source/Expression/ClangUserExpression.cpp - platform/external/lldb - Gitiles

 //===-- ClangUserExpression.cpp -------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 // C Includes
 #include <stdio.h>
 #if HAVE_SYS_TYPES_H
 #  include <sys/types.h>
 #endif

 // C++ Includes
 #include <cstdlib>
 #include <string>
 #include <map>

 #include "lldb/Core/ConstString.h"
 #include "lldb/Core/Log.h"
 #include "lldb/Core/StreamString.h"
 #include "lldb/Core/ValueObjectConstResult.h"
 #include "lldb/Expression/ClangExpressionDeclMap.h"
 #include "lldb/Expression/ClangExpressionParser.h"
 #include "lldb/Expression/ClangFunction.h"
 #include "lldb/Expression/ASTResultSynthesizer.h"
 #include "lldb/Expression/ClangUserExpression.h"
 #include "lldb/Host/Host.h"
 #include "lldb/Symbol/VariableList.h"
 #include "lldb/Target/ExecutionContext.h"
 #include "lldb/Target/StackFrame.h"
 #include "lldb/Target/Target.h"

 using namespace lldb_private;

 ClangUserExpression::ClangUserExpression (const char *expr,
                                           const char *expr_prefix) :
     m_expr_text(expr),
     m_expr_prefix(expr_prefix),
     m_transformed_text(),
     m_jit_addr(LLDB_INVALID_ADDRESS),
     m_cplusplus(false),
     m_objectivec(false),
     m_needs_object_ptr(false)
 {
 }

 ClangUserExpression::~ClangUserExpression ()
 {
 }

 clang::ASTConsumer *
 ClangUserExpression::ASTTransformer (clang::ASTConsumer *passthrough)
 {
     return new ASTResultSynthesizer(passthrough);
 }

 void
 ClangUserExpression::ScanContext(ExecutionContext &exe_ctx)
 {
     if (!exe_ctx.frame)
         return;

     VariableList *vars = exe_ctx.frame->GetVariableList(false);

     if (!vars)
         return;

     if (vars->FindVariable(ConstString("this")).get())
         m_cplusplus = true;
     else if (vars->FindVariable(ConstString("self")).get())
         m_objectivec = true;
 }

 // This is a really nasty hack, meant to fix Objective-C expressions of the form
 // (int)[myArray count].  Right now, because the type information for count is
 // not available, [myArray count] returns id, which can't be directly cast to
 // int without causing a clang error.
 static void
 ApplyObjcCastHack(std::string &expr)
 {
 #define OBJC_CAST_HACK_FROM "(int)["
 #define OBJC_CAST_HACK_TO   "(int)(long long)["

     size_t from_offset;

     while ((from_offset = expr.find(OBJC_CAST_HACK_FROM)) != expr.npos)
         expr.replace(from_offset, sizeof(OBJC_CAST_HACK_FROM) - 1, OBJC_CAST_HACK_TO);

 #undef OBJC_CAST_HACK_TO
 #undef OBJC_CAST_HACK_FROM
 }

 // Another hack, meant to allow use of unichar despite it not being available in
 // the type information.  Although we could special-case it in type lookup,
 // hopefully we'll figure out a way to #include the same environment as is
 // present in the original source file rather than try to hack specific type
 // definitions in as needed.
 static void
 ApplyUnicharHack(std::string &expr)
 {
 #define UNICHAR_HACK_FROM "unichar"
 #define UNICHAR_HACK_TO   "unsigned short"

     size_t from_offset;

     while ((from_offset = expr.find(UNICHAR_HACK_FROM)) != expr.npos)
         expr.replace(from_offset, sizeof(UNICHAR_HACK_FROM) - 1, UNICHAR_HACK_TO);

 #undef UNICHAR_HACK_TO
 #undef UNICHAR_HACK_FROM
 }

 bool
 ClangUserExpression::Parse (Stream &error_stream, ExecutionContext &exe_ctx)
 {
     Log *log = lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS);

     ScanContext(exe_ctx);

     StreamString m_transformed_stream;

     ////////////////////////////////////
     // Generate the expression
     //

     ApplyObjcCastHack(m_expr_text);
     //ApplyUnicharHack(m_expr_text);

     if (m_cplusplus)
     {
         m_transformed_stream.Printf("%s                                     \n"
                                     "typedef unsigned short unichar;        \n"
                                     "void                                   \n"
                                     "$__lldb_class::%s(void *$__lldb_arg)   \n"
                                     "{                                      \n"
                                     "    %s;                                \n"
                                     "}                                      \n",
                                     m_expr_prefix.c_str(),
                                     FunctionName(),
                                     m_expr_text.c_str());

         m_needs_object_ptr = true;
     }
     else
     {
         m_transformed_stream.Printf("%s                             \n"
                                     "typedef unsigned short unichar;\n"
                                     "void                           \n"
                                     "%s(void *$__lldb_arg)          \n"
                                     "{                              \n"
                                     "    %s;                        \n"
                                     "}                              \n",
                                     m_expr_prefix.c_str(),
                                     FunctionName(),
                                     m_expr_text.c_str());
     }

     m_transformed_text = m_transformed_stream.GetData();


     if (log)
         log->Printf("Parsing the following code:\n%s", m_transformed_text.c_str());

     ////////////////////////////////////
     // Set up the target and compiler
     //

     Target *target = exe_ctx.target;

     if (!target)
     {
         error_stream.PutCString ("error: invalid target\n");
         return false;
     }

     ConstString target_triple;

     target->GetTargetTriple (target_triple);

     if (!target_triple)
         target_triple = Host::GetTargetTriple ();

     if (!target_triple)
     {
         error_stream.PutCString ("error: invalid target triple\n");
         return false;
     }

     //////////////////////////
     // Parse the expression
     //

     m_expr_decl_map.reset(new ClangExpressionDeclMap(&exe_ctx));

     ClangExpressionParser parser(target_triple.GetCString(), *this);

     unsigned num_errors = parser.Parse (error_stream);

     if (num_errors)
     {
         error_stream.Printf ("error: %d errors parsing expression\n", num_errors);
         return false;
     }

     ///////////////////////////////////////////////
     // Convert the output of the parser to DWARF
     //

     m_dwarf_opcodes.reset(new StreamString);
     m_dwarf_opcodes->SetByteOrder (lldb::eByteOrderHost);
     m_dwarf_opcodes->GetFlags ().Set (Stream::eBinary);

     m_local_variables.reset(new ClangExpressionVariableStore());

     Error dwarf_error = parser.MakeDWARF ();

     if (dwarf_error.Success())
     {
         if (log)
             log->Printf("Code can be interpreted.");

         return true;
     }

     //////////////////////////////////
     // JIT the output of the parser
     //

     m_dwarf_opcodes.reset();

     lldb::addr_t jit_end;

     Error jit_error = parser.MakeJIT (m_jit_addr, jit_end, exe_ctx);

     if (jit_error.Success())
     {
         if (log)
         {
             log->Printf("Code can be run in the target.");

             StreamString disassembly_stream;

             Error err = parser.DisassembleFunction(disassembly_stream, exe_ctx);

             if (!err.Success())
             {
                 log->Printf("Couldn't disassemble function : %s", err.AsCString("unknown error"));
             }
             else
             {
                 log->Printf("Function disassembly:\n%s", disassembly_stream.GetData());
             }
         }

         return true;
     }
     else
     {
         error_stream.Printf ("error: expression can't be interpreted or run\n", num_errors);
         return false;
     }
 }

 bool
 ClangUserExpression::PrepareToExecuteJITExpression (Stream &error_stream,
                                                     ExecutionContext &exe_ctx,
                                                     lldb::addr_t &struct_address,
                                                     lldb::addr_t &object_ptr)
 {
     Log *log = lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS);

     if (m_jit_addr != LLDB_INVALID_ADDRESS)
     {

         Error materialize_error;


         if (m_needs_object_ptr && !(m_expr_decl_map->GetObjectPointer(object_ptr, &exe_ctx, materialize_error)))
         {
             error_stream.Printf("Couldn't get required object pointer: %s\n", materialize_error.AsCString());
             return false;
         }

         if (!m_expr_decl_map->Materialize(&exe_ctx, struct_address, materialize_error))
         {
             error_stream.Printf("Couldn't materialize struct: %s\n", materialize_error.AsCString());
             return false;
         }

         if (log)
         {
             log->Printf("Function address  : 0x%llx", (uint64_t)m_jit_addr);

             if (m_needs_object_ptr)
                 log->Printf("Object pointer    : 0x%llx", (uint64_t)object_ptr);

             log->Printf("Structure address : 0x%llx", (uint64_t)struct_address);

             StreamString args;

             Error dump_error;

             if (struct_address)
             {
                 if (!m_expr_decl_map->DumpMaterializedStruct(&exe_ctx, args, dump_error))
                 {
                     log->Printf("Couldn't extract variable values : %s", dump_error.AsCString("unknown error"));
                 }
                 else
                 {
                     log->Printf("Structure contents:\n%s", args.GetData());
                 }
             }
         }
     }
     return true;
 }

 ThreadPlan *
 ClangUserExpression::GetThreadPlanToExecuteJITExpression (Stream &error_stream,
                                        ExecutionContext &exe_ctx)
 {
     lldb::addr_t struct_address;

     lldb::addr_t object_ptr = NULL;

     PrepareToExecuteJITExpression (error_stream, exe_ctx, struct_address, object_ptr);

     return ClangFunction::GetThreadPlanToCallFunction (exe_ctx,
                                         m_jit_addr,
                                         struct_address,
                                         error_stream,
                                         true,
                                         true,
                                         (m_needs_object_ptr ? &object_ptr : NULL));
 }

 bool
 ClangUserExpression::FinalizeJITExecution (Stream &error_stream,
                                            ExecutionContext &exe_ctx,
                                            ClangExpressionVariable *&result)
 {
     Error expr_error;

     if (!m_expr_decl_map->Dematerialize(&exe_ctx, result, expr_error))
     {
         error_stream.Printf ("Couldn't dematerialize struct : %s\n", expr_error.AsCString("unknown error"));
         return false;
     }
     return true;
 }

 bool
 ClangUserExpression::Execute (Stream &error_stream,
                               ExecutionContext &exe_ctx,
                               ClangExpressionVariable *&result)
 {
     if (m_dwarf_opcodes.get())
     {
         // TODO execute the JITted opcodes

         error_stream.Printf("We don't currently support executing DWARF expressions");

         return false;
     }
     else if (m_jit_addr != LLDB_INVALID_ADDRESS)
     {
         lldb::addr_t struct_address;

         lldb::addr_t object_ptr = NULL;

         PrepareToExecuteJITExpression (error_stream, exe_ctx, struct_address, object_ptr);

         ClangFunction::ExecutionResults execution_result =
         ClangFunction::ExecuteFunction (exe_ctx,
                                         m_jit_addr,
                                         struct_address,
                                         true,
                                         true,
                                         10000000,
                                         error_stream,
                                         (m_needs_object_ptr ? &object_ptr : NULL));

         if (execution_result != ClangFunction::eExecutionCompleted)
         {
             const char *result_name;

             switch (execution_result)
             {
                 case ClangFunction::eExecutionCompleted:
                     result_name = "eExecutionCompleted";
                     break;
                 case ClangFunction::eExecutionDiscarded:
                     result_name = "eExecutionDiscarded";
                     break;
                 case ClangFunction::eExecutionInterrupted:
                     result_name = "eExecutionInterrupted";
                     break;
                 case ClangFunction::eExecutionSetupError:
                     result_name = "eExecutionSetupError";
                     break;
                 case ClangFunction::eExecutionTimedOut:
                     result_name = "eExecutionTimedOut";
                     break;
             }

             error_stream.Printf ("Couldn't execute function; result was %s\n", result_name);
             return false;
         }

         return FinalizeJITExecution (error_stream, exe_ctx, result);
     }
     else
     {
         error_stream.Printf("Expression can't be run; neither DWARF nor a JIT compiled function are present");
         return false;
     }
 }

 StreamString &
 ClangUserExpression::DwarfOpcodeStream ()
 {
     if (!m_dwarf_opcodes.get())
         m_dwarf_opcodes.reset(new StreamString());

     return *m_dwarf_opcodes.get();
 }


 lldb::ValueObjectSP
 ClangUserExpression::Evaluate (ExecutionContext &exe_ctx,
                                const char *expr_cstr,
                                const char *expr_prefix)
 {
     Error error;
     lldb::ValueObjectSP result_valobj_sp;
     ClangUserExpression user_expression (expr_cstr, expr_prefix);

     StreamString error_stream;

     if (!user_expression.Parse (error_stream, exe_ctx))
     {
         if (error_stream.GetString().empty())
             error.SetErrorString ("expression failed to parse, unknown error");
         else
             error.SetErrorString (error_stream.GetString().c_str());
     }
     else
     {
         ClangExpressionVariable *expr_result = NULL;

         error_stream.GetString().clear();

         if (!user_expression.Execute (error_stream, exe_ctx, expr_result))
         {
             if (error_stream.GetString().empty())
                 error.SetErrorString ("expression failed to execute, unknown error");
             else
                 error.SetErrorString (error_stream.GetString().c_str());
         }
         else
         {
             // TODO: seems weird to get a pointer to a result object back from
             // a function. Do we own it? Feels like we do, but from looking at the
             // code we don't. Might be best to make this a reference and state
             // explicitly that we don't own it when we get a reference back from
             // the execute?
             if (expr_result)
             {
                 result_valobj_sp = expr_result->GetExpressionResult (&exe_ctx);
             }
             else
             {
                 error.SetErrorString ("Expression did not return a result");
             }
         }
     }

     if (result_valobj_sp.get() == NULL)
         result_valobj_sp.reset (new ValueObjectConstResult (error));

     return result_valobj_sp;
 }
	//===-- ClangUserExpression.cpp -------------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	// C Includes
	#include <stdio.h>
	#if HAVE_SYS_TYPES_H
	# include <sys/types.h>
	#endif

	// C++ Includes
	#include <cstdlib>
	#include <string>
	#include <map>

	#include "lldb/Core/ConstString.h"
	#include "lldb/Core/Log.h"
	#include "lldb/Core/StreamString.h"
	#include "lldb/Core/ValueObjectConstResult.h"
	#include "lldb/Expression/ClangExpressionDeclMap.h"
	#include "lldb/Expression/ClangExpressionParser.h"
	#include "lldb/Expression/ClangFunction.h"
	#include "lldb/Expression/ASTResultSynthesizer.h"
	#include "lldb/Expression/ClangUserExpression.h"
	#include "lldb/Host/Host.h"
	#include "lldb/Symbol/VariableList.h"
	#include "lldb/Target/ExecutionContext.h"
	#include "lldb/Target/StackFrame.h"
	#include "lldb/Target/Target.h"

	using namespace lldb_private;

	ClangUserExpression::ClangUserExpression (const char *expr,
	const char *expr_prefix) :
	m_expr_text(expr),
	m_expr_prefix(expr_prefix),
	m_transformed_text(),
	m_jit_addr(LLDB_INVALID_ADDRESS),
	m_cplusplus(false),
	m_objectivec(false),
	m_needs_object_ptr(false)
	{
	}

	ClangUserExpression::~ClangUserExpression ()
	{
	}

	clang::ASTConsumer *
	ClangUserExpression::ASTTransformer (clang::ASTConsumer *passthrough)
	{
	return new ASTResultSynthesizer(passthrough);
	}

	void
	ClangUserExpression::ScanContext(ExecutionContext &exe_ctx)
	{
	if (!exe_ctx.frame)
	return;

	VariableList *vars = exe_ctx.frame->GetVariableList(false);

	if (!vars)
	return;

	if (vars->FindVariable(ConstString("this")).get())
	m_cplusplus = true;
	else if (vars->FindVariable(ConstString("self")).get())
	m_objectivec = true;
	}

	// This is a really nasty hack, meant to fix Objective-C expressions of the form
	// (int)[myArray count]. Right now, because the type information for count is
	// not available, [myArray count] returns id, which can't be directly cast to
	// int without causing a clang error.
	static void
	ApplyObjcCastHack(std::string &expr)
	{
	#define OBJC_CAST_HACK_FROM "(int)["
	#define OBJC_CAST_HACK_TO "(int)(long long)["

	size_t from_offset;

	while ((from_offset = expr.find(OBJC_CAST_HACK_FROM)) != expr.npos)
	expr.replace(from_offset, sizeof(OBJC_CAST_HACK_FROM) - 1, OBJC_CAST_HACK_TO);

	#undef OBJC_CAST_HACK_TO
	#undef OBJC_CAST_HACK_FROM
	}

	// Another hack, meant to allow use of unichar despite it not being available in
	// the type information. Although we could special-case it in type lookup,
	// hopefully we'll figure out a way to #include the same environment as is
	// present in the original source file rather than try to hack specific type
	// definitions in as needed.
	static void
	ApplyUnicharHack(std::string &expr)
	{
	#define UNICHAR_HACK_FROM "unichar"
	#define UNICHAR_HACK_TO "unsigned short"

	size_t from_offset;

	while ((from_offset = expr.find(UNICHAR_HACK_FROM)) != expr.npos)
	expr.replace(from_offset, sizeof(UNICHAR_HACK_FROM) - 1, UNICHAR_HACK_TO);

	#undef UNICHAR_HACK_TO
	#undef UNICHAR_HACK_FROM
	}

	bool
	ClangUserExpression::Parse (Stream &error_stream, ExecutionContext &exe_ctx)
	{
	Log *log = lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS);

	ScanContext(exe_ctx);

	StreamString m_transformed_stream;

	////////////////////////////////////
	// Generate the expression
	//

	ApplyObjcCastHack(m_expr_text);
	//ApplyUnicharHack(m_expr_text);

	if (m_cplusplus)
	{
	m_transformed_stream.Printf("%s \n"
	"typedef unsigned short unichar; \n"
	"void \n"
	"$__lldb_class::%s(void *$__lldb_arg) \n"
	"{ \n"
	" %s; \n"
	"} \n",
	m_expr_prefix.c_str(),
	FunctionName(),
	m_expr_text.c_str());

	m_needs_object_ptr = true;
	}
	else
	{
	m_transformed_stream.Printf("%s \n"
	"typedef unsigned short unichar;\n"
	"void \n"
	"%s(void *$__lldb_arg) \n"
	"{ \n"
	" %s; \n"
	"} \n",
	m_expr_prefix.c_str(),
	FunctionName(),
	m_expr_text.c_str());
	}

	m_transformed_text = m_transformed_stream.GetData();


	if (log)
	log->Printf("Parsing the following code:\n%s", m_transformed_text.c_str());

	////////////////////////////////////
	// Set up the target and compiler
	//

	Target *target = exe_ctx.target;

	if (!target)
	{
	error_stream.PutCString ("error: invalid target\n");
	return false;
	}

	ConstString target_triple;

	target->GetTargetTriple (target_triple);

	if (!target_triple)
	target_triple = Host::GetTargetTriple ();

	if (!target_triple)
	{
	error_stream.PutCString ("error: invalid target triple\n");
	return false;
	}

	//////////////////////////
	// Parse the expression
	//

	m_expr_decl_map.reset(new ClangExpressionDeclMap(&exe_ctx));

	ClangExpressionParser parser(target_triple.GetCString(), *this);

	unsigned num_errors = parser.Parse (error_stream);

	if (num_errors)
	{
	error_stream.Printf ("error: %d errors parsing expression\n", num_errors);
	return false;
	}

	///////////////////////////////////////////////
	// Convert the output of the parser to DWARF
	//

	m_dwarf_opcodes.reset(new StreamString);
	m_dwarf_opcodes->SetByteOrder (lldb::eByteOrderHost);
	m_dwarf_opcodes->GetFlags ().Set (Stream::eBinary);

	m_local_variables.reset(new ClangExpressionVariableStore());

	Error dwarf_error = parser.MakeDWARF ();

	if (dwarf_error.Success())
	{
	if (log)
	log->Printf("Code can be interpreted.");

	return true;
	}

	//////////////////////////////////
	// JIT the output of the parser
	//

	m_dwarf_opcodes.reset();

	lldb::addr_t jit_end;

	Error jit_error = parser.MakeJIT (m_jit_addr, jit_end, exe_ctx);

	if (jit_error.Success())
	{
	if (log)
	{
	log->Printf("Code can be run in the target.");

	StreamString disassembly_stream;

	Error err = parser.DisassembleFunction(disassembly_stream, exe_ctx);

	if (!err.Success())
	{
	log->Printf("Couldn't disassemble function : %s", err.AsCString("unknown error"));
	}
	else
	{
	log->Printf("Function disassembly:\n%s", disassembly_stream.GetData());
	}
	}

	return true;
	}
	else
	{
	error_stream.Printf ("error: expression can't be interpreted or run\n", num_errors);
	return false;
	}
	}

	bool
	ClangUserExpression::PrepareToExecuteJITExpression (Stream &error_stream,
	ExecutionContext &exe_ctx,
	lldb::addr_t &struct_address,
	lldb::addr_t &object_ptr)
	{
	Log *log = lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_EXPRESSIONS);

	if (m_jit_addr != LLDB_INVALID_ADDRESS)
	{

	Error materialize_error;


	if (m_needs_object_ptr && !(m_expr_decl_map->GetObjectPointer(object_ptr, &exe_ctx, materialize_error)))
	{
	error_stream.Printf("Couldn't get required object pointer: %s\n", materialize_error.AsCString());
	return false;
	}

	if (!m_expr_decl_map->Materialize(&exe_ctx, struct_address, materialize_error))
	{
	error_stream.Printf("Couldn't materialize struct: %s\n", materialize_error.AsCString());
	return false;
	}

	if (log)
	{
	log->Printf("Function address : 0x%llx", (uint64_t)m_jit_addr);

	if (m_needs_object_ptr)
	log->Printf("Object pointer : 0x%llx", (uint64_t)object_ptr);

	log->Printf("Structure address : 0x%llx", (uint64_t)struct_address);

	StreamString args;

	Error dump_error;

	if (struct_address)
	{
	if (!m_expr_decl_map->DumpMaterializedStruct(&exe_ctx, args, dump_error))
	{
	log->Printf("Couldn't extract variable values : %s", dump_error.AsCString("unknown error"));
	}
	else
	{
	log->Printf("Structure contents:\n%s", args.GetData());
	}
	}
	}
	}
	return true;
	}

	ThreadPlan *
	ClangUserExpression::GetThreadPlanToExecuteJITExpression (Stream &error_stream,
	ExecutionContext &exe_ctx)
	{
	lldb::addr_t struct_address;

	lldb::addr_t object_ptr = NULL;

	PrepareToExecuteJITExpression (error_stream, exe_ctx, struct_address, object_ptr);

	return ClangFunction::GetThreadPlanToCallFunction (exe_ctx,
	m_jit_addr,
	struct_address,
	error_stream,
	true,
	true,
	(m_needs_object_ptr ? &object_ptr : NULL));
	}

	bool
	ClangUserExpression::FinalizeJITExecution (Stream &error_stream,
	ExecutionContext &exe_ctx,
	ClangExpressionVariable *&result)
	{
	Error expr_error;

	if (!m_expr_decl_map->Dematerialize(&exe_ctx, result, expr_error))
	{
	error_stream.Printf ("Couldn't dematerialize struct : %s\n", expr_error.AsCString("unknown error"));
	return false;
	}
	return true;
	}

	bool
	ClangUserExpression::Execute (Stream &error_stream,
	ExecutionContext &exe_ctx,
	ClangExpressionVariable *&result)
	{
	if (m_dwarf_opcodes.get())
	{
	// TODO execute the JITted opcodes

	error_stream.Printf("We don't currently support executing DWARF expressions");

	return false;
	}
	else if (m_jit_addr != LLDB_INVALID_ADDRESS)
	{
	lldb::addr_t struct_address;

	lldb::addr_t object_ptr = NULL;

	PrepareToExecuteJITExpression (error_stream, exe_ctx, struct_address, object_ptr);

	ClangFunction::ExecutionResults execution_result =
	ClangFunction::ExecuteFunction (exe_ctx,
	m_jit_addr,
	struct_address,
	true,
	true,
	10000000,
	error_stream,
	(m_needs_object_ptr ? &object_ptr : NULL));

	if (execution_result != ClangFunction::eExecutionCompleted)
	{
	const char *result_name;

	switch (execution_result)
	{
	case ClangFunction::eExecutionCompleted:
	result_name = "eExecutionCompleted";
	break;
	case ClangFunction::eExecutionDiscarded:
	result_name = "eExecutionDiscarded";
	break;
	case ClangFunction::eExecutionInterrupted:
	result_name = "eExecutionInterrupted";
	break;
	case ClangFunction::eExecutionSetupError:
	result_name = "eExecutionSetupError";
	break;
	case ClangFunction::eExecutionTimedOut:
	result_name = "eExecutionTimedOut";
	break;
	}

	error_stream.Printf ("Couldn't execute function; result was %s\n", result_name);
	return false;
	}

	return FinalizeJITExecution (error_stream, exe_ctx, result);
	}
	else
	{
	error_stream.Printf("Expression can't be run; neither DWARF nor a JIT compiled function are present");
	return false;
	}
	}

	StreamString &
	ClangUserExpression::DwarfOpcodeStream ()
	{
	if (!m_dwarf_opcodes.get())
	m_dwarf_opcodes.reset(new StreamString());

	return *m_dwarf_opcodes.get();
	}


	lldb::ValueObjectSP
	ClangUserExpression::Evaluate (ExecutionContext &exe_ctx,
	const char *expr_cstr,
	const char *expr_prefix)
	{
	Error error;
	lldb::ValueObjectSP result_valobj_sp;
	ClangUserExpression user_expression (expr_cstr, expr_prefix);

	StreamString error_stream;

	if (!user_expression.Parse (error_stream, exe_ctx))
	{
	if (error_stream.GetString().empty())
	error.SetErrorString ("expression failed to parse, unknown error");
	else
	error.SetErrorString (error_stream.GetString().c_str());
	}
	else
	{
	ClangExpressionVariable *expr_result = NULL;

	error_stream.GetString().clear();

	if (!user_expression.Execute (error_stream, exe_ctx, expr_result))
	{
	if (error_stream.GetString().empty())
	error.SetErrorString ("expression failed to execute, unknown error");
	else
	error.SetErrorString (error_stream.GetString().c_str());
	}
	else
	{
	// TODO: seems weird to get a pointer to a result object back from
	// a function. Do we own it? Feels like we do, but from looking at the
	// code we don't. Might be best to make this a reference and state
	// explicitly that we don't own it when we get a reference back from
	// the execute?
	if (expr_result)
	{
	result_valobj_sp = expr_result->GetExpressionResult (&exe_ctx);
	}
	else
	{
	error.SetErrorString ("Expression did not return a result");
	}
	}
	}

	if (result_valobj_sp.get() == NULL)
	result_valobj_sp.reset (new ValueObjectConstResult (error));

	return result_valobj_sp;
	}