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llvm/lldb/source/Symbol/Symbol.cpp
Greg Clayton 6b2bd93918 Added many more python convenience accessors: 
You can now access a frame in a thread using:

lldb.SBThread.frame[int] -> lldb.SBFrame object for a frame in a thread

Where "int" is an integer index. You can also access a list object with all of
the frames using:

lldb.SBThread.frames => list() of lldb.SBFrame objects

All SB objects that give out SBAddress objects have properties named "addr"

lldb.SBInstructionList now has the following convenience accessors for len() and
instruction access using an index:

insts = lldb.frame.function.instructions
for idx in range(len(insts)):
    print insts[idx]
    
Instruction lists can also lookup an isntruction using a lldb.SBAddress as the key:

pc_inst = lldb.frame.function.instructions[lldb.frame.addr]

lldb.SBProcess now exposes:

lldb.SBProcess.is_alive => BOOL Check if a process is exists and is alive
lldb.SBProcess.is_running => BOOL check if a process is running (or stepping):
lldb.SBProcess.is_running => BOOL check if a process is currently stopped or crashed:
lldb.SBProcess.thread[int] => lldb.SBThreads for a given "int" zero based index
lldb.SBProcess.threads => list() containing all lldb.SBThread objects in a process

SBInstruction now exposes:
lldb.SBInstruction.mnemonic => python string for instruction mnemonic
lldb.SBInstruction.operands => python string for instruction operands
lldb.SBInstruction.command => python string for instruction comment

SBModule now exposes:

lldb.SBModule.uuid => uuid.UUID(), an UUID object from the "uuid" python module
lldb.SBModule.symbol[int] => lldb.Symbol, lookup symbol by zero based index
lldb.SBModule.symbol[str] => list() of lldb.Symbol objects that match "str"
lldb.SBModule.symbol[re] => list() of lldb.Symbol objecxts that match the regex
lldb.SBModule.symbols => list() of all symbols in a module

  
SBAddress objects can now access the current load address with the "lldb.SBAddress.load_addr"
property. The current "lldb.target" will be used to try and resolve the load address.

Load addresses can also be set using this accessor:

addr = lldb.SBAddress()
addd.load_addr = 0x123023

Then you can check the section and offset to see if the address got resolved.

SBTarget now exposes:

lldb.SBTarget.module[int] => lldb.SBModule from zero based module index
lldb.SBTarget.module[str] => lldb.SBModule by basename or fullpath or uuid string
lldb.SBTarget.module[uuid.UUID()] => lldb.SBModule whose UUID matches
lldb.SBTarget.module[re] => list() of lldb.SBModule objects that match the regex
lldb.SBTarget.modules => list() of all lldb.SBModule objects in the target

SBSymbol now exposes:

lldb.SBSymbol.name => python string for demangled symbol name
lldb.SBSymbol.mangled => python string for mangled symbol name or None if there is none
lldb.SBSymbol.type => lldb.eSymbolType enum value
lldb.SBSymbol.addr => SBAddress object that represents the start address for this symbol (if there is one)
lldb.SBSymbol.end_addr => SBAddress for the end address of the symbol  (if there is one)
lldb.SBSymbol.prologue_size => pythin int containing The size of the prologue in bytes
lldb.SBSymbol.instructions => SBInstructionList containing all instructions for this symbol

SBFunction now also has these new properties in addition to what is already has:
lldb.SBFunction.addr => SBAddress object that represents the start address for this function
lldb.SBFunction.end_addr => SBAddress for the end address of the function
lldb.SBFunction.instructions => SBInstructionList containing all instructions for this function

SBFrame now exposes the SBAddress for the frame:
lldb.SBFrame.addr => SBAddress which is the section offset address for the current frame PC

These are all in addition to what was already added. Documentation and website
updates coming soon.

llvm-svn: 149489
2012-02-01 08:09:32 +00:00

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//===-- Symbol.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/Symbol/Symbol.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/Section.h"
#include "lldb/Core/Stream.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/Target.h"
using namespace lldb;
using namespace lldb_private;
Symbol::Symbol() :
SymbolContextScope (),
m_uid (UINT32_MAX),
m_mangled (),
m_type_data (0),
m_type_data_resolved (false),
m_is_synthetic (false),
m_is_debug (false),
m_is_external (false),
m_size_is_sibling (false),
m_size_is_synthesized (false),
m_type (eSymbolTypeInvalid),
m_flags (),
m_addr_range ()
{
}
Symbol::Symbol
(
uint32_t symID,
const char *name,
bool name_is_mangled,
SymbolType type,
bool external,
bool is_debug,
bool is_trampoline,
bool is_artificial,
const Section* section,
addr_t offset,
uint32_t size,
uint32_t flags
) :
SymbolContextScope (),
m_uid (symID),
m_mangled (name, name_is_mangled),
m_type_data (0),
m_type_data_resolved (false),
m_is_synthetic (is_artificial),
m_is_debug (is_debug),
m_is_external (external),
m_size_is_sibling (false),
m_size_is_synthesized (false),
m_type (type),
m_flags (flags),
m_addr_range (section, offset, size)
{
}
Symbol::Symbol
(
uint32_t symID,
const char *name,
bool name_is_mangled,
SymbolType type,
bool external,
bool is_debug,
bool is_trampoline,
bool is_artificial,
const AddressRange &range,
uint32_t flags
) :
SymbolContextScope (),
m_uid (symID),
m_mangled (name, name_is_mangled),
m_type_data (0),
m_type_data_resolved (false),
m_is_synthetic (is_artificial),
m_is_debug (is_debug),
m_is_external (external),
m_size_is_sibling (false),
m_size_is_synthesized (false),
m_type (type),
m_flags (flags),
m_addr_range (range)
{
}
Symbol::Symbol(const Symbol& rhs):
SymbolContextScope (rhs),
m_uid (rhs.m_uid),
m_mangled (rhs.m_mangled),
m_type_data (rhs.m_type_data),
m_type_data_resolved (rhs.m_type_data_resolved),
m_is_synthetic (rhs.m_is_synthetic),
m_is_debug (rhs.m_is_debug),
m_is_external (rhs.m_is_external),
m_size_is_sibling (rhs.m_size_is_sibling),
m_size_is_synthesized (false),
m_type (rhs.m_type),
m_flags (rhs.m_flags),
m_addr_range (rhs.m_addr_range)
{
}
const Symbol&
Symbol::operator= (const Symbol& rhs)
{
if (this != &rhs)
{
SymbolContextScope::operator= (rhs);
m_uid = rhs.m_uid;
m_mangled = rhs.m_mangled;
m_type_data = rhs.m_type_data;
m_type_data_resolved = rhs.m_type_data_resolved;
m_is_synthetic = rhs.m_is_synthetic;
m_is_debug = rhs.m_is_debug;
m_is_external = rhs.m_is_external;
m_size_is_sibling = rhs.m_size_is_sibling;
m_size_is_synthesized = rhs.m_size_is_sibling;
m_type = rhs.m_type;
m_flags = rhs.m_flags;
m_addr_range = rhs.m_addr_range;
}
return *this;
}
void
Symbol::Clear()
{
m_uid = UINT32_MAX;
m_mangled.Clear();
m_type_data = 0;
m_type_data_resolved = false;
m_is_synthetic = false;
m_is_debug = false;
m_is_external = false;
m_size_is_sibling = false;
m_size_is_synthesized = false;
m_type = eSymbolTypeInvalid;
m_flags = 0;
m_addr_range.Clear();
}
AddressRange *
Symbol::GetAddressRangePtr()
{
if (m_addr_range.GetBaseAddress().GetSection())
return &m_addr_range;
return NULL;
}
const AddressRange *
Symbol::GetAddressRangePtr() const
{
if (m_addr_range.GetBaseAddress().GetSection())
return &m_addr_range;
return NULL;
}
uint32_t
Symbol::GetSiblingIndex() const
{
return m_size_is_sibling ? m_addr_range.GetByteSize() : 0;
}
bool
Symbol::IsTrampoline () const
{
return m_type == eSymbolTypeTrampoline;
}
void
Symbol::GetDescription (Stream *s, lldb::DescriptionLevel level, Target *target) const
{
s->Printf("uid={%6u}", m_uid);
const Section *section = m_addr_range.GetBaseAddress().GetSection();
if (section != NULL)
{
if (m_addr_range.GetBaseAddress().IsSectionOffset())
{
if (m_addr_range.GetByteSize() > 0)
{
s->PutCString (", range = ");
m_addr_range.Dump(s, target, Address::DumpStyleLoadAddress, Address::DumpStyleFileAddress);
}
else
{
s->PutCString (", address = ");
m_addr_range.GetBaseAddress().Dump(s, target, Address::DumpStyleLoadAddress, Address::DumpStyleFileAddress);
}
}
else
s->Printf (", value = 0x%16.16llx", m_addr_range.GetBaseAddress().GetOffset());
}
else
{
if (m_size_is_sibling)
s->Printf (", sibling = %5llu", m_addr_range.GetBaseAddress().GetOffset());
else
s->Printf (", value = 0x%16.16llx", m_addr_range.GetBaseAddress().GetOffset());
}
if (m_mangled.GetDemangledName())
s->Printf(", name=\"%s\"", m_mangled.GetDemangledName().AsCString());
if (m_mangled.GetMangledName())
s->Printf(", mangled=\"%s\"", m_mangled.GetMangledName().AsCString());
}
void
Symbol::Dump(Stream *s, Target *target, uint32_t index) const
{
// s->Printf("%.*p: ", (int)sizeof(void*) * 2, this);
// s->Indent();
// s->Printf("Symbol[%5u] %6u %c%c %-12s ",
s->Printf("[%5u] %6u %c%c%c %-12s ",
index,
GetID(),
m_is_debug ? 'D' : ' ',
m_is_synthetic ? 'S' : ' ',
m_is_external ? 'X' : ' ',
GetTypeAsString());
const Section *section = m_addr_range.GetBaseAddress().GetSection();
if (section != NULL)
{
if (!m_addr_range.GetBaseAddress().Dump(s, NULL, Address::DumpStyleFileAddress))
s->Printf("%*s", 18, "");
s->PutChar(' ');
if (!m_addr_range.GetBaseAddress().Dump(s, target, Address::DumpStyleLoadAddress))
s->Printf("%*s", 18, "");
const char *format = m_size_is_sibling ?
" Sibling -> [%5llu] 0x%8.8x %s\n":
" 0x%16.16llx 0x%8.8x %s\n";
s->Printf( format,
m_addr_range.GetByteSize(),
m_flags,
m_mangled.GetName().AsCString(""));
}
else
{
const char *format = m_size_is_sibling ?
"0x%16.16llx Sibling -> [%5llu] 0x%8.8x %s\n":
"0x%16.16llx 0x%16.16llx 0x%8.8x %s\n";
s->Printf( format,
m_addr_range.GetBaseAddress().GetOffset(),
m_addr_range.GetByteSize(),
m_flags,
m_mangled.GetName().AsCString(""));
}
}
uint32_t
Symbol::GetPrologueByteSize ()
{
if (m_type == eSymbolTypeCode)
{
if (!m_type_data_resolved)
{
m_type_data_resolved = true;
Module *module = m_addr_range.GetBaseAddress().GetModulePtr();
SymbolContext sc;
if (module && module->ResolveSymbolContextForAddress (m_addr_range.GetBaseAddress(),
eSymbolContextLineEntry,
sc))
{
m_type_data = sc.line_entry.range.GetByteSize();
}
else
{
// TODO: expose something in Process to figure out the
// size of a function prologue.
}
}
return m_type_data;
}
return 0;
}
void
Symbol::SetValue(addr_t value)
{
m_addr_range.GetBaseAddress().SetSection(NULL);
m_addr_range.GetBaseAddress().SetOffset(value);
}
bool
Symbol::Compare(const ConstString& name, SymbolType type) const
{
if (type == eSymbolTypeAny || m_type == type)
return m_mangled.GetMangledName() == name || m_mangled.GetDemangledName() == name;
return false;
}
#define ENUM_TO_CSTRING(x) case eSymbolType##x: return #x;
const char *
Symbol::GetTypeAsString() const
{
switch (m_type)
{
ENUM_TO_CSTRING(Invalid);
ENUM_TO_CSTRING(Absolute);
ENUM_TO_CSTRING(Code);
ENUM_TO_CSTRING(Data);
ENUM_TO_CSTRING(Trampoline);
ENUM_TO_CSTRING(Runtime);
ENUM_TO_CSTRING(Exception);
ENUM_TO_CSTRING(SourceFile);
ENUM_TO_CSTRING(HeaderFile);
ENUM_TO_CSTRING(ObjectFile);
ENUM_TO_CSTRING(CommonBlock);
ENUM_TO_CSTRING(Block);
ENUM_TO_CSTRING(Local);
ENUM_TO_CSTRING(Param);
ENUM_TO_CSTRING(Variable);
ENUM_TO_CSTRING(VariableType);
ENUM_TO_CSTRING(LineEntry);
ENUM_TO_CSTRING(LineHeader);
ENUM_TO_CSTRING(ScopeBegin);
ENUM_TO_CSTRING(ScopeEnd);
ENUM_TO_CSTRING(Additional);
ENUM_TO_CSTRING(Compiler);
ENUM_TO_CSTRING(Instrumentation);
ENUM_TO_CSTRING(Undefined);
ENUM_TO_CSTRING(ObjCClass);
ENUM_TO_CSTRING(ObjCMetaClass);
ENUM_TO_CSTRING(ObjCIVar);
default:
break;
}
return "<unknown SymbolType>";
}
void
Symbol::CalculateSymbolContext (SymbolContext *sc)
{
// Symbols can reconstruct the symbol and the module in the symbol context
sc->symbol = this;
const AddressRange *range = GetAddressRangePtr();
if (range)
sc->module_sp = range->GetBaseAddress().GetModuleSP ();
else
sc->module_sp.reset();
}
Module *
Symbol::CalculateSymbolContextModule ()
{
const AddressRange *range = GetAddressRangePtr();
if (range)
return range->GetBaseAddress().GetModulePtr ();
return NULL;
}
Symbol *
Symbol::CalculateSymbolContextSymbol ()
{
return this;
}
void
Symbol::DumpSymbolContext (Stream *s)
{
bool dumped_module = false;
const AddressRange *range = GetAddressRangePtr();
if (range)
{
Module *module = range->GetBaseAddress().GetModulePtr ();
if (module)
{
dumped_module = true;
module->DumpSymbolContext(s);
}
}
if (dumped_module)
s->PutCString(", ");
s->Printf("Symbol{0x%8.8x}", GetID());
}
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