source/Target/ThreadPlanStepRange.cpp - lldb - Git at Google

 //===-- ThreadPlanStepRange.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/Target/ThreadPlanStepRange.h"

 // C Includes
 // C++ Includes
 // Other libraries and framework includes
 // Project includes

 #include "lldb/lldb-private-log.h"
 #include "lldb/Breakpoint/BreakpointLocation.h"
 #include "lldb/Breakpoint/BreakpointSite.h"
 #include "lldb/Core/Disassembler.h"
 #include "lldb/Core/Log.h"
 #include "lldb/Core/Stream.h"
 #include "lldb/Symbol/Function.h"
 #include "lldb/Symbol/Symbol.h"
 #include "lldb/Target/ExecutionContext.h"
 #include "lldb/Target/Process.h"
 #include "lldb/Target/RegisterContext.h"
 #include "lldb/Target/StopInfo.h"
 #include "lldb/Target/Target.h"
 #include "lldb/Target/Thread.h"
 #include "lldb/Target/ThreadPlanRunToAddress.h"

 using namespace lldb;
 using namespace lldb_private;


 //----------------------------------------------------------------------
 // ThreadPlanStepRange: Step through a stack range, either stepping over or into
 // based on the value of \a type.
 //----------------------------------------------------------------------

 ThreadPlanStepRange::ThreadPlanStepRange (ThreadPlanKind kind,
                                           const char *name,
                                           Thread &thread,
                                           const AddressRange &range,
                                           const SymbolContext &addr_context,
                                           lldb::RunMode stop_others) :
     ThreadPlan (kind, name, thread, eVoteNoOpinion, eVoteNoOpinion),
     m_addr_context (addr_context),
     m_address_ranges (),
     m_stop_others (stop_others),
     m_stack_id (),
     m_no_more_plans (false),
     m_first_run_event (true),
     m_use_fast_step(false)
 {
     m_use_fast_step = GetTarget().GetUseFastStepping();
     AddRange(range);
     m_stack_id = m_thread.GetStackFrameAtIndex(0)->GetStackID();
 }

 ThreadPlanStepRange::~ThreadPlanStepRange ()
 {
     ClearNextBranchBreakpoint();

     size_t num_instruction_ranges = m_instruction_ranges.size();

     // FIXME: The DisassemblerLLVMC has a reference cycle and won't go away if it has any active instructions.
     // I'll fix that but for now, just clear the list and it will go away nicely.
     for (size_t i = 0; i < num_instruction_ranges; i++)
     {
         if (m_instruction_ranges[i])
             m_instruction_ranges[i]->GetInstructionList().Clear();
     }
 }

 void
 ThreadPlanStepRange::DidPush ()
 {
     // See if we can find a "next range" breakpoint:
     SetNextBranchBreakpoint();
 }

 bool
 ThreadPlanStepRange::ValidatePlan (Stream *error)
 {
     return true;
 }

 Vote
 ThreadPlanStepRange::ShouldReportStop (Event *event_ptr)
 {
     Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));

     const Vote vote = IsPlanComplete() ? eVoteYes : eVoteNo;
     if (log)
         log->Printf ("ThreadPlanStepRange::ShouldReportStop() returning vote %i\n", vote);
     return vote;
 }

 void
 ThreadPlanStepRange::AddRange(const AddressRange &new_range)
 {
     // For now I'm just adding the ranges.  At some point we may want to
     // condense the ranges if they overlap, though I don't think it is likely
     // to be very important.
     m_address_ranges.push_back (new_range);

     // Fill the slot for this address range with an empty DisassemblerSP in the instruction ranges. I want the
     // indices to match, but I don't want to do the work to disassemble this range if I don't step into it.
     m_instruction_ranges.push_back (DisassemblerSP());
 }

 void
 ThreadPlanStepRange::DumpRanges(Stream *s)
 {
     size_t num_ranges = m_address_ranges.size();
     if (num_ranges == 1)
     {
         m_address_ranges[0].Dump (s, m_thread.CalculateTarget().get(), Address::DumpStyleLoadAddress);
     }
     else
     {
         for (size_t i = 0; i < num_ranges; i++)
         {
             s->PutCString("%d: ");
             m_address_ranges[i].Dump (s, m_thread.CalculateTarget().get(), Address::DumpStyleLoadAddress);
         }
     }
 }

 bool
 ThreadPlanStepRange::InRange ()
 {
     Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
     bool ret_value = false;

     lldb::addr_t pc_load_addr = m_thread.GetRegisterContext()->GetPC();

     size_t num_ranges = m_address_ranges.size();
     for (size_t i = 0; i < num_ranges; i++)
     {
         ret_value = m_address_ranges[i].ContainsLoadAddress(pc_load_addr, m_thread.CalculateTarget().get());
         if (ret_value)
             break;
     }

     if (!ret_value)
     {
         // See if we've just stepped to another part of the same line number...
         StackFrame *frame = m_thread.GetStackFrameAtIndex(0).get();

         SymbolContext new_context(frame->GetSymbolContext(eSymbolContextEverything));
         if (m_addr_context.line_entry.IsValid() && new_context.line_entry.IsValid())
         {
             if (m_addr_context.line_entry.file == new_context.line_entry.file)
             {
                 if (m_addr_context.line_entry.line == new_context.line_entry.line)
                 {
                     m_addr_context = new_context;
                     AddRange(m_addr_context.line_entry.range);
                     ret_value = true;
                     if (log)
                     {
                         StreamString s;
                         m_addr_context.line_entry.Dump (&s,
                                                         m_thread.CalculateTarget().get(),
                                                         true,
                                                         Address::DumpStyleLoadAddress,
                                                         Address::DumpStyleLoadAddress,
                                                         true);

                         log->Printf ("Step range plan stepped to another range of same line: %s", s.GetData());
                     }
                 }
                 else if (new_context.line_entry.line == 0)
                 {
                     new_context.line_entry.line = m_addr_context.line_entry.line;
                     m_addr_context = new_context;
                     AddRange(m_addr_context.line_entry.range);
                     ret_value = true;
                     if (log)
                     {
                         StreamString s;
                         m_addr_context.line_entry.Dump (&s,
                                                         m_thread.CalculateTarget().get(),
                                                         true,
                                                         Address::DumpStyleLoadAddress,
                                                         Address::DumpStyleLoadAddress,
                                                         true);

                         log->Printf ("Step range plan stepped to a range at linenumber 0 stepping through that range: %s", s.GetData());
                     }
                 }
                 else if (new_context.line_entry.range.GetBaseAddress().GetLoadAddress(m_thread.CalculateTarget().get())
                          != pc_load_addr)
                 {
                     // Another thing that sometimes happens here is that we step out of one line into the MIDDLE of another
                     // line.  So far I mostly see this due to bugs in the debug information.
                     // But we probably don't want to be in the middle of a line range, so in that case reset the stepping
                     // range to the line we've stepped into the middle of and continue.
                     m_addr_context = new_context;
                     m_address_ranges.clear();
                     AddRange(m_addr_context.line_entry.range);
                     ret_value = true;
                     if (log)
                     {
                         StreamString s;
                         m_addr_context.line_entry.Dump (&s,
                                                         m_thread.CalculateTarget().get(),
                                                         true,
                                                         Address::DumpStyleLoadAddress,
                                                         Address::DumpStyleLoadAddress,
                                                         true);

                         log->Printf ("Step range plan stepped to the middle of new line(%d): %s, continuing to clear this line.",
                                      new_context.line_entry.line,
                                      s.GetData());
                     }

                 }
             }

         }

     }

     if (!ret_value && log)
         log->Printf ("Step range plan out of range to 0x%" PRIx64, pc_load_addr);

     return ret_value;
 }

 bool
 ThreadPlanStepRange::InSymbol()
 {
     lldb::addr_t cur_pc = m_thread.GetRegisterContext()->GetPC();
     if (m_addr_context.function != NULL)
     {
         return m_addr_context.function->GetAddressRange().ContainsLoadAddress (cur_pc, m_thread.CalculateTarget().get());
     }
     else if (m_addr_context.symbol)
     {
         AddressRange range(m_addr_context.symbol->GetAddress(), m_addr_context.symbol->GetByteSize());
         return range.ContainsLoadAddress (cur_pc, m_thread.CalculateTarget().get());
     }
     return false;
 }

 // FIXME: This should also handle inlining if we aren't going to do inlining in the
 // main stack.
 //
 // Ideally we should remember the whole stack frame list, and then compare that
 // to the current list.

 lldb::FrameComparison
 ThreadPlanStepRange::CompareCurrentFrameToStartFrame()
 {
     FrameComparison frame_order;

     StackID cur_frame_id = m_thread.GetStackFrameAtIndex(0)->GetStackID();

     if (cur_frame_id == m_stack_id)
     {
         frame_order = eFrameCompareEqual;
     }
     else if (cur_frame_id < m_stack_id)
     {
         frame_order = eFrameCompareYounger;
     }
     else
     {
         frame_order = eFrameCompareOlder;
     }
     return frame_order;
 }

 bool
 ThreadPlanStepRange::StopOthers ()
 {
     if (m_stop_others == lldb::eOnlyThisThread
         || m_stop_others == lldb::eOnlyDuringStepping)
         return true;
     else
         return false;
 }

 InstructionList *
 ThreadPlanStepRange::GetInstructionsForAddress(lldb::addr_t addr, size_t &range_index, size_t &insn_offset)
 {
     size_t num_ranges = m_address_ranges.size();
     for (size_t i = 0; i < num_ranges; i++)
     {
         if (m_address_ranges[i].ContainsLoadAddress(addr, &GetTarget()))
         {
             // Some joker added a zero size range to the stepping range...
             if (m_address_ranges[i].GetByteSize() == 0)
                 return NULL;

             if (!m_instruction_ranges[i])
             {
                 //Disassemble the address range given:
                 ExecutionContext exe_ctx (m_thread.GetProcess());
                 const char *plugin_name = NULL;
                 const char *flavor = NULL;
                 const bool prefer_file_cache = true;
                 m_instruction_ranges[i] = Disassembler::DisassembleRange(GetTarget().GetArchitecture(),
                                                                          plugin_name,
                                                                          flavor,
                                                                          exe_ctx,
                                                                          m_address_ranges[i],
                                                                          prefer_file_cache);

             }
             if (!m_instruction_ranges[i])
                 return NULL;
             else
             {
                 // Find where we are in the instruction list as well.  If we aren't at an instruction,
                 // return NULL.  In this case, we're probably lost, and shouldn't try to do anything fancy.

                 insn_offset = m_instruction_ranges[i]->GetInstructionList().GetIndexOfInstructionAtLoadAddress(addr, GetTarget());
                 if (insn_offset == UINT32_MAX)
                     return NULL;
                 else
                 {
                     range_index = i;
                     return &m_instruction_ranges[i]->GetInstructionList();
                 }
             }
         }
     }
     return NULL;
 }

 void
 ThreadPlanStepRange::ClearNextBranchBreakpoint()
 {
     if (m_next_branch_bp_sp)
     {
         Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
         if (log)
             log->Printf ("Removing next branch breakpoint: %d.", m_next_branch_bp_sp->GetID());
         GetTarget().RemoveBreakpointByID (m_next_branch_bp_sp->GetID());
         m_next_branch_bp_sp.reset();
     }
 }

 bool
 ThreadPlanStepRange::SetNextBranchBreakpoint ()
 {
     if (m_next_branch_bp_sp)
         return true;

     Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
     // Stepping through ranges using breakpoints doesn't work yet, but with this off we fall back to instruction
     // single stepping.
     if (!m_use_fast_step)
          return false;

     lldb::addr_t cur_addr = GetThread().GetRegisterContext()->GetPC();
     // Find the current address in our address ranges, and fetch the disassembly if we haven't already:
     size_t pc_index;
     size_t range_index;
     InstructionList *instructions = GetInstructionsForAddress (cur_addr, range_index, pc_index);
     if (instructions == NULL)
         return false;
     else
     {
         uint32_t branch_index;
         branch_index = instructions->GetIndexOfNextBranchInstruction (pc_index);

         Address run_to_address;

         // If we didn't find a branch, run to the end of the range.
         if (branch_index == UINT32_MAX)
         {
             branch_index = instructions->GetSize() - 1;
         }

         if (branch_index - pc_index > 1)
         {
             const bool is_internal = true;
             run_to_address = instructions->GetInstructionAtIndex(branch_index)->GetAddress();
             m_next_branch_bp_sp = GetTarget().CreateBreakpoint(run_to_address, is_internal, false);
             if (m_next_branch_bp_sp)
             {
                 if (log)
                 {
                     lldb::break_id_t bp_site_id = LLDB_INVALID_BREAK_ID;
                     BreakpointLocationSP bp_loc = m_next_branch_bp_sp->GetLocationAtIndex(0);
                     if (bp_loc)
                     {
                         BreakpointSiteSP bp_site = bp_loc->GetBreakpointSite();
                         if (bp_site)
                         {
                             bp_site_id = bp_site->GetID();
                         }
                     }
                     log->Printf ("ThreadPlanStepRange::SetNextBranchBreakpoint - Setting breakpoint %d (site %d) to run to address 0x%" PRIx64,
                                  m_next_branch_bp_sp->GetID(),
                                  bp_site_id,
                                  run_to_address.GetLoadAddress(&m_thread.GetProcess()->GetTarget()));
                 }
                 m_next_branch_bp_sp->SetThreadID(m_thread.GetID());
                 m_next_branch_bp_sp->SetBreakpointKind ("next-branch-location");
                 return true;
             }
             else
                 return false;
         }
     }
     return false;
 }

 bool
 ThreadPlanStepRange::NextRangeBreakpointExplainsStop (lldb::StopInfoSP stop_info_sp)
 {
     Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
     if (!m_next_branch_bp_sp)
         return false;

     break_id_t bp_site_id = stop_info_sp->GetValue();
     BreakpointSiteSP bp_site_sp = m_thread.GetProcess()->GetBreakpointSiteList().FindByID(bp_site_id);
     if (!bp_site_sp)
         return false;
     else if (!bp_site_sp->IsBreakpointAtThisSite (m_next_branch_bp_sp->GetID()))
         return false;
     else
     {
         // If we've hit the next branch breakpoint, then clear it.
         size_t num_owners = bp_site_sp->GetNumberOfOwners();
         bool explains_stop = true;
         // If all the owners are internal, then we are probably just stepping over this range from multiple threads,
         // or multiple frames, so we want to continue.  If one is not internal, then we should not explain the stop,
         // and let the user breakpoint handle the stop.
         for (size_t i = 0; i < num_owners; i++)
         {
             if (!bp_site_sp->GetOwnerAtIndex(i)->GetBreakpoint().IsInternal())
             {
                 explains_stop = false;
                 break;
             }
         }
         if (log)
             log->Printf ("ThreadPlanStepRange::NextRangeBreakpointExplainsStop - Hit next range breakpoint which has %" PRIu64 " owners - explains stop: %u.",
                         (uint64_t)num_owners,
                         explains_stop);
         ClearNextBranchBreakpoint();
         return  explains_stop;
     }
 }

 bool
 ThreadPlanStepRange::WillStop ()
 {
     return true;
 }

 StateType
 ThreadPlanStepRange::GetPlanRunState ()
 {
     if (m_next_branch_bp_sp)
         return eStateRunning;
     else
         return eStateStepping;
 }

 bool
 ThreadPlanStepRange::MischiefManaged ()
 {
     // If we have pushed some plans between ShouldStop & MischiefManaged, then we're not done...
     // I do this check first because we might have stepped somewhere that will fool InRange into
     // thinking it needs to step past the end of that line.  This happens, for instance, when stepping
     // over inlined code that is in the middle of the current line.

     if (!m_no_more_plans)
         return false;

     bool done = true;
     if (!IsPlanComplete())
     {
         if (InRange())
         {
             done = false;
         }
         else
         {
             FrameComparison frame_order = CompareCurrentFrameToStartFrame();
             if (frame_order != eFrameCompareOlder)
             {
                 if (m_no_more_plans)
                     done = true;
                 else
                     done = false;
             }
             else
                 done = true;
         }
     }

     if (done)
     {
         Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
         if (log)
             log->Printf("Completed step through range plan.");
         ClearNextBranchBreakpoint();
         ThreadPlan::MischiefManaged ();
         return true;
     }
     else
     {
         return false;
     }

 }

 bool
 ThreadPlanStepRange::IsPlanStale ()
 {
     Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
     FrameComparison frame_order = CompareCurrentFrameToStartFrame();

     if (frame_order == eFrameCompareOlder)
     {
         if (log)
         {
             log->Printf("ThreadPlanStepRange::IsPlanStale returning true, we've stepped out.");
         }
         return true;
     }
     else if (frame_order == eFrameCompareEqual && InSymbol())
     {
         // If we are not in a place we should step through, we've gotten stale.
         // One tricky bit here is that some stubs don't push a frame, so we should.
         // check that we are in the same symbol.
         if (!InRange())
         {
             return true;
         }
     }
     return false;
 }
	//===-- ThreadPlanStepRange.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/Target/ThreadPlanStepRange.h"

	// C Includes
	// C++ Includes
	// Other libraries and framework includes
	// Project includes

	#include "lldb/lldb-private-log.h"
	#include "lldb/Breakpoint/BreakpointLocation.h"
	#include "lldb/Breakpoint/BreakpointSite.h"
	#include "lldb/Core/Disassembler.h"
	#include "lldb/Core/Log.h"
	#include "lldb/Core/Stream.h"
	#include "lldb/Symbol/Function.h"
	#include "lldb/Symbol/Symbol.h"
	#include "lldb/Target/ExecutionContext.h"
	#include "lldb/Target/Process.h"
	#include "lldb/Target/RegisterContext.h"
	#include "lldb/Target/StopInfo.h"
	#include "lldb/Target/Target.h"
	#include "lldb/Target/Thread.h"
	#include "lldb/Target/ThreadPlanRunToAddress.h"

	using namespace lldb;
	using namespace lldb_private;


	//----------------------------------------------------------------------
	// ThreadPlanStepRange: Step through a stack range, either stepping over or into
	// based on the value of \a type.
	//----------------------------------------------------------------------

	ThreadPlanStepRange::ThreadPlanStepRange (ThreadPlanKind kind,
	const char *name,
	Thread &thread,
	const AddressRange &range,
	const SymbolContext &addr_context,
	lldb::RunMode stop_others) :
	ThreadPlan (kind, name, thread, eVoteNoOpinion, eVoteNoOpinion),
	m_addr_context (addr_context),
	m_address_ranges (),
	m_stop_others (stop_others),
	m_stack_id (),
	m_no_more_plans (false),
	m_first_run_event (true),
	m_use_fast_step(false)
	{
	m_use_fast_step = GetTarget().GetUseFastStepping();
	AddRange(range);
	m_stack_id = m_thread.GetStackFrameAtIndex(0)->GetStackID();
	}

	ThreadPlanStepRange::~ThreadPlanStepRange ()
	{
	ClearNextBranchBreakpoint();

	size_t num_instruction_ranges = m_instruction_ranges.size();

	// FIXME: The DisassemblerLLVMC has a reference cycle and won't go away if it has any active instructions.
	// I'll fix that but for now, just clear the list and it will go away nicely.
	for (size_t i = 0; i < num_instruction_ranges; i++)
	{
	if (m_instruction_ranges[i])
	m_instruction_ranges[i]->GetInstructionList().Clear();
	}
	}

	void
	ThreadPlanStepRange::DidPush ()
	{
	// See if we can find a "next range" breakpoint:
	SetNextBranchBreakpoint();
	}

	bool
	ThreadPlanStepRange::ValidatePlan (Stream *error)
	{
	return true;
	}

	Vote
	ThreadPlanStepRange::ShouldReportStop (Event *event_ptr)
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));

	const Vote vote = IsPlanComplete() ? eVoteYes : eVoteNo;
	if (log)
	log->Printf ("ThreadPlanStepRange::ShouldReportStop() returning vote %i\n", vote);
	return vote;
	}

	void
	ThreadPlanStepRange::AddRange(const AddressRange &new_range)
	{
	// For now I'm just adding the ranges. At some point we may want to
	// condense the ranges if they overlap, though I don't think it is likely
	// to be very important.
	m_address_ranges.push_back (new_range);

	// Fill the slot for this address range with an empty DisassemblerSP in the instruction ranges. I want the
	// indices to match, but I don't want to do the work to disassemble this range if I don't step into it.
	m_instruction_ranges.push_back (DisassemblerSP());
	}

	void
	ThreadPlanStepRange::DumpRanges(Stream *s)
	{
	size_t num_ranges = m_address_ranges.size();
	if (num_ranges == 1)
	{
	m_address_ranges[0].Dump (s, m_thread.CalculateTarget().get(), Address::DumpStyleLoadAddress);
	}
	else
	{
	for (size_t i = 0; i < num_ranges; i++)
	{
	s->PutCString("%d: ");
	m_address_ranges[i].Dump (s, m_thread.CalculateTarget().get(), Address::DumpStyleLoadAddress);
	}
	}
	}

	bool
	ThreadPlanStepRange::InRange ()
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	bool ret_value = false;

	lldb::addr_t pc_load_addr = m_thread.GetRegisterContext()->GetPC();

	size_t num_ranges = m_address_ranges.size();
	for (size_t i = 0; i < num_ranges; i++)
	{
	ret_value = m_address_ranges[i].ContainsLoadAddress(pc_load_addr, m_thread.CalculateTarget().get());
	if (ret_value)
	break;
	}

	if (!ret_value)
	{
	// See if we've just stepped to another part of the same line number...
	StackFrame *frame = m_thread.GetStackFrameAtIndex(0).get();

	SymbolContext new_context(frame->GetSymbolContext(eSymbolContextEverything));
	if (m_addr_context.line_entry.IsValid() && new_context.line_entry.IsValid())
	{
	if (m_addr_context.line_entry.file == new_context.line_entry.file)
	{
	if (m_addr_context.line_entry.line == new_context.line_entry.line)
	{
	m_addr_context = new_context;
	AddRange(m_addr_context.line_entry.range);
	ret_value = true;
	if (log)
	{
	StreamString s;
	m_addr_context.line_entry.Dump (&s,
	m_thread.CalculateTarget().get(),
	true,
	Address::DumpStyleLoadAddress,
	Address::DumpStyleLoadAddress,
	true);

	log->Printf ("Step range plan stepped to another range of same line: %s", s.GetData());
	}
	}
	else if (new_context.line_entry.line == 0)
	{
	new_context.line_entry.line = m_addr_context.line_entry.line;
	m_addr_context = new_context;
	AddRange(m_addr_context.line_entry.range);
	ret_value = true;
	if (log)
	{
	StreamString s;
	m_addr_context.line_entry.Dump (&s,
	m_thread.CalculateTarget().get(),
	true,
	Address::DumpStyleLoadAddress,
	Address::DumpStyleLoadAddress,
	true);

	log->Printf ("Step range plan stepped to a range at linenumber 0 stepping through that range: %s", s.GetData());
	}
	}
	else if (new_context.line_entry.range.GetBaseAddress().GetLoadAddress(m_thread.CalculateTarget().get())
	!= pc_load_addr)
	{
	// Another thing that sometimes happens here is that we step out of one line into the MIDDLE of another
	// line. So far I mostly see this due to bugs in the debug information.
	// But we probably don't want to be in the middle of a line range, so in that case reset the stepping
	// range to the line we've stepped into the middle of and continue.
	m_addr_context = new_context;
	m_address_ranges.clear();
	AddRange(m_addr_context.line_entry.range);
	ret_value = true;
	if (log)
	{
	StreamString s;
	m_addr_context.line_entry.Dump (&s,
	m_thread.CalculateTarget().get(),
	true,
	Address::DumpStyleLoadAddress,
	Address::DumpStyleLoadAddress,
	true);

	log->Printf ("Step range plan stepped to the middle of new line(%d): %s, continuing to clear this line.",
	new_context.line_entry.line,
	s.GetData());
	}

	}
	}

	}

	}

	if (!ret_value && log)
	log->Printf ("Step range plan out of range to 0x%" PRIx64, pc_load_addr);

	return ret_value;
	}

	bool
	ThreadPlanStepRange::InSymbol()
	{
	lldb::addr_t cur_pc = m_thread.GetRegisterContext()->GetPC();
	if (m_addr_context.function != NULL)
	{
	return m_addr_context.function->GetAddressRange().ContainsLoadAddress (cur_pc, m_thread.CalculateTarget().get());
	}
	else if (m_addr_context.symbol)
	{
	AddressRange range(m_addr_context.symbol->GetAddress(), m_addr_context.symbol->GetByteSize());
	return range.ContainsLoadAddress (cur_pc, m_thread.CalculateTarget().get());
	}
	return false;
	}

	// FIXME: This should also handle inlining if we aren't going to do inlining in the
	// main stack.
	//
	// Ideally we should remember the whole stack frame list, and then compare that
	// to the current list.

	lldb::FrameComparison
	ThreadPlanStepRange::CompareCurrentFrameToStartFrame()
	{
	FrameComparison frame_order;

	StackID cur_frame_id = m_thread.GetStackFrameAtIndex(0)->GetStackID();

	if (cur_frame_id == m_stack_id)
	{
	frame_order = eFrameCompareEqual;
	}
	else if (cur_frame_id < m_stack_id)
	{
	frame_order = eFrameCompareYounger;
	}
	else
	{
	frame_order = eFrameCompareOlder;
	}
	return frame_order;
	}

	bool
	ThreadPlanStepRange::StopOthers ()
	{
	if (m_stop_others == lldb::eOnlyThisThread
	\|\| m_stop_others == lldb::eOnlyDuringStepping)
	return true;
	else
	return false;
	}

	InstructionList *
	ThreadPlanStepRange::GetInstructionsForAddress(lldb::addr_t addr, size_t &range_index, size_t &insn_offset)
	{
	size_t num_ranges = m_address_ranges.size();
	for (size_t i = 0; i < num_ranges; i++)
	{
	if (m_address_ranges[i].ContainsLoadAddress(addr, &GetTarget()))
	{
	// Some joker added a zero size range to the stepping range...
	if (m_address_ranges[i].GetByteSize() == 0)
	return NULL;

	if (!m_instruction_ranges[i])
	{
	//Disassemble the address range given:
	ExecutionContext exe_ctx (m_thread.GetProcess());
	const char *plugin_name = NULL;
	const char *flavor = NULL;
	const bool prefer_file_cache = true;
	m_instruction_ranges[i] = Disassembler::DisassembleRange(GetTarget().GetArchitecture(),
	plugin_name,
	flavor,
	exe_ctx,
	m_address_ranges[i],
	prefer_file_cache);

	}
	if (!m_instruction_ranges[i])
	return NULL;
	else
	{
	// Find where we are in the instruction list as well. If we aren't at an instruction,
	// return NULL. In this case, we're probably lost, and shouldn't try to do anything fancy.

	insn_offset = m_instruction_ranges[i]->GetInstructionList().GetIndexOfInstructionAtLoadAddress(addr, GetTarget());
	if (insn_offset == UINT32_MAX)
	return NULL;
	else
	{
	range_index = i;
	return &m_instruction_ranges[i]->GetInstructionList();
	}
	}
	}
	}
	return NULL;
	}

	void
	ThreadPlanStepRange::ClearNextBranchBreakpoint()
	{
	if (m_next_branch_bp_sp)
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	if (log)
	log->Printf ("Removing next branch breakpoint: %d.", m_next_branch_bp_sp->GetID());
	GetTarget().RemoveBreakpointByID (m_next_branch_bp_sp->GetID());
	m_next_branch_bp_sp.reset();
	}
	}

	bool
	ThreadPlanStepRange::SetNextBranchBreakpoint ()
	{
	if (m_next_branch_bp_sp)
	return true;

	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	// Stepping through ranges using breakpoints doesn't work yet, but with this off we fall back to instruction
	// single stepping.
	if (!m_use_fast_step)
	return false;

	lldb::addr_t cur_addr = GetThread().GetRegisterContext()->GetPC();
	// Find the current address in our address ranges, and fetch the disassembly if we haven't already:
	size_t pc_index;
	size_t range_index;
	InstructionList *instructions = GetInstructionsForAddress (cur_addr, range_index, pc_index);
	if (instructions == NULL)
	return false;
	else
	{
	uint32_t branch_index;
	branch_index = instructions->GetIndexOfNextBranchInstruction (pc_index);

	Address run_to_address;

	// If we didn't find a branch, run to the end of the range.
	if (branch_index == UINT32_MAX)
	{
	branch_index = instructions->GetSize() - 1;
	}

	if (branch_index - pc_index > 1)
	{
	const bool is_internal = true;
	run_to_address = instructions->GetInstructionAtIndex(branch_index)->GetAddress();
	m_next_branch_bp_sp = GetTarget().CreateBreakpoint(run_to_address, is_internal, false);
	if (m_next_branch_bp_sp)
	{
	if (log)
	{
	lldb::break_id_t bp_site_id = LLDB_INVALID_BREAK_ID;
	BreakpointLocationSP bp_loc = m_next_branch_bp_sp->GetLocationAtIndex(0);
	if (bp_loc)
	{
	BreakpointSiteSP bp_site = bp_loc->GetBreakpointSite();
	if (bp_site)
	{
	bp_site_id = bp_site->GetID();
	}
	}
	log->Printf ("ThreadPlanStepRange::SetNextBranchBreakpoint - Setting breakpoint %d (site %d) to run to address 0x%" PRIx64,
	m_next_branch_bp_sp->GetID(),
	bp_site_id,
	run_to_address.GetLoadAddress(&m_thread.GetProcess()->GetTarget()));
	}
	m_next_branch_bp_sp->SetThreadID(m_thread.GetID());
	m_next_branch_bp_sp->SetBreakpointKind ("next-branch-location");
	return true;
	}
	else
	return false;
	}
	}
	return false;
	}

	bool
	ThreadPlanStepRange::NextRangeBreakpointExplainsStop (lldb::StopInfoSP stop_info_sp)
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	if (!m_next_branch_bp_sp)
	return false;

	break_id_t bp_site_id = stop_info_sp->GetValue();
	BreakpointSiteSP bp_site_sp = m_thread.GetProcess()->GetBreakpointSiteList().FindByID(bp_site_id);
	if (!bp_site_sp)
	return false;
	else if (!bp_site_sp->IsBreakpointAtThisSite (m_next_branch_bp_sp->GetID()))
	return false;
	else
	{
	// If we've hit the next branch breakpoint, then clear it.
	size_t num_owners = bp_site_sp->GetNumberOfOwners();
	bool explains_stop = true;
	// If all the owners are internal, then we are probably just stepping over this range from multiple threads,
	// or multiple frames, so we want to continue. If one is not internal, then we should not explain the stop,
	// and let the user breakpoint handle the stop.
	for (size_t i = 0; i < num_owners; i++)
	{
	if (!bp_site_sp->GetOwnerAtIndex(i)->GetBreakpoint().IsInternal())
	{
	explains_stop = false;
	break;
	}
	}
	if (log)
	log->Printf ("ThreadPlanStepRange::NextRangeBreakpointExplainsStop - Hit next range breakpoint which has %" PRIu64 " owners - explains stop: %u.",
	(uint64_t)num_owners,
	explains_stop);
	ClearNextBranchBreakpoint();
	return explains_stop;
	}
	}

	bool
	ThreadPlanStepRange::WillStop ()
	{
	return true;
	}

	StateType
	ThreadPlanStepRange::GetPlanRunState ()
	{
	if (m_next_branch_bp_sp)
	return eStateRunning;
	else
	return eStateStepping;
	}

	bool
	ThreadPlanStepRange::MischiefManaged ()
	{
	// If we have pushed some plans between ShouldStop & MischiefManaged, then we're not done...
	// I do this check first because we might have stepped somewhere that will fool InRange into
	// thinking it needs to step past the end of that line. This happens, for instance, when stepping
	// over inlined code that is in the middle of the current line.

	if (!m_no_more_plans)
	return false;

	bool done = true;
	if (!IsPlanComplete())
	{
	if (InRange())
	{
	done = false;
	}
	else
	{
	FrameComparison frame_order = CompareCurrentFrameToStartFrame();
	if (frame_order != eFrameCompareOlder)
	{
	if (m_no_more_plans)
	done = true;
	else
	done = false;
	}
	else
	done = true;
	}
	}

	if (done)
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	if (log)
	log->Printf("Completed step through range plan.");
	ClearNextBranchBreakpoint();
	ThreadPlan::MischiefManaged ();
	return true;
	}
	else
	{
	return false;
	}

	}

	bool
	ThreadPlanStepRange::IsPlanStale ()
	{
	Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_STEP));
	FrameComparison frame_order = CompareCurrentFrameToStartFrame();

	if (frame_order == eFrameCompareOlder)
	{
	if (log)
	{
	log->Printf("ThreadPlanStepRange::IsPlanStale returning true, we've stepped out.");
	}
	return true;
	}
	else if (frame_order == eFrameCompareEqual && InSymbol())
	{
	// If we are not in a place we should step through, we've gotten stale.
	// One tricky bit here is that some stubs don't push a frame, so we should.
	// check that we are in the same symbol.
	if (!InRange())
	{
	return true;
	}
	}
	return false;
	}