void IRForTarget::TurnGuardLoadIntoZero(llvm::Instruction* guard_load) { Constant* zero(ConstantInt::get(Type::getInt8Ty(m_module->getContext()), 0, true)); Value::use_iterator ui; for (ui = guard_load->use_begin(); ui != guard_load->use_end(); ++ui) { if (isa<Constant>(*ui)) { // do nothing for the moment } else { ui->replaceUsesOfWith(guard_load, zero); } } guard_load->eraseFromParent(); } static void ExciseGuardStore(Instruction* guard_store) { guard_store->eraseFromParent(); } bool IRForTarget::RemoveGuards(BasicBlock &basic_block) { /////////////////////////////////////////////////////// // Eliminate any reference to guard variables found. // BasicBlock::iterator ii; typedef SmallVector <Instruction*, 2> InstrList; typedef InstrList::iterator InstrIterator; InstrList guard_loads; InstrList guard_stores; for (ii = basic_block.begin(); ii != basic_block.end(); ++ii) { Instruction &inst = *ii; if (LoadInst *load = dyn_cast<LoadInst>(&inst)) if (isGuardVariableRef(load->getPointerOperand())) guard_loads.push_back(&inst); if (StoreInst *store = dyn_cast<StoreInst>(&inst)) if (isGuardVariableRef(store->getPointerOperand())) guard_stores.push_back(&inst); } InstrIterator iter; for (iter = guard_loads.begin(); iter != guard_loads.end(); ++iter) TurnGuardLoadIntoZero(*iter); for (iter = guard_stores.begin(); iter != guard_stores.end(); ++iter) ExciseGuardStore(*iter); return true; } // This function does not report errors; its callers are responsible. bool IRForTarget::UnfoldConstant(Constant *old_constant, FunctionValueCache &value_maker, FunctionValueCache &entry_instruction_finder) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); Value::use_iterator ui; SmallVector<User*, 16> users; // We do this because the use list might change, invalidating our iterator. // Much better to keep a work list ourselves. for (ui = old_constant->use_begin(); ui != old_constant->use_end(); ++ui) users.push_back(*ui); for (size_t i = 0; i < users.size(); ++i) { User *user = users[i]; if (Constant *constant = dyn_cast<Constant>(user)) { // synthesize a new non-constant equivalent of the constant if (ConstantExpr *constant_expr = dyn_cast<ConstantExpr>(constant)) { switch (constant_expr->getOpcode()) { default: if (log) log->Printf("Unhandled constant expression type: \"%s\"", PrintValue(constant_expr).c_str()); return false; case Instruction::BitCast: { FunctionValueCache bit_cast_maker ([&value_maker, &entry_instruction_finder, old_constant, constant_expr] (llvm::Function *function)->llvm::Value* { // UnaryExpr // OperandList[0] is value if (constant_expr->getOperand(0) != old_constant) return constant_expr; return new BitCastInst(value_maker.GetValue(function), constant_expr->getType(), "", llvm::cast<Instruction>(entry_instruction_finder.GetValue(function))); }); if (!UnfoldConstant(constant_expr, bit_cast_maker, entry_instruction_finder)) return false; } break; case Instruction::GetElementPtr: { // GetElementPtrConstantExpr // OperandList[0] is base // OperandList[1]... are indices FunctionValueCache get_element_pointer_maker ([&value_maker, &entry_instruction_finder, old_constant, constant_expr] (llvm::Function *function)->llvm::Value* { Value *ptr = constant_expr->getOperand(0); if (ptr == old_constant) ptr = value_maker.GetValue(function); std::vector<Value*> index_vector; unsigned operand_index; unsigned num_operands = constant_expr->getNumOperands(); for (operand_index = 1; operand_index < num_operands; ++operand_index) { Value *operand = constant_expr->getOperand(operand_index); if (operand == old_constant) operand = value_maker.GetValue(function); index_vector.push_back(operand); } ArrayRef <Value*> indices(index_vector); return GetElementPtrInst::Create(ptr, indices, "", llvm::cast<Instruction>(entry_instruction_finder.GetValue(function))); }); if (!UnfoldConstant(constant_expr, get_element_pointer_maker, entry_instruction_finder)) return false; } break; } } else { if (log) log->Printf("Unhandled constant type: \"%s\"", PrintValue(constant).c_str()); return false; } } else { if (Instruction *inst = llvm::dyn_cast<Instruction>(user)) { inst->replaceUsesOfWith(old_constant, value_maker.GetValue(inst->getParent()->getParent())); } else { if (log) log->Printf("Unhandled non-constant type: \"%s\"", PrintValue(user).c_str()); return false; } } } if (!isa<GlobalValue>(old_constant)) { old_constant->destroyConstant(); } return true; } bool IRForTarget::ReplaceVariables (Function &llvm_function) { if (!m_resolve_vars) return true; lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); m_decl_map->DoStructLayout(); if (log) log->Printf("Element arrangement:"); uint32_t num_elements; uint32_t element_index; size_t size; off_t alignment; if (!m_decl_map->GetStructInfo (num_elements, size, alignment)) return false; Function::arg_iterator iter(llvm_function.getArgumentList().begin()); if (iter == llvm_function.getArgumentList().end()) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes no arguments (should take at least a struct pointer)"); return false; } Argument *argument = iter; if (argument->getName().equals("this")) { ++iter; if (iter == llvm_function.getArgumentList().end()) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes only 'this' argument (should take a struct pointer too)"); return false; } argument = iter; } else if (argument->getName().equals("self")) { ++iter; if (iter == llvm_function.getArgumentList().end()) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes only 'self' argument (should take '_cmd' and a struct pointer too)"); return false; } if (!iter->getName().equals("_cmd")) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes '%s' after 'self' argument (should take '_cmd')", iter->getName().str().c_str()); return false; } ++iter; if (iter == llvm_function.getArgumentList().end()) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes only 'self' and '_cmd' arguments (should take a struct pointer too)"); return false; } argument = iter; } if (!argument->getName().equals("$__lldb_arg")) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Wrapper takes an argument named '%s' instead of the struct pointer", argument->getName().str().c_str()); return false; } if (log) log->Printf("Arg: \"%s\"", PrintValue(argument).c_str()); BasicBlock &entry_block(llvm_function.getEntryBlock()); Instruction *FirstEntryInstruction(entry_block.getFirstNonPHIOrDbg()); if (!FirstEntryInstruction) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't find the first instruction in the wrapper for use in rewriting"); return false; } LLVMContext &context(m_module->getContext()); IntegerType *offset_type(Type::getInt32Ty(context)); if (!offset_type) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't produce an offset type"); return false; } for (element_index = 0; element_index < num_elements; ++element_index) { const clang::NamedDecl *decl = NULL; Value *value = NULL; off_t offset; lldb_private::ConstString name; if (!m_decl_map->GetStructElement (decl, value, offset, name, element_index)) { if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Structure information is incomplete"); return false; } if (log) log->Printf(" \"%s\" (\"%s\") placed at %" PRId64, name.GetCString(), decl->getNameAsString().c_str(), offset); if (value) { if (log) log->Printf(" Replacing [%s]", PrintValue(value).c_str()); FunctionValueCache body_result_maker ([this, name, offset_type, offset, argument, value] (llvm::Function *function)->llvm::Value * { // Per the comment at ASTResultSynthesizer::SynthesizeBodyResult, in cases where the result // variable is an rvalue, we have to synthesize a dereference of the appropriate structure // entry in order to produce the static variable that the AST thinks it is accessing. llvm::Instruction *entry_instruction = llvm::cast<Instruction>(m_entry_instruction_finder.GetValue(function)); ConstantInt *offset_int(ConstantInt::get(offset_type, offset, true)); GetElementPtrInst *get_element_ptr = GetElementPtrInst::Create(argument, offset_int, "", entry_instruction); if (name == m_result_name && !m_result_is_pointer) { BitCastInst *bit_cast = new BitCastInst(get_element_ptr, value->getType()->getPointerTo(), "", entry_instruction); LoadInst *load = new LoadInst(bit_cast, "", entry_instruction); return load; } else { BitCastInst *bit_cast = new BitCastInst(get_element_ptr, value->getType(), "", entry_instruction); return bit_cast; } }); if (Constant *constant = dyn_cast<Constant>(value)) { UnfoldConstant(constant, body_result_maker, m_entry_instruction_finder); } else if (Instruction *instruction = dyn_cast<Instruction>(value)) { value->replaceAllUsesWith(body_result_maker.GetValue(instruction->getParent()->getParent())); } else { if (log) log->Printf("Unhandled non-constant type: \"%s\"", PrintValue(value).c_str()); return false; } if (GlobalVariable *var = dyn_cast<GlobalVariable>(value)) var->eraseFromParent(); } } if (log) log->Printf("Total structure [align %" PRId64 ", size %lu]", alignment, size); return true; } llvm::Constant * IRForTarget::BuildRelocation(llvm::Type *type, uint64_t offset) { IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); llvm::Constant *offset_int = ConstantInt::get(intptr_ty, offset); llvm::Constant *offset_array[1]; offset_array[0] = offset_int; llvm::ArrayRef<llvm::Constant *> offsets(offset_array, 1); llvm::Constant *reloc_getelementptr = ConstantExpr::getGetElementPtr(m_reloc_placeholder, offsets); llvm::Constant *reloc_getbitcast = ConstantExpr::getBitCast(reloc_getelementptr, type); return reloc_getbitcast; } bool IRForTarget::CompleteDataAllocation () { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); if (!m_data_allocator.GetStream().GetSize()) return true; lldb::addr_t allocation = m_data_allocator.Allocate(); if (log) { if (allocation) log->Printf("Allocated static data at 0x%llx", (unsigned long long)allocation); else log->Printf("Failed to allocate static data"); } if (!allocation || allocation == LLDB_INVALID_ADDRESS) return false; IntegerType *intptr_ty = Type::getIntNTy(m_module->getContext(), (m_module->getPointerSize() == Module::Pointer64) ? 64 : 32); Constant *relocated_addr = ConstantInt::get(intptr_ty, (uint64_t)allocation); Constant *relocated_bitcast = ConstantExpr::getIntToPtr(relocated_addr, llvm::Type::getInt8PtrTy(m_module->getContext())); m_reloc_placeholder->replaceAllUsesWith(relocated_bitcast); m_reloc_placeholder->eraseFromParent(); return true; } bool IRForTarget::StripAllGVs (Module &llvm_module) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); std::vector<GlobalVariable *> global_vars; std::set<GlobalVariable *>erased_vars; bool erased = true; while (erased) { erased = false; for (Module::global_iterator gi = llvm_module.global_begin(), ge = llvm_module.global_end(); gi != ge; ++gi) { GlobalVariable *global_var = dyn_cast<GlobalVariable>(gi); global_var->removeDeadConstantUsers(); if (global_var->use_empty()) { if (log) log->Printf("Did remove %s", PrintValue(global_var).c_str()); global_var->eraseFromParent(); erased = true; break; } } } for (Module::global_iterator gi = llvm_module.global_begin(), ge = llvm_module.global_end(); gi != ge; ++gi) { GlobalVariable *global_var = dyn_cast<GlobalVariable>(gi); GlobalValue::use_iterator ui = global_var->use_begin(); if (log) log->Printf("Couldn't remove %s because of %s", PrintValue(global_var).c_str(), PrintValue(*ui).c_str()); } return true; } bool IRForTarget::runOnModule (Module &llvm_module) { lldb_private::Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS)); m_module = &llvm_module; m_target_data.reset(new DataLayout(m_module)); if (log) { std::string s; raw_string_ostream oss(s); m_module->print(oss, NULL); oss.flush(); log->Printf("Module as passed in to IRForTarget: \n\"%s\"", s.c_str()); } Function* main_function = m_module->getFunction(StringRef(m_func_name.c_str())); if (!main_function) { if (log) log->Printf("Couldn't find \"%s()\" in the module", m_func_name.c_str()); if (m_error_stream) m_error_stream->Printf("Internal error [IRForTarget]: Couldn't find wrapper '%s' in the module", m_func_name.c_str()); return false; } if (!FixFunctionLinkage (*main_function)) { if (log) log->Printf("Couldn't fix the linkage for the function"); return false; } llvm::Type *intptr_ty = Type::getInt8Ty(m_module->getContext()); m_reloc_placeholder = new llvm::GlobalVariable((*m_module), intptr_ty, false /* IsConstant */, GlobalVariable::InternalLinkage, Constant::getNullValue(intptr_ty), "reloc_placeholder", NULL /* InsertBefore */, GlobalVariable::NotThreadLocal /* ThreadLocal */, 0 /* AddressSpace */); //////////////////////////////////////////////////////////// // Replace $__lldb_expr_result with a persistent variable // if (!CreateResultVariable(*main_function)) { if (log) log->Printf("CreateResultVariable() failed"); // CreateResultVariable() reports its own errors, so we don't do so here return false; } if (log && log->GetVerbose()) { std::string s; raw_string_ostream oss(s); m_module->print(oss, NULL); oss.flush(); log->Printf("Module after creating the result variable: \n\"%s\"", s.c_str()); } for (Module::iterator fi = m_module->begin(), fe = m_module->end(); fi != fe; ++fi) { llvm::Function *function = fi; if (function->begin() == function->end()) continue; Function::iterator bbi; for (bbi = function->begin(); bbi != function->end(); ++bbi) { if (!RemoveGuards(*bbi)) { if (log) log->Printf("RemoveGuards() failed"); // RemoveGuards() reports its own errors, so we don't do so here return false; } if (!RewritePersistentAllocs(*bbi)) { if (log) log->Printf("RewritePersistentAllocs() failed"); // RewritePersistentAllocs() reports its own errors, so we don't do so here return false; } if (!RemoveCXAAtExit(*bbi)) { if (log) log->Printf("RemoveCXAAtExit() failed"); // RemoveCXAAtExit() reports its own errors, so we don't do so here return false; } } } /////////////////////////////////////////////////////////////////////////////// // Fix all Objective-C constant strings to use NSStringWithCString:encoding: // if (!RewriteObjCConstStrings()) { if (log) log->Printf("RewriteObjCConstStrings() failed"); // RewriteObjCConstStrings() reports its own errors, so we don't do so here return false; } /////////////////////////////// // Resolve function pointers // if (!ResolveFunctionPointers(llvm_module)) { if (log) log->Printf("ResolveFunctionPointers() failed"); // ResolveFunctionPointers() reports its own errors, so we don't do so here return false; } for (Module::iterator fi = m_module->begin(), fe = m_module->end(); fi != fe; ++fi) { llvm::Function *function = fi; for (llvm::Function::iterator bbi = function->begin(), bbe = function->end(); bbi != bbe; ++bbi) { if (!RewriteObjCSelectors(*bbi)) { if (log) log->Printf("RewriteObjCSelectors() failed"); // RewriteObjCSelectors() reports its own errors, so we don't do so here return false; } } } for (Module::iterator fi = m_module->begin(), fe = m_module->end(); fi != fe; ++fi) { llvm::Function *function = fi; for (llvm::Function::iterator bbi = function->begin(), bbe = function->end(); bbi != bbe; ++bbi) { if (!ResolveCalls(*bbi)) { if (log) log->Printf("ResolveCalls() failed"); // ResolveCalls() reports its own errors, so we don't do so here return false; } if (!ReplaceStaticLiterals(*bbi)) { if (log) log->Printf("ReplaceStaticLiterals() failed"); return false; } } } //////////////////////////////////////////////////////////////////////// // Run function-level passes that only make sense on the main function // if (!ResolveExternals(*main_function)) { if (log) log->Printf("ResolveExternals() failed"); // ResolveExternals() reports its own errors, so we don't do so here return false; } if (!ReplaceVariables(*main_function)) { if (log) log->Printf("ReplaceVariables() failed"); // ReplaceVariables() reports its own errors, so we don't do so here return false; } if (!ReplaceStrings()) { if (log) log->Printf("ReplaceStrings() failed"); return false; } if (!CompleteDataAllocation()) { if (log) log->Printf("CompleteDataAllocation() failed"); return false; } if (!StripAllGVs(llvm_module)) { if (log) log->Printf("StripAllGVs() failed"); } if (log && log->GetVerbose()) { std::string s; raw_string_ostream oss(s); m_module->print(oss, NULL); oss.flush(); log->Printf("Module after preparing for execution: \n\"%s\"", s.c_str()); } return true; } void IRForTarget::assignPassManager (PMStack &pass_mgr_stack, PassManagerType pass_mgr_type) { } PassManagerType IRForTarget::getPotentialPassManagerType() const { return PMT_ModulePassManager; }