maxjhandsome
/
llvm-project
forked from OSchip/llvm-project
1
0
Fork 0
Code Issues Pull Requests Packages Releases Wiki Activity
llvm-project/lldb/source/Expression/IRInterpreter.cpp

1396 lines
50 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//===-- IRInterpreter.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/Core/DataEncoder.h"
#include "lldb/Core/Log.h"
#include "lldb/Core/ValueObjectConstResult.h"
#include "lldb/Expression/ClangExpressionDeclMap.h"
#include "lldb/Expression/IRForTarget.h"
#include "lldb/Expression/IRInterpreter.h"
#include "llvm/Constants.h"
#include "llvm/Function.h"
#include "llvm/Instructions.h"
#include "llvm/Module.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/Target/TargetData.h"
#include <map>
using namespace llvm;
IRInterpreter::IRInterpreter(lldb_private::ClangExpressionDeclMap &decl_map,
lldb_private::Stream *error_stream) :
m_decl_map(decl_map),
m_error_stream(error_stream)
{
}
IRInterpreter::~IRInterpreter()
{
}
static std::string
PrintValue(const Value *value, bool truncate = false)
{
std::string s;
raw_string_ostream rso(s);
value->print(rso);
rso.flush();
if (truncate)
s.resize(s.length() - 1);
size_t offset;
while ((offset = s.find('\n')) != s.npos)
s.erase(offset, 1);
while (s[0] == ' ' || s[0] == '\t')
s.erase(0, 1);
return s;
}
static std::string
PrintType(const 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;
}
typedef lldb::SharedPtr <lldb_private::DataEncoder>::Type DataEncoderSP;
typedef lldb::SharedPtr <lldb_private::DataExtractor>::Type DataExtractorSP;
class Memory
{
public:
typedef uint32_t index_t;
struct Allocation
{
// m_virtual_address is always the address of the variable in the virtual memory
// space provided by Memory.
//
// m_origin is always non-NULL and describes the source of the data (possibly
// m_data if this allocation is the authoritative source).
//
// Possible value configurations:
//
// Allocation type getValueType() getContextType() m_origin->GetScalar() m_data
// =========================================================================================================================
// FileAddress eValueTypeFileAddress eContextTypeInvalid A location in a binary NULL
// image
//
// LoadAddress eValueTypeLoadAddress eContextTypeInvalid A location in the target's NULL
// virtual memory
//
// Alloca eValueTypeHostAddress eContextTypeInvalid == m_data->GetBytes() Deleted at end of
// execution
//
// PersistentVar eValueTypeHostAddress eContextTypeClangType A persistent variable's NULL
// location in LLDB's memory
//
// Register [ignored] eContextTypeRegister [ignored] Flushed to the register
// at the end of execution
lldb::addr_t m_virtual_address;
size_t m_extent;
lldb_private::Value m_origin;
lldb::DataBufferSP m_data;
Allocation (lldb::addr_t virtual_address,
size_t extent,
lldb::DataBufferSP data) :
m_virtual_address(virtual_address),
m_extent(extent),
m_data(data)
{
}
Allocation (const Allocation &allocation) :
m_virtual_address(allocation.m_virtual_address),
m_extent(allocation.m_extent),
m_origin(allocation.m_origin),
m_data(allocation.m_data)
{
}
};
typedef lldb::SharedPtr <Allocation>::Type AllocationSP;
struct Region
{
AllocationSP m_allocation;
uint64_t m_base;
uint64_t m_extent;
Region () :
m_allocation(),
m_base(0),
m_extent(0)
{
}
Region (AllocationSP allocation, uint64_t base, uint64_t extent) :
m_allocation(allocation),
m_base(base),
m_extent(extent)
{
}
Region (const Region &region) :
m_allocation(region.m_allocation),
m_base(region.m_base),
m_extent(region.m_extent)
{
}
bool IsValid ()
{
return m_allocation != NULL;
}
bool IsInvalid ()
{
return m_allocation == NULL;
}
};
typedef std::vector <AllocationSP> MemoryMap;
private:
lldb::addr_t m_addr_base;
lldb::addr_t m_addr_max;
MemoryMap m_memory;
lldb::ByteOrder m_byte_order;
lldb::addr_t m_addr_byte_size;
TargetData &m_target_data;
lldb_private::ClangExpressionDeclMap &m_decl_map;
MemoryMap::iterator LookupInternal (lldb::addr_t addr)
{
for (MemoryMap::iterator i = m_memory.begin(), e = m_memory.end();
i != e;
++i)
{
if ((*i)->m_virtual_address <= addr &&
(*i)->m_virtual_address + (*i)->m_extent > addr)
return i;
}
return m_memory.end();
}
public:
Memory (TargetData &target_data,
lldb_private::ClangExpressionDeclMap &decl_map,
lldb::addr_t alloc_start,
lldb::addr_t alloc_max) :
m_addr_base(alloc_start),
m_addr_max(alloc_max),
m_target_data(target_data),
m_decl_map(decl_map)
{
m_byte_order = (target_data.isLittleEndian() ? lldb::eByteOrderLittle : lldb::eByteOrderBig);
m_addr_byte_size = (target_data.getPointerSize());
}
Region Malloc (size_t size, size_t align)
{
lldb::DataBufferSP data(new lldb_private::DataBufferHeap(size, 0));
if (data)
{
index_t index = m_memory.size();
const size_t mask = (align - 1);
m_addr_base += mask;
m_addr_base &= ~mask;
if (m_addr_base + size < m_addr_base ||
m_addr_base + size > m_addr_max)
return Region();
uint64_t base = m_addr_base;
m_memory.push_back(AllocationSP(new Allocation(base, size, data)));
m_addr_base += size;
AllocationSP alloc = m_memory[index];
alloc->m_origin.GetScalar() = (unsigned long long)data->GetBytes();
alloc->m_origin.SetContext(lldb_private::Value::eContextTypeInvalid, NULL);
alloc->m_origin.SetValueType(lldb_private::Value::eValueTypeHostAddress);
return Region(alloc, base, size);
}
return Region();
}
Region Malloc (Type *type)
{
return Malloc (m_target_data.getTypeAllocSize(type),
m_target_data.getPrefTypeAlignment(type));
}
Region Place (Type *type, lldb::addr_t base, lldb_private::Value &value)
{
index_t index = m_memory.size();
size_t size = m_target_data.getTypeAllocSize(type);
m_memory.push_back(AllocationSP(new Allocation(base, size, lldb::DataBufferSP())));
AllocationSP alloc = m_memory[index];
alloc->m_origin = value;
return Region(alloc, base, size);
}
void Free (lldb::addr_t addr)
{
MemoryMap::iterator i = LookupInternal (addr);
if (i != m_memory.end())
m_memory.erase(i);
}
Region Lookup (lldb::addr_t addr, Type *type)
{
MemoryMap::iterator i = LookupInternal(addr);
if (i == m_memory.end())
return Region();
size_t size = m_target_data.getTypeStoreSize(type);
return Region(*i, addr, size);
}
DataEncoderSP GetEncoder (Region region)
{
if (region.m_allocation->m_origin.GetValueType() != lldb_private::Value::eValueTypeHostAddress)
return DataEncoderSP();
lldb::DataBufferSP buffer = region.m_allocation->m_data;
if (!buffer)
return DataEncoderSP();
size_t base_offset = (size_t)(region.m_base - region.m_allocation->m_virtual_address);
return DataEncoderSP(new lldb_private::DataEncoder(buffer->GetBytes() + base_offset, region.m_extent, m_byte_order, m_addr_byte_size));
}
DataExtractorSP GetExtractor (Region region)
{
if (region.m_allocation->m_origin.GetValueType() != lldb_private::Value::eValueTypeHostAddress)
return DataExtractorSP();
lldb::DataBufferSP buffer = region.m_allocation->m_data;
size_t base_offset = (size_t)(region.m_base - region.m_allocation->m_virtual_address);
if (buffer)
return DataExtractorSP(new lldb_private::DataExtractor(buffer->GetBytes() + base_offset, region.m_extent, m_byte_order, m_addr_byte_size));
else
return DataExtractorSP(new lldb_private::DataExtractor((uint8_t*)region.m_allocation->m_origin.GetScalar().ULongLong() + base_offset, region.m_extent, m_byte_order, m_addr_byte_size));
}
lldb_private::Value GetAccessTarget(lldb::addr_t addr)
{
MemoryMap::iterator i = LookupInternal(addr);
if (i == m_memory.end())
return lldb_private::Value();
lldb_private::Value target = (*i)->m_origin;
if (target.GetContextType() == lldb_private::Value::eContextTypeRegisterInfo)
{
target.SetContext(lldb_private::Value::eContextTypeInvalid, NULL);
target.SetValueType(lldb_private::Value::eValueTypeHostAddress);
target.GetScalar() = (unsigned long long)(*i)->m_data->GetBytes();
}
target.GetScalar() += (addr - (*i)->m_virtual_address);
return target;
}
bool Write (lldb::addr_t addr, const uint8_t *data, size_t length)
{
lldb_private::Value target = GetAccessTarget(addr);
return m_decl_map.WriteTarget(target, data, length);
}
bool Read (uint8_t *data, lldb::addr_t addr, size_t length)
{
lldb_private::Value target = GetAccessTarget(addr);
return m_decl_map.ReadTarget(data, target, length);
}
std::string PrintData (lldb::addr_t addr, size_t length)
{
lldb_private::Value target = GetAccessTarget(addr);
lldb_private::DataBufferHeap buf(length, 0);
if (!m_decl_map.ReadTarget(buf.GetBytes(), target, length))
return std::string("<couldn't read data>");
lldb_private::StreamString ss;
for (size_t i = 0; i < length; i++)
{
if ((!(i & 0xf)) && i)
ss.Printf("%02hhx - ", buf.GetBytes()[i]);
else
ss.Printf("%02hhx ", buf.GetBytes()[i]);
}
return ss.GetString();
}
std::string SummarizeRegion (Region &region)
{
lldb_private::StreamString ss;
lldb_private::Value base = GetAccessTarget(region.m_base);
ss.Printf("%llx [%s - %s %llx]",
region.m_base,
lldb_private::Value::GetValueTypeAsCString(base.GetValueType()),
lldb_private::Value::GetContextTypeAsCString(base.GetContextType()),
base.GetScalar().ULongLong());
ss.Printf(" %s", PrintData(region.m_base, region.m_extent).c_str());
return ss.GetString();
}
};
class InterpreterStackFrame
{
public:
typedef std::map <const Value*, Memory::Region> ValueMap;
ValueMap m_values;
Memory &m_memory;
TargetData &m_target_data;
lldb_private::ClangExpressionDeclMap &m_decl_map;
const BasicBlock *m_bb;
BasicBlock::const_iterator m_ii;
BasicBlock::const_iterator m_ie;
lldb::ByteOrder m_byte_order;
size_t m_addr_byte_size;
InterpreterStackFrame (TargetData &target_data,
Memory &memory,
lldb_private::ClangExpressionDeclMap &decl_map) :
m_target_data (target_data),
m_memory (memory),
m_decl_map (decl_map)
{
m_byte_order = (target_data.isLittleEndian() ? lldb::eByteOrderLittle : lldb::eByteOrderBig);
m_addr_byte_size = (target_data.getPointerSize());
}
void Jump (const BasicBlock *bb)
{
m_bb = bb;
m_ii = m_bb->begin();
m_ie = m_bb->end();
}
bool Cache (Memory::AllocationSP allocation, Type *type)
{
if (allocation->m_origin.GetContextType() != lldb_private::Value::eContextTypeRegisterInfo)
return false;
return m_decl_map.ReadTarget(allocation->m_data->GetBytes(), allocation->m_origin, allocation->m_data->GetByteSize());
}
std::string SummarizeValue (const Value *value)
{
lldb_private::StreamString ss;
ss.Printf("%s", PrintValue(value).c_str());
ValueMap::iterator i = m_values.find(value);
if (i != m_values.end())
{
Memory::Region region = i->second;
ss.Printf(" %s", m_memory.SummarizeRegion(region).c_str());
}
return ss.GetString();
}
bool AssignToMatchType (lldb_private::Scalar &scalar, uint64_t u64value, Type *type)
{
size_t type_size = m_target_data.getTypeStoreSize(type);
switch (type_size)
{
case 1:
scalar = (uint8_t)u64value;
break;
case 2:
scalar = (uint16_t)u64value;
break;
case 4:
scalar = (uint32_t)u64value;
break;
case 8:
scalar = (uint64_t)u64value;
break;
default:
return false;
}
return true;
}
bool EvaluateValue (lldb_private::Scalar &scalar, const Value *value, Module &module)
{
const Constant *constant = dyn_cast<Constant>(value);
if (constant)
{
if (const ConstantInt *constant_int = dyn_cast<ConstantInt>(constant))
{
return AssignToMatchType(scalar, constant_int->getLimitedValue(), value->getType());
}
}
else
{
Memory::Region region = ResolveValue(value, module);
DataExtractorSP value_extractor = m_memory.GetExtractor(region);
if (!value_extractor)
return false;
size_t value_size = m_target_data.getTypeStoreSize(value->getType());
uint32_t offset = 0;
uint64_t u64value = value_extractor->GetMaxU64(&offset, value_size);
return AssignToMatchType(scalar, u64value, value->getType());
}
return false;
}
bool AssignValue (const Value *value, lldb_private::Scalar &scalar, Module &module)
{
Memory::Region region = ResolveValue (value, module);
lldb_private::Scalar cast_scalar;
if (!AssignToMatchType(cast_scalar, scalar.GetRawBits64(0), value->getType()))
return false;
lldb_private::DataBufferHeap buf(cast_scalar.GetByteSize(), 0);
lldb_private::Error err;
if (!cast_scalar.GetAsMemoryData(buf.GetBytes(), buf.GetByteSize(), m_byte_order, err))
return false;
DataEncoderSP region_encoder = m_memory.GetEncoder(region);
memcpy(region_encoder->GetDataStart(), buf.GetBytes(), buf.GetByteSize());
return true;
}
bool ResolveConstant (Memory::Region &region, const Constant *constant)
{
size_t constant_size = m_target_data.getTypeStoreSize(constant->getType());
if (const ConstantInt *constant_int = dyn_cast<ConstantInt>(constant))
{
const uint64_t *raw_data = constant_int->getValue().getRawData();
return m_memory.Write(region.m_base, (const uint8_t*)raw_data, constant_size);
}
if (const ConstantFP *constant_fp = dyn_cast<ConstantFP>(constant))
{
const uint64_t *raw_data = constant_fp->getValueAPF().bitcastToAPInt().getRawData();
return m_memory.Write(region.m_base, (const uint8_t*)raw_data, constant_size);
}
return false;
}
Memory::Region ResolveValue (const Value *value, Module &module)
{
ValueMap::iterator i = m_values.find(value);
if (i != m_values.end())
return i->second;
const GlobalValue *global_value = dyn_cast<GlobalValue>(value);
// Attempt to resolve the value using the program's data.
// If it is, the values to be created are:
//
// data_region - a region of memory in which the variable's data resides.
// ref_region - a region of memory in which its address (i.e., &var) resides.
// In the JIT case, this region would be a member of the struct passed in.
// pointer_region - a region of memory in which the address of the pointer
// resides. This is an IR-level variable.
do
{
if (!global_value)
break;
lldb::LogSP log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS));
clang::NamedDecl *decl = IRForTarget::DeclForGlobal(global_value, &module);
if (!decl)
break;
lldb_private::Value resolved_value = m_decl_map.LookupDecl(decl);
if (resolved_value.GetScalar().GetType() != lldb_private::Scalar::e_void)
{
if (resolved_value.GetContextType() == lldb_private::Value::eContextTypeRegisterInfo)
{
Memory::Region data_region = m_memory.Malloc(value->getType());
data_region.m_allocation->m_origin = resolved_value;
Memory::Region ref_region = m_memory.Malloc(value->getType());
Memory::Region pointer_region = m_memory.Malloc(value->getType());
if (!Cache(data_region.m_allocation, value->getType()))
return Memory::Region();
if (ref_region.IsInvalid())
return Memory::Region();
if (pointer_region.IsInvalid())
return Memory::Region();
DataEncoderSP ref_encoder = m_memory.GetEncoder(ref_region);
if (ref_encoder->PutAddress(0, data_region.m_base) == UINT32_MAX)
return Memory::Region();
DataEncoderSP pointer_encoder = m_memory.GetEncoder(pointer_region);
if (pointer_encoder->PutAddress(0, ref_region.m_base) == UINT32_MAX)
return Memory::Region();
m_values[value] = pointer_region;
return pointer_region;
}
else if (isa<clang::FunctionDecl>(decl))
{
if (log)
log->Printf("The interpreter does not handle function pointers at the moment");
return Memory::Region();
}
else
{
Memory::Region data_region = m_memory.Place(value->getType(), resolved_value.GetScalar().ULongLong(), resolved_value);
Memory::Region ref_region = m_memory.Malloc(value->getType());
Memory::Region pointer_region = m_memory.Malloc(value->getType());
if (ref_region.IsInvalid())
return Memory::Region();
if (pointer_region.IsInvalid())
return Memory::Region();
DataEncoderSP ref_encoder = m_memory.GetEncoder(ref_region);
if (ref_encoder->PutAddress(0, data_region.m_base) == UINT32_MAX)
return Memory::Region();
DataEncoderSP pointer_encoder = m_memory.GetEncoder(pointer_region);
if (pointer_encoder->PutAddress(0, ref_region.m_base) == UINT32_MAX)
return Memory::Region();
m_values[value] = pointer_region;
if (log)
{
log->Printf("Made an allocation for %s", PrintValue(global_value).c_str());
log->Printf(" Data contents : %s", m_memory.PrintData(data_region.m_base, data_region.m_extent).c_str());
log->Printf(" Data region : %llx", (unsigned long long)data_region.m_base);
log->Printf(" Ref region : %llx", (unsigned long long)ref_region.m_base);
log->Printf(" Pointer region : %llx", (unsigned long long)pointer_region.m_base);
}
return pointer_region;
}
}
}
while(0);
// Fall back and allocate space [allocation type Alloca]
Type *type = value->getType();
lldb::ValueSP backing_value(new lldb_private::Value);
Memory::Region data_region = m_memory.Malloc(type);
data_region.m_allocation->m_origin.GetScalar() = (unsigned long long)data_region.m_allocation->m_data->GetBytes();
data_region.m_allocation->m_origin.SetContext(lldb_private::Value::eContextTypeInvalid, NULL);
data_region.m_allocation->m_origin.SetValueType(lldb_private::Value::eValueTypeHostAddress);
const Constant *constant = dyn_cast<Constant>(value);
do
{
if (!constant)
break;
if (!ResolveConstant (data_region, constant))
return Memory::Region();
}
while(0);
m_values[value] = data_region;
return data_region;
}
bool ConstructResult (lldb::ClangExpressionVariableSP &result,
const GlobalValue *result_value,
const lldb_private::ConstString &result_name,
lldb_private::TypeFromParser result_type,
Module &module)
{
// The result_value resolves to P, a pointer to a region R containing the result data.
// If the result variable is a reference, the region R contains a pointer to the result R_final in the original process.
if (!result_value)
return true; // There was no slot for a result the expression doesn't return one.
ValueMap::iterator i = m_values.find(result_value);
if (i == m_values.end())
return false; // There was a slot for the result, but we didn't write into it.
Memory::Region P = i->second;
DataExtractorSP P_extractor = m_memory.GetExtractor(P);
if (!P_extractor)
return false;
Type *pointer_ty = result_value->getType();
PointerType *pointer_ptr_ty = dyn_cast<PointerType>(pointer_ty);
if (!pointer_ptr_ty)
return false;
Type *R_ty = pointer_ptr_ty->getElementType();
uint32_t offset = 0;
lldb::addr_t pointer = P_extractor->GetAddress(&offset);
Memory::Region R = m_memory.Lookup(pointer, R_ty);
if (R.m_allocation->m_origin.GetValueType() != lldb_private::Value::eValueTypeHostAddress ||
!R.m_allocation->m_data)
return false;
lldb_private::Value base;
bool transient = false;
if (m_decl_map.ResultIsReference(result_name))
{
PointerType *R_ptr_ty = dyn_cast<PointerType>(R_ty);
if (!R_ptr_ty)
return false;
Type *R_final_ty = R_ptr_ty->getElementType();
DataExtractorSP R_extractor = m_memory.GetExtractor(R);
if (!R_extractor)
return false;
offset = 0;
lldb::addr_t R_pointer = R_extractor->GetAddress(&offset);
Memory::Region R_final = m_memory.Lookup(R_pointer, R_final_ty);
if (!R_final.m_allocation)
return false;
if (R_final.m_allocation->m_data)
transient = true; // this is a stack allocation
base = R_final.m_allocation->m_origin;
base.GetScalar() += (R_final.m_base - R_final.m_allocation->m_virtual_address);
}
else
{
base.SetContext(lldb_private::Value::eContextTypeInvalid, NULL);
base.SetValueType(lldb_private::Value::eValueTypeHostAddress);
base.GetScalar() = (unsigned long long)R.m_allocation->m_data->GetBytes() + (R.m_base - R.m_allocation->m_virtual_address);
}
return m_decl_map.CompleteResultVariable (result, base, result_name, result_type, transient);
}
};
bool
IRInterpreter::maybeRunOnFunction (lldb::ClangExpressionVariableSP &result,
const lldb_private::ConstString &result_name,
lldb_private::TypeFromParser result_type,
Function &llvm_function,
Module &llvm_module)
{
if (supportsFunction (llvm_function))
return runOnFunction(result,
result_name,
result_type,
llvm_function,
llvm_module);
else
return false;
}
bool
IRInterpreter::supportsFunction (Function &llvm_function)
{
lldb::LogSP log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS));
for (Function::iterator bbi = llvm_function.begin(), bbe = llvm_function.end();
bbi != bbe;
++bbi)
{
for (BasicBlock::iterator ii = bbi->begin(), ie = bbi->end();
ii != ie;
++ii)
{
switch (ii->getOpcode())
{
default:
{
if (log)
log->Printf("Unsupported instruction: %s", PrintValue(ii).c_str());
return false;
}
case Instruction::Add:
case Instruction::Alloca:
case Instruction::BitCast:
case Instruction::Br:
case Instruction::GetElementPtr:
break;
case Instruction::ICmp:
{
ICmpInst *icmp_inst = dyn_cast<ICmpInst>(ii);
if (!icmp_inst)
return false;
switch (icmp_inst->getPredicate())
{
default:
{
if (log)
log->Printf("Unsupported ICmp predicate: %s", PrintValue(ii).c_str());
return false;
}
case CmpInst::ICMP_EQ:
case CmpInst::ICMP_NE:
case CmpInst::ICMP_UGT:
case CmpInst::ICMP_UGE:
case CmpInst::ICMP_ULT:
case CmpInst::ICMP_ULE:
case CmpInst::ICMP_SGT:
case CmpInst::ICMP_SGE:
case CmpInst::ICMP_SLT:
case CmpInst::ICMP_SLE:
break;
}
}
break;
case Instruction::Load:
case Instruction::Mul:
case Instruction::Ret:
case Instruction::SDiv:
case Instruction::Store:
case Instruction::Sub:
case Instruction::UDiv:
break;
}
}
}
return true;
}
bool
IRInterpreter::runOnFunction (lldb::ClangExpressionVariableSP &result,
const lldb_private::ConstString &result_name,
lldb_private::TypeFromParser result_type,
Function &llvm_function,
Module &llvm_module)
{
lldb::LogSP log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS));
lldb_private::ClangExpressionDeclMap::TargetInfo target_info = m_decl_map.GetTargetInfo();
if (!target_info.IsValid())
return false;
lldb::addr_t alloc_min;
lldb::addr_t alloc_max;
switch (target_info.address_byte_size)
{
default:
return false;
case 4:
alloc_min = 0x00001000llu;
alloc_max = 0x0000ffffllu;
break;
case 8:
alloc_min = 0x0000000000001000llu;
alloc_max = 0x000000000000ffffllu;
break;
}
TargetData target_data(&llvm_module);
if (target_data.getPointerSize() != target_info.address_byte_size)
return false;
if (target_data.isLittleEndian() != (target_info.byte_order == lldb::eByteOrderLittle))
return false;
Memory memory(target_data, m_decl_map, alloc_min, alloc_max);
InterpreterStackFrame frame(target_data, memory, m_decl_map);
uint32_t num_insts = 0;
frame.Jump(llvm_function.begin());
while (frame.m_ii != frame.m_ie && (++num_insts < 4096))
{
const Instruction *inst = frame.m_ii;
if (log)
log->Printf("Interpreting %s", PrintValue(inst).c_str());
switch (inst->getOpcode())
{
default:
break;
case Instruction::Add:
case Instruction::Sub:
case Instruction::Mul:
case Instruction::SDiv:
case Instruction::UDiv:
{
const BinaryOperator *bin_op = dyn_cast<BinaryOperator>(inst);
if (!bin_op)
{
if (log)
log->Printf("getOpcode() returns %s, but instruction is not a BinaryOperator", inst->getOpcodeName());
return false;
}
Value *lhs = inst->getOperand(0);
Value *rhs = inst->getOperand(1);
lldb_private::Scalar L;
lldb_private::Scalar R;
if (!frame.EvaluateValue(L, lhs, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(lhs).c_str());
return false;
}
if (!frame.EvaluateValue(R, rhs, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(rhs).c_str());
return false;
}
lldb_private::Scalar result;
switch (inst->getOpcode())
{
default:
break;
case Instruction::Add:
result = L + R;
break;
case Instruction::Mul:
result = L * R;
break;
case Instruction::Sub:
result = L - R;
break;
case Instruction::SDiv:
result = L / R;
break;
case Instruction::UDiv:
result = L.GetRawBits64(0) / R.GetRawBits64(1);
break;
}
frame.AssignValue(inst, result, llvm_module);
if (log)
{
log->Printf("Interpreted a %s", inst->getOpcodeName());
log->Printf(" L : %s", frame.SummarizeValue(lhs).c_str());
log->Printf(" R : %s", frame.SummarizeValue(rhs).c_str());
log->Printf(" = : %s", frame.SummarizeValue(inst).c_str());
}
}
break;
case Instruction::Alloca:
{
const AllocaInst *alloca_inst = dyn_cast<AllocaInst>(inst);
if (!alloca_inst)
{
if (log)
log->Printf("getOpcode() returns Alloca, but instruction is not an AllocaInst");
return false;
}
if (alloca_inst->isArrayAllocation())
{
if (log)
log->Printf("AllocaInsts are not handled if isArrayAllocation() is true");
return false;
}
// The semantics of Alloca are:
// Create a region R of virtual memory of type T, backed by a data buffer
// Create a region P of virtual memory of type T*, backed by a data buffer
// Write the virtual address of R into P
Type *T = alloca_inst->getAllocatedType();
Type *Tptr = alloca_inst->getType();
Memory::Region R = memory.Malloc(T);
if (R.IsInvalid())
{
if (log)
log->Printf("Couldn't allocate memory for an AllocaInst");
return false;
}
Memory::Region P = memory.Malloc(Tptr);
if (P.IsInvalid())
{
if (log)
log->Printf("Couldn't allocate the result pointer for an AllocaInst");
return false;
}
DataEncoderSP P_encoder = memory.GetEncoder(P);
if (P_encoder->PutAddress(0, R.m_base) == UINT32_MAX)
{
if (log)
log->Printf("Couldn't write the reseult pointer for an AllocaInst");
return false;
}
frame.m_values[alloca_inst] = P;
if (log)
{
log->Printf("Interpreted an AllocaInst");
log->Printf(" R : %s", memory.SummarizeRegion(R).c_str());
log->Printf(" P : %s", frame.SummarizeValue(alloca_inst).c_str());
}
}
break;
case Instruction::BitCast:
{
const BitCastInst *bit_cast_inst = dyn_cast<BitCastInst>(inst);
if (!bit_cast_inst)
{
if (log)
log->Printf("getOpcode() returns BitCast, but instruction is not a BitCastInst");
return false;
}
Value *source = bit_cast_inst->getOperand(0);
lldb_private::Scalar S;
if (!frame.EvaluateValue(S, source, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(source).c_str());
return false;
}
frame.AssignValue(inst, S, llvm_module);
}
break;
case Instruction::Br:
{
const BranchInst *br_inst = dyn_cast<BranchInst>(inst);
if (!br_inst)
{
if (log)
log->Printf("getOpcode() returns Br, but instruction is not a BranchInst");
return false;
}
if (br_inst->isConditional())
{
Value *condition = br_inst->getCondition();
lldb_private::Scalar C;
if (!frame.EvaluateValue(C, condition, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(condition).c_str());
return false;
}
if (C.GetRawBits64(0))
frame.Jump(br_inst->getSuccessor(0));
else
frame.Jump(br_inst->getSuccessor(1));
if (log)
{
log->Printf("Interpreted a BrInst with a condition");
log->Printf(" cond : %s", frame.SummarizeValue(condition).c_str());
}
}
else
{
frame.Jump(br_inst->getSuccessor(0));
if (log)
{
log->Printf("Interpreted a BrInst with no condition");
}
}
}
continue;
case Instruction::GetElementPtr:
{
const GetElementPtrInst *gep_inst = dyn_cast<GetElementPtrInst>(inst);
if (!gep_inst)
{
if (log)
log->Printf("getOpcode() returns GetElementPtr, but instruction is not a GetElementPtrInst");
return false;
}
const Value *pointer_operand = gep_inst->getPointerOperand();
Type *pointer_type = pointer_operand->getType();
lldb_private::Scalar P;
if (!frame.EvaluateValue(P, pointer_operand, llvm_module))
return false;
SmallVector <Value *, 8> indices (gep_inst->idx_begin(),
gep_inst->idx_end());
uint64_t offset = target_data.getIndexedOffset(pointer_type, indices);
lldb_private::Scalar Poffset = P + offset;
frame.AssignValue(inst, Poffset, llvm_module);
if (log)
{
log->Printf("Interpreted a GetElementPtrInst");
log->Printf(" P : %s", frame.SummarizeValue(pointer_operand).c_str());
log->Printf(" Poffset : %s", frame.SummarizeValue(inst).c_str());
}
}
break;
case Instruction::ICmp:
{
const ICmpInst *icmp_inst = dyn_cast<ICmpInst>(inst);
if (!icmp_inst)
{
if (log)
log->Printf("getOpcode() returns ICmp, but instruction is not an ICmpInst");
return false;
}
CmpInst::Predicate predicate = icmp_inst->getPredicate();
Value *lhs = inst->getOperand(0);
Value *rhs = inst->getOperand(1);
lldb_private::Scalar L;
lldb_private::Scalar R;
if (!frame.EvaluateValue(L, lhs, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(lhs).c_str());
return false;
}
if (!frame.EvaluateValue(R, rhs, llvm_module))
{
if (log)
log->Printf("Couldn't evaluate %s", PrintValue(rhs).c_str());
return false;
}
lldb_private::Scalar result;
switch (predicate)
{
default:
return false;
case CmpInst::ICMP_EQ:
result = (L == R);
break;
case CmpInst::ICMP_NE:
result = (L != R);
break;
case CmpInst::ICMP_UGT:
result = (L.GetRawBits64(0) > R.GetRawBits64(0));
break;
case CmpInst::ICMP_UGE:
result = (L.GetRawBits64(0) >= R.GetRawBits64(0));
break;
case CmpInst::ICMP_ULT:
result = (L.GetRawBits64(0) < R.GetRawBits64(0));
break;
case CmpInst::ICMP_ULE:
result = (L.GetRawBits64(0) <= R.GetRawBits64(0));
break;
case CmpInst::ICMP_SGT:
result = (L > R);
break;
case CmpInst::ICMP_SGE:
result = (L >= R);
break;
case CmpInst::ICMP_SLT:
result = (L < R);
break;
case CmpInst::ICMP_SLE:
result = (L <= R);
break;
}
frame.AssignValue(inst, result, llvm_module);
if (log)
{
log->Printf("Interpreted an ICmpInst");
log->Printf(" L : %s", frame.SummarizeValue(lhs).c_str());
log->Printf(" R : %s", frame.SummarizeValue(rhs).c_str());
log->Printf(" = : %s", frame.SummarizeValue(inst).c_str());
}
}
break;
case Instruction::Load:
{
const LoadInst *load_inst = dyn_cast<LoadInst>(inst);
if (!load_inst)
{
if (log)
log->Printf("getOpcode() returns Load, but instruction is not a LoadInst");
return false;
}
// The semantics of Load are:
// Create a region D that will contain the loaded data
// Resolve the region P containing a pointer
// Dereference P to get the region R that the data should be loaded from
// Transfer a unit of type type(D) from R to D
const Value *pointer_operand = load_inst->getPointerOperand();
Type *pointer_ty = pointer_operand->getType();
PointerType *pointer_ptr_ty = dyn_cast<PointerType>(pointer_ty);
if (!pointer_ptr_ty)
return false;
Type *target_ty = pointer_ptr_ty->getElementType();
Memory::Region D = frame.ResolveValue(load_inst, llvm_module);
Memory::Region P = frame.ResolveValue(pointer_operand, llvm_module);
if (D.IsInvalid())
{
if (log)
log->Printf("LoadInst's value doesn't resolve to anything");
return false;
}
if (P.IsInvalid())
{
if (log)
log->Printf("LoadInst's pointer doesn't resolve to anything");
return false;
}
DataExtractorSP P_extractor(memory.GetExtractor(P));
DataEncoderSP D_encoder(memory.GetEncoder(D));
uint32_t offset = 0;
lldb::addr_t pointer = P_extractor->GetAddress(&offset);
Memory::Region R = memory.Lookup(pointer, target_ty);
memory.Read(D_encoder->GetDataStart(), R.m_base, target_data.getTypeStoreSize(target_ty));
if (log)
{
log->Printf("Interpreted a LoadInst");
log->Printf(" P : %s", frame.SummarizeValue(pointer_operand).c_str());
log->Printf(" R : %s", memory.SummarizeRegion(R).c_str());
log->Printf(" D : %s", frame.SummarizeValue(load_inst).c_str());
}
}
break;
case Instruction::Ret:
{
if (result_name.IsEmpty())
return true;
GlobalValue *result_value = llvm_module.getNamedValue(result_name.GetCString());
return frame.ConstructResult(result, result_value, result_name, result_type, llvm_module);
}
case Instruction::Store:
{
const StoreInst *store_inst = dyn_cast<StoreInst>(inst);
if (!store_inst)
{
if (log)
log->Printf("getOpcode() returns Store, but instruction is not a StoreInst");
return false;
}
// The semantics of Store are:
// Resolve the region D containing the data to be stored
// Resolve the region P containing a pointer
// Dereference P to get the region R that the data should be stored in
// Transfer a unit of type type(D) from D to R
const Value *value_operand = store_inst->getValueOperand();
const Value *pointer_operand = store_inst->getPointerOperand();
Type *pointer_ty = pointer_operand->getType();
PointerType *pointer_ptr_ty = dyn_cast<PointerType>(pointer_ty);
if (!pointer_ptr_ty)
return false;
Type *target_ty = pointer_ptr_ty->getElementType();
Memory::Region D = frame.ResolveValue(value_operand, llvm_module);
Memory::Region P = frame.ResolveValue(pointer_operand, llvm_module);
if (D.IsInvalid())
{
if (log)
log->Printf("StoreInst's value doesn't resolve to anything");
return false;
}
if (P.IsInvalid())
{
if (log)
log->Printf("StoreInst's pointer doesn't resolve to anything");
return false;
}
DataExtractorSP P_extractor(memory.GetExtractor(P));
DataExtractorSP D_extractor(memory.GetExtractor(D));
if (!P_extractor || !D_extractor)
return false;
uint32_t offset = 0;
lldb::addr_t pointer = P_extractor->GetAddress(&offset);
Memory::Region R = memory.Lookup(pointer, target_ty);
if (R.IsInvalid())
{
if (log)
log->Printf("StoreInst's pointer doesn't point to a valid target");
return false;
}
memory.Write(R.m_base, D_extractor->GetDataStart(), target_data.getTypeStoreSize(target_ty));
if (log)
{
log->Printf("Interpreted a StoreInst");
log->Printf(" D : %s", frame.SummarizeValue(value_operand).c_str());
log->Printf(" P : %s", frame.SummarizeValue(pointer_operand).c_str());
log->Printf(" R : %s", memory.SummarizeRegion(R).c_str());
}
}
break;
}
++frame.m_ii;
}
if (num_insts >= 4096)
return false;
return false;
}
Reference in New Issue View Git Blame Copy Permalink