llvm-project/lldb/source/Commands/CommandObjectMemory.cpp

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//===-- CommandObjectMemory.cpp ---------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "CommandObjectMemory.h"
// C Includes
// C++ Includes
// Other libraries and framework includes
// Project includes
#include "lldb/Core/DataBufferHeap.h"
#include "lldb/Core/DataExtractor.h"
#include "lldb/Core/Debugger.h"
#include "lldb/Core/StreamString.h"
#include "lldb/Core/ValueObjectMemory.h"
#include "lldb/Interpreter/Args.h"
#include "lldb/Interpreter/CommandReturnObject.h"
#include "lldb/Interpreter/CommandInterpreter.h"
#include "lldb/Interpreter/Options.h"
#include "lldb/Interpreter/OptionGroupFormat.h"
#include "lldb/Interpreter/OptionGroupOutputFile.h"
#include "lldb/Interpreter/OptionGroupValueObjectDisplay.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/StackFrame.h"
using namespace lldb;
using namespace lldb_private;
static OptionDefinition
g_option_table[] =
{
{ LLDB_OPT_SET_1|
LLDB_OPT_SET_2, false, "size" ,'s', required_argument, NULL, 0, eArgTypeByteSize ,"The size in bytes to use when displaying with the selected format."},
{ LLDB_OPT_SET_1|
LLDB_OPT_SET_3, false, "count" ,'c', required_argument, NULL, 0, eArgTypeCount ,"The number of total items to display."},
{ LLDB_OPT_SET_1, false, "num-per-line" ,'l', required_argument, NULL, 0, eArgTypeNumberPerLine ,"The number of items per line to display."},
{ LLDB_OPT_SET_2, false, "binary" ,'b', no_argument , NULL, 0, eArgTypeNone ,"If true, memory will be saved as binary. If false, the memory is saved save as an ASCII dump that uses the format, size, count and number per line settings."},
{ LLDB_OPT_SET_3, true , "view-as" ,'t', required_argument, NULL, 0, eArgTypeNone ,"The name of a type to view memory as."},
};
class OptionGroupReadMemory : public OptionGroup
{
public:
OptionGroupReadMemory () :
m_byte_size (1,1),
m_count (8,8),
m_num_per_line (1,1),
m_output_as_binary (false),
m_view_as_type()
{
}
virtual
~OptionGroupReadMemory ()
{
}
virtual uint32_t
GetNumDefinitions ()
{
return sizeof (g_option_table) / sizeof (OptionDefinition);
}
virtual const OptionDefinition*
GetDefinitions ()
{
return g_option_table;
}
virtual Error
SetOptionValue (CommandInterpreter &interpreter,
uint32_t option_idx,
const char *option_arg)
{
Error error;
char short_option = (char) g_option_table[option_idx].short_option;
switch (short_option)
{
case 'l':
error = m_num_per_line.SetValueFromCString (option_arg);
if (m_num_per_line.GetCurrentValue() == 0)
error.SetErrorStringWithFormat("Invalid value for --num-per-line option '%s'. Must be positive integer value.\n", option_arg);
break;
case 'c':
error = m_count.SetValueFromCString (option_arg);
if (m_count.GetCurrentValue() == 0)
error.SetErrorStringWithFormat("Invalid value for --count option '%s'. Must be positive integer value.\n", option_arg);
break;
case 's':
error = m_byte_size.SetValueFromCString (option_arg);
if (m_byte_size.GetCurrentValue() == 0)
error.SetErrorStringWithFormat("Invalid value for --size option '%s'. Must be positive integer value.\n", option_arg);
break;
case 'b':
m_output_as_binary = true;
break;
case 't':
error = m_view_as_type.SetValueFromCString (option_arg);
break;
default:
error.SetErrorStringWithFormat("Unrecognized short option '%c'.\n", short_option);
break;
}
return error;
}
virtual void
OptionParsingStarting (CommandInterpreter &interpreter)
{
m_byte_size.Clear();
m_count.Clear();
m_num_per_line.Clear();
m_output_as_binary = false;
m_view_as_type.Clear();
}
Error
FinalizeSettings (Target *target, const OptionGroupFormat& format_options)
{
Error error;
bool byte_size_option_set = m_byte_size.OptionWasSet();
const bool num_per_line_option_set = m_num_per_line.OptionWasSet();
const bool count_option_set = m_count.OptionWasSet();
uint32_t format_byte_size = format_options.GetByteSize();
if (byte_size_option_set)
{
if (format_byte_size > 0)
{
error.SetErrorString("can't specify the byte size in both the '--size <num>' option and the '--format [<byte-size>]<format-char>' options.");
return error;
}
}
else
{
if (format_byte_size != 0)
{
byte_size_option_set = true;
m_byte_size = format_byte_size;
}
}
switch (format_options.GetFormat())
{
default:
break;
case eFormatBoolean:
if (!byte_size_option_set)
m_byte_size = 1;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
m_count = 8;
break;
case eFormatCString:
break;
case eFormatPointer:
m_byte_size = target->GetArchitecture().GetAddressByteSize();
if (!num_per_line_option_set)
m_num_per_line = 4;
if (!count_option_set)
m_count = 8;
break;
case eFormatBinary:
case eFormatFloat:
case eFormatOctal:
case eFormatDecimal:
case eFormatEnum:
case eFormatUnicode16:
case eFormatUnicode32:
case eFormatUnsigned:
if (!byte_size_option_set)
m_byte_size = 4;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
m_count = 8;
break;
case eFormatBytes:
case eFormatBytesWithASCII:
if (m_byte_size.OptionWasSet())
{
if (m_byte_size > 1)
error.SetErrorString ("use --count option to specify an end address to display a number of bytes");
}
else
m_byte_size = 1;
if (!num_per_line_option_set)
m_num_per_line = 16;
if (!count_option_set)
m_count = 32;
break;
case eFormatChar:
case eFormatCharPrintable:
if (!byte_size_option_set)
m_byte_size = 1;
if (!num_per_line_option_set)
m_num_per_line = 32;
if (!count_option_set)
m_count = 64;
break;
case eFormatComplex:
if (!byte_size_option_set)
m_byte_size = 8;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
m_count = 8;
break;
case eFormatHex:
if (!byte_size_option_set)
m_byte_size = 4;
if (!num_per_line_option_set)
{
switch (m_byte_size)
{
case 1:
case 2:
m_num_per_line = 8;
break;
case 4:
m_num_per_line = 4;
break;
case 8:
m_num_per_line = 2;
break;
default:
m_num_per_line = 1;
break;
}
}
if (!count_option_set)
m_count = 8;
break;
case eFormatVectorOfChar:
case eFormatVectorOfSInt8:
case eFormatVectorOfUInt8:
case eFormatVectorOfSInt16:
case eFormatVectorOfUInt16:
case eFormatVectorOfSInt32:
case eFormatVectorOfUInt32:
case eFormatVectorOfSInt64:
case eFormatVectorOfUInt64:
case eFormatVectorOfFloat32:
case eFormatVectorOfFloat64:
case eFormatVectorOfUInt128:
if (!byte_size_option_set)
m_byte_size = 128;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
m_count = 4;
break;
}
return error;
}
OptionValueUInt64 m_byte_size;
OptionValueUInt64 m_count;
OptionValueUInt64 m_num_per_line;
bool m_output_as_binary;
OptionValueString m_view_as_type;
};
//----------------------------------------------------------------------
// Read memory from the inferior process
//----------------------------------------------------------------------
class CommandObjectMemoryRead : public CommandObject
{
public:
CommandObjectMemoryRead (CommandInterpreter &interpreter) :
CommandObject (interpreter,
"memory read",
"Read from the memory of the process being debugged.",
NULL,
eFlagProcessMustBeLaunched),
m_option_group (interpreter),
m_format_options (eFormatBytesWithASCII, 0, true),
m_memory_options (),
m_outfile_options (),
m_varobj_options()
{
CommandArgumentEntry arg1;
CommandArgumentEntry arg2;
CommandArgumentData start_addr_arg;
CommandArgumentData end_addr_arg;
// Define the first (and only) variant of this arg.
start_addr_arg.arg_type = eArgTypeStartAddress;
start_addr_arg.arg_repetition = eArgRepeatPlain;
// There is only one variant this argument could be; put it into the argument entry.
arg1.push_back (start_addr_arg);
// Define the first (and only) variant of this arg.
end_addr_arg.arg_type = eArgTypeEndAddress;
end_addr_arg.arg_repetition = eArgRepeatOptional;
// There is only one variant this argument could be; put it into the argument entry.
arg2.push_back (end_addr_arg);
// Push the data for the first argument into the m_arguments vector.
m_arguments.push_back (arg1);
m_arguments.push_back (arg2);
m_option_group.Append (&m_format_options, LLDB_OPT_SET_ALL, LLDB_OPT_SET_1 | LLDB_OPT_SET_3);
m_option_group.Append (&m_memory_options);
m_option_group.Append (&m_outfile_options, LLDB_OPT_SET_ALL, LLDB_OPT_SET_1 | LLDB_OPT_SET_2 | LLDB_OPT_SET_3);
m_option_group.Append (&m_varobj_options, LLDB_OPT_SET_ALL, LLDB_OPT_SET_3);
m_option_group.Finalize();
}
virtual
~CommandObjectMemoryRead ()
{
}
Options *
GetOptions ()
{
return &m_option_group;
}
virtual bool
Execute (Args& command,
CommandReturnObject &result)
{
ExecutionContext exe_ctx (m_interpreter.GetExecutionContext());
if (exe_ctx.process == NULL)
{
result.AppendError("need a process to read memory");
result.SetStatus(eReturnStatusFailed);
return false;
}
const size_t argc = command.GetArgumentCount();
if (argc == 0 || argc > 2)
{
result.AppendErrorWithFormat ("%s takes 1 or two args.\n", m_cmd_name.c_str());
result.SetStatus(eReturnStatusFailed);
return false;
}
ClangASTType clang_ast_type;
Error error;
Format format = m_format_options.GetFormat();
const char *view_as_type_cstr = m_memory_options.m_view_as_type.GetCurrentValue();
if (view_as_type_cstr && view_as_type_cstr[0])
{
// We are viewing memory as a type
SymbolContext sc;
const bool append = true;
TypeList type_list;
uint32_t reference_count = 0;
uint32_t pointer_count = 0;
size_t idx;
static const char *g_keywords[] = { "const", "volatile", "restrict", "struct", "class", "union"};
static size_t g_num_keywords = sizeof(g_keywords)/sizeof(const char *);
std::string type_str(view_as_type_cstr);
// Remove all instances of g_keywords that are followed by spaces
for (size_t i = 0; i < g_num_keywords; ++i)
{
const char *keyword = g_keywords[i];
int keyword_len = ::strlen (keyword);
while ((idx = type_str.find (keyword)) != std::string::npos)
{
if (type_str[idx + keyword_len] == ' ' || type_str[idx + keyword_len] == '\t')
type_str.erase(idx, keyword_len+1);
}
}
bool done = type_str.empty();
//
idx = type_str.find_first_not_of (" \t");
if (idx > 0 && idx != std::string::npos)
type_str.erase (0, idx);
while (!done)
{
// Strip trailing spaces
if (type_str.empty())
done = true;
else
{
switch (type_str[type_str.size()-1])
{
case '*':
++pointer_count;
// fall through...
case ' ':
case '\t':
type_str.erase(type_str.size()-1);
break;
case '&':
if (reference_count == 0)
{
reference_count = 1;
type_str.erase(type_str.size()-1);
}
else
{
result.AppendErrorWithFormat ("invalid type string: '%s'\n", view_as_type_cstr);
result.SetStatus(eReturnStatusFailed);
return false;
}
break;
default:
done = true;
break;
}
}
}
ConstString lookup_type_name(type_str.c_str());
if (exe_ctx.frame)
{
sc = exe_ctx.frame->GetSymbolContext (eSymbolContextModule);
if (sc.module_sp)
{
sc.module_sp->FindTypes (sc,
lookup_type_name,
append,
1,
type_list);
}
}
if (type_list.GetSize() == 0)
{
exe_ctx.target->GetImages().FindTypes (sc,
lookup_type_name,
append,
1,
type_list);
}
if (type_list.GetSize() == 0)
{
result.AppendErrorWithFormat ("unable to find any types that match the raw type '%s' for full type '%s'\n",
lookup_type_name.GetCString(),
view_as_type_cstr);
result.SetStatus(eReturnStatusFailed);
return false;
}
TypeSP type_sp (type_list.GetTypeAtIndex(0));
clang_ast_type.SetClangType (type_sp->GetClangAST(), type_sp->GetClangFullType());
while (pointer_count > 0)
{
clang_type_t pointer_type = ClangASTContext::CreatePointerType (clang_ast_type.GetASTContext(), clang_ast_type.GetOpaqueQualType());
if (pointer_type)
clang_ast_type.SetClangType (clang_ast_type.GetASTContext(), pointer_type);
else
{
result.AppendError ("unable make a pointer type\n");
result.SetStatus(eReturnStatusFailed);
return false;
}
--pointer_count;
}
m_memory_options.m_byte_size = (clang_ast_type.GetClangTypeBitWidth () + 7) / 8;
if (m_memory_options.m_byte_size == 0)
{
result.AppendErrorWithFormat ("unable to get the byte size of the type '%s'\n",
view_as_type_cstr);
result.SetStatus(eReturnStatusFailed);
return false;
}
if (!m_memory_options.m_count.OptionWasSet())
m_memory_options.m_count = 1;
}
else
{
error = m_memory_options.FinalizeSettings (exe_ctx.target, m_format_options);
}
// Look for invalid combinations of settings
if (error.Fail())
{
result.AppendErrorWithFormat("%s", error.AsCString());
result.SetStatus(eReturnStatusFailed);
return false;
}
size_t item_count = m_memory_options.m_count.GetCurrentValue();
const size_t item_byte_size = m_memory_options.m_byte_size;
const size_t num_per_line = m_memory_options.m_num_per_line.GetCurrentValue();
size_t total_byte_size = item_count * item_byte_size;
if (total_byte_size == 0)
total_byte_size = 32;
lldb::addr_t addr = Args::StringToUInt64(command.GetArgumentAtIndex(0), LLDB_INVALID_ADDRESS, 0);
if (addr == LLDB_INVALID_ADDRESS)
{
result.AppendErrorWithFormat("invalid start address string '%s'.\n", command.GetArgumentAtIndex(0));
result.SetStatus(eReturnStatusFailed);
return false;
}
if (argc == 2)
{
lldb::addr_t end_addr = Args::StringToUInt64(command.GetArgumentAtIndex(1), LLDB_INVALID_ADDRESS, 0);
if (end_addr == LLDB_INVALID_ADDRESS)
{
result.AppendErrorWithFormat("invalid end address string '%s'.\n", command.GetArgumentAtIndex(1));
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (end_addr <= addr)
{
result.AppendErrorWithFormat("end address (0x%llx) must be greater that the start address (0x%llx).\n", end_addr, addr);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (m_memory_options.m_count.OptionWasSet())
{
result.AppendErrorWithFormat("specify either the end address (0x%llx) or the count (--count %u), not both.\n", end_addr, item_count);
result.SetStatus(eReturnStatusFailed);
return false;
}
total_byte_size = end_addr - addr;
item_count = total_byte_size / item_byte_size;
}
DataBufferSP data_sp;
size_t bytes_read = 0;
if (!clang_ast_type.GetOpaqueQualType())
{
data_sp.reset (new DataBufferHeap (total_byte_size, '\0'));
bytes_read = exe_ctx.process->ReadMemory(addr, data_sp->GetBytes (), data_sp->GetByteSize(), error);
if (bytes_read == 0)
{
result.AppendWarningWithFormat("Read from 0x%llx failed.\n", addr);
result.AppendError(error.AsCString());
result.SetStatus(eReturnStatusFailed);
return false;
}
if (bytes_read < total_byte_size)
result.AppendWarningWithFormat("Not all bytes (%u/%u) were able to be read from 0x%llx.\n", bytes_read, total_byte_size, addr);
}
StreamFile outfile_stream;
Stream *output_stream = NULL;
const FileSpec &outfile_spec = m_outfile_options.GetFile().GetCurrentValue();
if (outfile_spec)
{
char path[PATH_MAX];
outfile_spec.GetPath (path, sizeof(path));
uint32_t open_options = File::eOpenOptionWrite | File::eOpenOptionCanCreate;
const bool append = m_outfile_options.GetAppend().GetCurrentValue();
if (append)
open_options |= File::eOpenOptionAppend;
if (outfile_stream.GetFile ().Open (path, open_options).Success())
{
if (m_memory_options.m_output_as_binary)
{
int bytes_written = outfile_stream.Write (data_sp->GetBytes(), bytes_read);
if (bytes_written > 0)
{
result.GetOutputStream().Printf ("%i bytes %s to '%s'\n",
bytes_written,
append ? "appended" : "written",
path);
return true;
}
else
{
result.AppendErrorWithFormat("Failed to write %zu bytes to '%s'.\n", bytes_read, path);
result.SetStatus(eReturnStatusFailed);
return false;
}
}
else
{
// We are going to write ASCII to the file just point the
// output_stream to our outfile_stream...
output_stream = &outfile_stream;
}
}
else
{
result.AppendErrorWithFormat("Failed to open file '%s' for %s.\n", path, append ? "append" : "write");
result.SetStatus(eReturnStatusFailed);
return false;
}
}
else
{
output_stream = &result.GetOutputStream();
}
if (clang_ast_type.GetOpaqueQualType())
{
for (uint32_t i = 0; i<item_count; ++i)
{
addr_t item_addr = addr + (i * item_byte_size);
Address address (NULL, item_addr);
StreamString name_strm;
name_strm.Printf ("0x%llx", item_addr);
ValueObjectSP valobj_sp (ValueObjectMemory::Create (exe_ctx.GetBestExecutionContextScope(),
name_strm.GetString().c_str(),
address,
clang_ast_type));
if (valobj_sp)
{
if (format != eFormatDefault)
valobj_sp->SetFormat (format);
bool use_dynamic = false;
bool scope_already_checked = true;
ValueObject::DumpValueObject (*output_stream,
valobj_sp.get(),
NULL,
m_varobj_options.ptr_depth,
0,
m_varobj_options.max_depth,
m_varobj_options.show_types,
m_varobj_options.show_location,
m_varobj_options.use_objc,
use_dynamic,
scope_already_checked,
m_varobj_options.flat_output);
}
else
{
result.AppendErrorWithFormat ("failed to create a value object for: (%s) %s\n",
view_as_type_cstr,
name_strm.GetString().c_str());
result.SetStatus(eReturnStatusFailed);
return false;
}
}
return true;
}
result.SetStatus(eReturnStatusSuccessFinishResult);
DataExtractor data (data_sp,
exe_ctx.target->GetArchitecture().GetByteOrder(),
exe_ctx.target->GetArchitecture().GetAddressByteSize());
assert (output_stream);
data.Dump (output_stream,
0,
m_format_options.GetFormat(),
item_byte_size,
item_count,
num_per_line,
addr,
0,
0);
output_stream->EOL();
return true;
}
protected:
// CommandOptions m_options;
OptionGroupOptions m_option_group;
OptionGroupFormat m_format_options;
OptionGroupReadMemory m_memory_options;
OptionGroupOutputFile m_outfile_options;
OptionGroupValueObjectDisplay m_varobj_options;
};
//OptionDefinition
//CommandObjectMemoryRead::CommandOptions::g_option_table[] =
//{
//{ LLDB_OPT_SET_1, false, "format" ,'f', required_argument, NULL, 0, eArgTypeFormat ,"The format that will be used to display the memory. Defaults to bytes with ASCII (--format=Y)."},
//{ LLDB_OPT_SET_1, false, "size" ,'s', required_argument, NULL, 0, eArgTypeByteSize ,"The size in bytes to use when displaying with the selected format."},
//{ LLDB_OPT_SET_1, false, "num-per-line" ,'l', required_argument, NULL, 0, eArgTypeNumberPerLine ,"The number of items per line to display."},
//{ LLDB_OPT_SET_1|
// LLDB_OPT_SET_2|
// LLDB_OPT_SET_3, false, "count" ,'c', required_argument, NULL, 0, eArgTypeCount ,"The number of total items to display."},
//{ LLDB_OPT_SET_1|
// LLDB_OPT_SET_2|
// LLDB_OPT_SET_3, false, "outfile" ,'o', required_argument, NULL, 0, eArgTypeFilename ,"Dump memory read results into a file."},
//{ LLDB_OPT_SET_1|
// LLDB_OPT_SET_2|
// LLDB_OPT_SET_3, false, "append" ,'a', no_argument , NULL, 0, eArgTypeNone ,"Append memory read results to 'outfile'."},
//{ LLDB_OPT_SET_2, false, "binary" ,'b', no_argument , NULL, 0, eArgTypeNone ,"If true, memory will be saved as binary. If false, the memory is saved save as an ASCII dump that uses the format, size, count and number per line settings."},
//{ LLDB_OPT_SET_3, true , "view-as" ,'t', required_argument, NULL, 0, eArgTypeNone ,"The name of a type to view memory as."},
//{ 0 , false, NULL , 0 , 0 , NULL, 0, eArgTypeNone , NULL }
//};
//----------------------------------------------------------------------
// Write memory to the inferior process
//----------------------------------------------------------------------
class CommandObjectMemoryWrite : public CommandObject
{
public:
class CommandOptions : public Options
{
public:
CommandOptions (CommandInterpreter &interpreter) :
Options(interpreter)
{
Added two new classes for command options: lldb_private::OptionGroup lldb_private::OptionGroupOptions OptionGroup lets you define a class that encapsulates settings that you want to reuse in multiple commands. It contains only the option definitions and the ability to set the option values, but it doesn't directly interface with the lldb_private::Options class that is the front end to all of the CommandObject option parsing. For that the OptionGroupOptions class can be used. It aggregates one or more OptionGroup objects and directs the option setting to the appropriate OptionGroup class. For an example of this, take a look at the CommandObjectFile and how it uses its "m_option_group" object shown below to be able to set values in both the FileOptionGroup and PlatformOptionGroup classes. The members used in CommandObjectFile are: OptionGroupOptions m_option_group; FileOptionGroup m_file_options; PlatformOptionGroup m_platform_options; Then in the constructor for CommandObjectFile you can combine the option settings. The code below shows a simplified version of the constructor: CommandObjectFile::CommandObjectFile(CommandInterpreter &interpreter) : CommandObject (...), m_option_group (interpreter), m_file_options (), m_platform_options(true) { m_option_group.Append (&m_file_options); m_option_group.Append (&m_platform_options); m_option_group.Finalize(); } We append the m_file_options and then the m_platform_options and then tell the option group the finalize the results. This allows the m_option_group to become the organizer of our prefs and after option parsing we end up with valid preference settings in both the m_file_options and m_platform_options objects. This also allows any other commands to use the FileOptionGroup and PlatformOptionGroup classes to implement options for their commands. Renamed: virtual void Options::ResetOptionValues(); to: virtual void Options::OptionParsingStarting(); And implemented a new callback named: virtual Error Options::OptionParsingFinished(); This allows Options subclasses to verify that the options all go together after all of the options have been specified and gives the chance for the command object to return an error. It also gives a chance to take all of the option values and produce or initialize objects after all options have completed parsing. Modfied: virtual Error SetOptionValue (int option_idx, const char *option_arg) = 0; to be: virtual Error SetOptionValue (uint32_t option_idx, const char *option_arg) = 0; (option_idx is now unsigned). llvm-svn: 129415
2011-04-13 08:18:08 +08:00
OptionParsingStarting();
}
virtual
~CommandOptions ()
{
}
virtual Error
Added two new classes for command options: lldb_private::OptionGroup lldb_private::OptionGroupOptions OptionGroup lets you define a class that encapsulates settings that you want to reuse in multiple commands. It contains only the option definitions and the ability to set the option values, but it doesn't directly interface with the lldb_private::Options class that is the front end to all of the CommandObject option parsing. For that the OptionGroupOptions class can be used. It aggregates one or more OptionGroup objects and directs the option setting to the appropriate OptionGroup class. For an example of this, take a look at the CommandObjectFile and how it uses its "m_option_group" object shown below to be able to set values in both the FileOptionGroup and PlatformOptionGroup classes. The members used in CommandObjectFile are: OptionGroupOptions m_option_group; FileOptionGroup m_file_options; PlatformOptionGroup m_platform_options; Then in the constructor for CommandObjectFile you can combine the option settings. The code below shows a simplified version of the constructor: CommandObjectFile::CommandObjectFile(CommandInterpreter &interpreter) : CommandObject (...), m_option_group (interpreter), m_file_options (), m_platform_options(true) { m_option_group.Append (&m_file_options); m_option_group.Append (&m_platform_options); m_option_group.Finalize(); } We append the m_file_options and then the m_platform_options and then tell the option group the finalize the results. This allows the m_option_group to become the organizer of our prefs and after option parsing we end up with valid preference settings in both the m_file_options and m_platform_options objects. This also allows any other commands to use the FileOptionGroup and PlatformOptionGroup classes to implement options for their commands. Renamed: virtual void Options::ResetOptionValues(); to: virtual void Options::OptionParsingStarting(); And implemented a new callback named: virtual Error Options::OptionParsingFinished(); This allows Options subclasses to verify that the options all go together after all of the options have been specified and gives the chance for the command object to return an error. It also gives a chance to take all of the option values and produce or initialize objects after all options have completed parsing. Modfied: virtual Error SetOptionValue (int option_idx, const char *option_arg) = 0; to be: virtual Error SetOptionValue (uint32_t option_idx, const char *option_arg) = 0; (option_idx is now unsigned). llvm-svn: 129415
2011-04-13 08:18:08 +08:00
SetOptionValue (uint32_t option_idx, const char *option_arg)
{
Error error;
char short_option = (char) m_getopt_table[option_idx].val;
switch (short_option)
{
case 'f':
error = Args::StringToFormat (option_arg, m_format, &m_byte_size);
break;
case 's':
m_byte_size = Args::StringToUInt32 (option_arg, 0);
if (m_byte_size == 0)
error.SetErrorStringWithFormat("Invalid value for --size option '%s'. Must be positive integer value.\n", option_arg);
break;
case 'i':
m_infile.SetFile (option_arg, true);
if (!m_infile.Exists())
{
m_infile.Clear();
error.SetErrorStringWithFormat("Input file does not exist: '%s'\n", option_arg);
}
break;
case 'o':
{
bool success;
m_infile_offset = Args::StringToUInt64(option_arg, 0, 0, &success);
if (!success)
{
error.SetErrorStringWithFormat("Invalid offset string '%s'\n", option_arg);
}
}
break;
default:
error.SetErrorStringWithFormat("Unrecognized short option '%c'\n", short_option);
break;
}
return error;
}
void
Added two new classes for command options: lldb_private::OptionGroup lldb_private::OptionGroupOptions OptionGroup lets you define a class that encapsulates settings that you want to reuse in multiple commands. It contains only the option definitions and the ability to set the option values, but it doesn't directly interface with the lldb_private::Options class that is the front end to all of the CommandObject option parsing. For that the OptionGroupOptions class can be used. It aggregates one or more OptionGroup objects and directs the option setting to the appropriate OptionGroup class. For an example of this, take a look at the CommandObjectFile and how it uses its "m_option_group" object shown below to be able to set values in both the FileOptionGroup and PlatformOptionGroup classes. The members used in CommandObjectFile are: OptionGroupOptions m_option_group; FileOptionGroup m_file_options; PlatformOptionGroup m_platform_options; Then in the constructor for CommandObjectFile you can combine the option settings. The code below shows a simplified version of the constructor: CommandObjectFile::CommandObjectFile(CommandInterpreter &interpreter) : CommandObject (...), m_option_group (interpreter), m_file_options (), m_platform_options(true) { m_option_group.Append (&m_file_options); m_option_group.Append (&m_platform_options); m_option_group.Finalize(); } We append the m_file_options and then the m_platform_options and then tell the option group the finalize the results. This allows the m_option_group to become the organizer of our prefs and after option parsing we end up with valid preference settings in both the m_file_options and m_platform_options objects. This also allows any other commands to use the FileOptionGroup and PlatformOptionGroup classes to implement options for their commands. Renamed: virtual void Options::ResetOptionValues(); to: virtual void Options::OptionParsingStarting(); And implemented a new callback named: virtual Error Options::OptionParsingFinished(); This allows Options subclasses to verify that the options all go together after all of the options have been specified and gives the chance for the command object to return an error. It also gives a chance to take all of the option values and produce or initialize objects after all options have completed parsing. Modfied: virtual Error SetOptionValue (int option_idx, const char *option_arg) = 0; to be: virtual Error SetOptionValue (uint32_t option_idx, const char *option_arg) = 0; (option_idx is now unsigned). llvm-svn: 129415
2011-04-13 08:18:08 +08:00
OptionParsingStarting ()
{
m_format = eFormatBytes;
m_byte_size = 1;
m_infile.Clear();
m_infile_offset = 0;
}
const OptionDefinition*
GetDefinitions ()
{
return g_option_table;
}
// Options table: Required for subclasses of Options.
static OptionDefinition g_option_table[];
// Instance variables to hold the values for command options.
lldb::Format m_format;
uint32_t m_byte_size;
FileSpec m_infile;
off_t m_infile_offset;
};
CommandObjectMemoryWrite (CommandInterpreter &interpreter) :
CommandObject (interpreter,
"memory write",
"Write to the memory of the process being debugged.",
//"memory write [<cmd-options>] <addr> [value1 value2 ...]",
NULL,
eFlagProcessMustBeLaunched),
m_options (interpreter)
{
CommandArgumentEntry arg1;
CommandArgumentEntry arg2;
CommandArgumentData addr_arg;
CommandArgumentData value_arg;
// Define the first (and only) variant of this arg.
addr_arg.arg_type = eArgTypeAddress;
addr_arg.arg_repetition = eArgRepeatPlain;
// There is only one variant this argument could be; put it into the argument entry.
arg1.push_back (addr_arg);
// Define the first (and only) variant of this arg.
value_arg.arg_type = eArgTypeValue;
value_arg.arg_repetition = eArgRepeatPlus;
// There is only one variant this argument could be; put it into the argument entry.
arg2.push_back (value_arg);
// Push the data for the first argument into the m_arguments vector.
m_arguments.push_back (arg1);
m_arguments.push_back (arg2);
}
virtual
~CommandObjectMemoryWrite ()
{
}
Options *
GetOptions ()
{
return &m_options;
}
bool
UIntValueIsValidForSize (uint64_t uval64, size_t total_byte_size)
{
if (total_byte_size > 8)
return false;
if (total_byte_size == 8)
return true;
const uint64_t max = ((uint64_t)1 << (uint64_t)(total_byte_size * 8)) - 1;
return uval64 <= max;
}
bool
SIntValueIsValidForSize (int64_t sval64, size_t total_byte_size)
{
if (total_byte_size > 8)
return false;
if (total_byte_size == 8)
return true;
const int64_t max = ((int64_t)1 << (uint64_t)(total_byte_size * 8 - 1)) - 1;
const int64_t min = ~(max);
return min <= sval64 && sval64 <= max;
}
virtual bool
Execute (Args& command,
CommandReturnObject &result)
{
Moved the execution context that was in the Debugger into the CommandInterpreter where it was always being used. Make sure that Modules can track their object file offsets correctly to allow opening of sub object files (like the "__commpage" on darwin). Modified the Platforms to be able to launch processes. The first part of this move is the platform soon will become the entity that launches your program and when it does, it uses a new ProcessLaunchInfo class which encapsulates all process launching settings. This simplifies the internal APIs needed for launching. I want to slowly phase out process launching from the process classes, so for now we can still launch just as we used to, but eventually the platform is the object that should do the launching. Modified the Host::LaunchProcess in the MacOSX Host.mm to correctly be able to launch processes with all of the new eLaunchFlag settings. Modified any code that was manually launching processes to use the Host::LaunchProcess functions. Fixed an issue where lldb_private::Args had implicitly defined copy constructors that could do the wrong thing. This has now been fixed by adding an appropriate copy constructor and assignment operator. Make sure we don't add empty ModuleSP entries to a module list. Fixed the commpage module creation on MacOSX, but we still need to train the MacOSX dynamic loader to not get rid of it when it doesn't have an entry in the all image infos. Abstracted many more calls from in ProcessGDBRemote down into the GDBRemoteCommunicationClient subclass to make the classes cleaner and more efficient. Fixed the default iOS ARM register context to be correct and also added support for targets that don't support the qThreadStopInfo packet by selecting the current thread (only if needed) and then sending a stop reply packet. Debugserver can now start up with a --unix-socket (-u for short) and can then bind to port zero and send the port it bound to to a listening process on the other end. This allows the GDB remote platform to spawn new GDB server instances (debugserver) to allow platform debugging. llvm-svn: 129351
2011-04-12 13:54:46 +08:00
Process *process = m_interpreter.GetExecutionContext().process;
if (process == NULL)
{
result.AppendError("need a process to read memory");
result.SetStatus(eReturnStatusFailed);
return false;
}
const size_t argc = command.GetArgumentCount();
if (m_options.m_infile)
{
if (argc < 1)
{
result.AppendErrorWithFormat ("%s takes a destination address when writing file contents.\n", m_cmd_name.c_str());
result.SetStatus(eReturnStatusFailed);
return false;
}
}
else if (argc < 2)
{
result.AppendErrorWithFormat ("%s takes a destination address and at least one value.\n", m_cmd_name.c_str());
result.SetStatus(eReturnStatusFailed);
return false;
}
StreamString buffer (Stream::eBinary,
process->GetTarget().GetArchitecture().GetAddressByteSize(),
process->GetTarget().GetArchitecture().GetByteOrder());
size_t item_byte_size = m_options.m_byte_size;
lldb::addr_t addr = Args::StringToUInt64(command.GetArgumentAtIndex(0), LLDB_INVALID_ADDRESS, 0);
if (addr == LLDB_INVALID_ADDRESS)
{
result.AppendErrorWithFormat("Invalid address string '%s'.\n", command.GetArgumentAtIndex(0));
result.SetStatus(eReturnStatusFailed);
return false;
}
if (m_options.m_infile)
{
size_t length = SIZE_MAX;
if (m_options.m_byte_size > 0)
length = m_options.m_byte_size;
lldb::DataBufferSP data_sp (m_options.m_infile.ReadFileContents (m_options.m_infile_offset, length));
if (data_sp)
{
length = data_sp->GetByteSize();
if (length > 0)
{
Error error;
size_t bytes_written = process->WriteMemory (addr, data_sp->GetBytes(), length, error);
if (bytes_written == length)
{
// All bytes written
result.GetOutputStream().Printf("%zu bytes were written to 0x%llx\n", bytes_written, addr);
result.SetStatus(eReturnStatusSuccessFinishResult);
}
else if (bytes_written > 0)
{
// Some byte written
result.GetOutputStream().Printf("%zu bytes of %zu requested were written to 0x%llx\n", bytes_written, length, addr);
result.SetStatus(eReturnStatusSuccessFinishResult);
}
else
{
result.AppendErrorWithFormat ("Memory write to 0x%llx failed: %s.\n", addr, error.AsCString());
result.SetStatus(eReturnStatusFailed);
}
}
}
else
{
result.AppendErrorWithFormat ("Unable to read contents of file.\n");
result.SetStatus(eReturnStatusFailed);
}
return result.Succeeded();
}
else if (m_options.m_byte_size == 0)
{
if (m_options.m_format == eFormatPointer)
item_byte_size = buffer.GetAddressByteSize();
else
item_byte_size = 1;
}
command.Shift(); // shift off the address argument
uint64_t uval64;
int64_t sval64;
bool success = false;
const uint32_t num_value_args = command.GetArgumentCount();
uint32_t i;
for (i=0; i<num_value_args; ++i)
{
const char *value_str = command.GetArgumentAtIndex(i);
switch (m_options.m_format)
{
case eFormatFloat: // TODO: add support for floats soon
case eFormatCharPrintable:
case eFormatBytesWithASCII:
case eFormatComplex:
case eFormatEnum:
case eFormatUnicode16:
case eFormatUnicode32:
case eFormatVectorOfChar:
case eFormatVectorOfSInt8:
case eFormatVectorOfUInt8:
case eFormatVectorOfSInt16:
case eFormatVectorOfUInt16:
case eFormatVectorOfSInt32:
case eFormatVectorOfUInt32:
case eFormatVectorOfSInt64:
case eFormatVectorOfUInt64:
case eFormatVectorOfFloat32:
case eFormatVectorOfFloat64:
case eFormatVectorOfUInt128:
case eFormatOSType:
case eFormatComplexInteger:
result.AppendError("unsupported format for writing memory");
result.SetStatus(eReturnStatusFailed);
return false;
case eFormatDefault:
case eFormatBytes:
case eFormatHex:
case eFormatPointer:
// Decode hex bytes
uval64 = Args::StringToUInt64(value_str, UINT64_MAX, 16, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid hex string value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (!UIntValueIsValidForSize (uval64, item_byte_size))
{
result.AppendErrorWithFormat ("Value 0x%llx is too large to fit in a %u byte unsigned integer value.\n", uval64, item_byte_size);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (uval64, item_byte_size);
break;
case eFormatBoolean:
uval64 = Args::StringToBoolean(value_str, false, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid boolean string value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (uval64, item_byte_size);
break;
case eFormatBinary:
uval64 = Args::StringToUInt64(value_str, UINT64_MAX, 2, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid binary string value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (!UIntValueIsValidForSize (uval64, item_byte_size))
{
result.AppendErrorWithFormat ("Value 0x%llx is too large to fit in a %u byte unsigned integer value.\n", uval64, item_byte_size);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (uval64, item_byte_size);
break;
case eFormatChar:
case eFormatCString:
if (value_str[0])
{
size_t len = strlen (value_str);
// Include the NULL for C strings...
if (m_options.m_format == eFormatCString)
++len;
Error error;
if (process->WriteMemory (addr, value_str, len, error) == len)
{
addr += len;
}
else
{
result.AppendErrorWithFormat ("Memory write to 0x%llx failed: %s.\n", addr, error.AsCString());
result.SetStatus(eReturnStatusFailed);
return false;
}
}
break;
case eFormatDecimal:
sval64 = Args::StringToSInt64(value_str, INT64_MAX, 0, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid signed decimal value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (!SIntValueIsValidForSize (sval64, item_byte_size))
{
result.AppendErrorWithFormat ("Value %lli is too large or small to fit in a %u byte signed integer value.\n", sval64, item_byte_size);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (sval64, item_byte_size);
break;
case eFormatUnsigned:
uval64 = Args::StringToUInt64(value_str, UINT64_MAX, 0, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid unsigned decimal string value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (!UIntValueIsValidForSize (uval64, item_byte_size))
{
result.AppendErrorWithFormat ("Value %llu is too large to fit in a %u byte unsigned integer value.\n", uval64, item_byte_size);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (uval64, item_byte_size);
break;
case eFormatOctal:
uval64 = Args::StringToUInt64(value_str, UINT64_MAX, 8, &success);
if (!success)
{
result.AppendErrorWithFormat ("'%s' is not a valid octal string value.\n", value_str);
result.SetStatus(eReturnStatusFailed);
return false;
}
else if (!UIntValueIsValidForSize (uval64, item_byte_size))
{
result.AppendErrorWithFormat ("Value %llo is too large to fit in a %u byte unsigned integer value.\n", uval64, item_byte_size);
result.SetStatus(eReturnStatusFailed);
return false;
}
buffer.PutMaxHex64 (uval64, item_byte_size);
break;
}
}
if (!buffer.GetString().empty())
{
Error error;
if (process->WriteMemory (addr, buffer.GetString().c_str(), buffer.GetString().size(), error) == buffer.GetString().size())
return true;
else
{
result.AppendErrorWithFormat ("Memory write to 0x%llx failed: %s.\n", addr, error.AsCString());
result.SetStatus(eReturnStatusFailed);
return false;
}
}
return true;
}
protected:
CommandOptions m_options;
};
#define SET1 LLDB_OPT_SET_1
#define SET2 LLDB_OPT_SET_2
OptionDefinition
CommandObjectMemoryWrite::CommandOptions::g_option_table[] =
{
{ SET1 , false, "format", 'f', required_argument, NULL, 0, eArgTypeFormat, "The format value types that will be decoded and written to memory."},
{ SET1 | SET2, false, "size", 's', required_argument, NULL, 0, eArgTypeByteSize, "The size in bytes of the values to write to memory."},
{ SET2, true, "infile", 'i', required_argument, NULL, 0, eArgTypeFilename, "Write memory using the contents of a file."},
{ SET2, false, "offset", 'o', required_argument, NULL, 0, eArgTypeOffset, "Start writng bytes from an offset within the input file."},
{ 0 , false, NULL , 0 , 0 , NULL, 0, eArgTypeNone, NULL }
};
#undef SET1
#undef SET2
//-------------------------------------------------------------------------
// CommandObjectMemory
//-------------------------------------------------------------------------
CommandObjectMemory::CommandObjectMemory (CommandInterpreter &interpreter) :
CommandObjectMultiword (interpreter,
"memory",
"A set of commands for operating on memory.",
"memory <subcommand> [<subcommand-options>]")
{
LoadSubCommand ("read", CommandObjectSP (new CommandObjectMemoryRead (interpreter)));
LoadSubCommand ("write", CommandObjectSP (new CommandObjectMemoryWrite (interpreter)));
}
CommandObjectMemory::~CommandObjectMemory ()
{
}