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//===-- CommandObjectMemory.cpp -------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "CommandObjectMemory.h"
#include "CommandObjectMemoryTag.h"
#include "lldb/Core/DumpDataExtractor.h"
#include "lldb/Core/Section.h"
#include "lldb/Core/ValueObjectMemory.h"
#include "lldb/Expression/ExpressionVariable.h"
#include "lldb/Host/OptionParser.h"
#include "lldb/Interpreter/CommandReturnObject.h"
#include "lldb/Interpreter/OptionArgParser.h"
#include "lldb/Interpreter/OptionGroupFormat.h"
#include "lldb/Interpreter/OptionGroupOutputFile.h"
#include "lldb/Interpreter/OptionGroupValueObjectDisplay.h"
#include "lldb/Interpreter/OptionValueLanguage.h"
#include "lldb/Interpreter/OptionValueString.h"
#include "lldb/Interpreter/Options.h"
#include "lldb/Symbol/SymbolFile.h"
#include "lldb/Symbol/TypeList.h"
#include "lldb/Target/Language.h"
#include "lldb/Target/MemoryHistory.h"
#include "lldb/Target/MemoryRegionInfo.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/StackFrame.h"
#include "lldb/Target/Target.h"
#include "lldb/Target/Thread.h"
#include "lldb/Utility/Args.h"
#include "lldb/Utility/DataBufferHeap.h"
#include "lldb/Utility/DataBufferLLVM.h"
#include "lldb/Utility/StreamString.h"
#include "llvm/Support/MathExtras.h"
#include <cinttypes>
#include <memory>
using namespace lldb;
using namespace lldb_private;
#define LLDB_OPTIONS_memory_read
#include "CommandOptions.inc"
class OptionGroupReadMemory : public OptionGroup {
public:
OptionGroupReadMemory()
: m_num_per_line(1, 1), m_view_as_type(), m_offset(0, 0),
m_language_for_type(eLanguageTypeUnknown) {}
~OptionGroupReadMemory() override = default;
llvm::ArrayRef<OptionDefinition> GetDefinitions() override {
return llvm::makeArrayRef(g_memory_read_options);
}
Status SetOptionValue(uint32_t option_idx, llvm::StringRef option_value,
ExecutionContext *execution_context) override {
Status error;
const int short_option = g_memory_read_options[option_idx].short_option;
switch (short_option) {
case 'l':
error = m_num_per_line.SetValueFromString(option_value);
if (m_num_per_line.GetCurrentValue() == 0)
error.SetErrorStringWithFormat(
"invalid value for --num-per-line option '%s'",
option_value.str().c_str());
break;
case 'b':
m_output_as_binary = true;
break;
case 't':
error = m_view_as_type.SetValueFromString(option_value);
break;
case 'r':
m_force = true;
break;
case 'x':
error = m_language_for_type.SetValueFromString(option_value);
break;
case 'E':
error = m_offset.SetValueFromString(option_value);
break;
default:
llvm_unreachable("Unimplemented option");
}
return error;
}
void OptionParsingStarting(ExecutionContext *execution_context) override {
m_num_per_line.Clear();
m_output_as_binary = false;
m_view_as_type.Clear();
m_force = false;
m_offset.Clear();
m_language_for_type.Clear();
}
Status FinalizeSettings(Target *target, OptionGroupFormat &format_options) {
Status error;
OptionValueUInt64 &byte_size_value = format_options.GetByteSizeValue();
OptionValueUInt64 &count_value = format_options.GetCountValue();
const bool byte_size_option_set = byte_size_value.OptionWasSet();
const bool num_per_line_option_set = m_num_per_line.OptionWasSet();
const bool count_option_set = format_options.GetCountValue().OptionWasSet();
switch (format_options.GetFormat()) {
default:
break;
case eFormatBoolean:
if (!byte_size_option_set)
byte_size_value = 1;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatCString:
break;
case eFormatInstruction:
if (count_option_set)
byte_size_value = target->GetArchitecture().GetMaximumOpcodeByteSize();
m_num_per_line = 1;
break;
case eFormatAddressInfo:
if (!byte_size_option_set)
byte_size_value = target->GetArchitecture().GetAddressByteSize();
m_num_per_line = 1;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatPointer:
byte_size_value = target->GetArchitecture().GetAddressByteSize();
if (!num_per_line_option_set)
m_num_per_line = 4;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatBinary:
case eFormatFloat:
case eFormatOctal:
case eFormatDecimal:
case eFormatEnum:
case eFormatUnicode8:
case eFormatUnicode16:
case eFormatUnicode32:
case eFormatUnsigned:
case eFormatHexFloat:
if (!byte_size_option_set)
byte_size_value = 4;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatBytes:
case eFormatBytesWithASCII:
if (byte_size_option_set) {
if (byte_size_value > 1)
error.SetErrorStringWithFormat(
"display format (bytes/bytes with ASCII) conflicts with the "
"specified byte size %" PRIu64 "\n"
"\tconsider using a different display format or don't specify "
"the byte size.",
byte_size_value.GetCurrentValue());
} else
byte_size_value = 1;
if (!num_per_line_option_set)
m_num_per_line = 16;
if (!count_option_set)
format_options.GetCountValue() = 32;
break;
case eFormatCharArray:
case eFormatChar:
case eFormatCharPrintable:
if (!byte_size_option_set)
byte_size_value = 1;
if (!num_per_line_option_set)
m_num_per_line = 32;
if (!count_option_set)
format_options.GetCountValue() = 64;
break;
case eFormatComplex:
if (!byte_size_option_set)
byte_size_value = 8;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatComplexInteger:
if (!byte_size_option_set)
byte_size_value = 8;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
format_options.GetCountValue() = 8;
break;
case eFormatHex:
if (!byte_size_option_set)
byte_size_value = 4;
if (!num_per_line_option_set) {
switch (byte_size_value) {
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)
count_value = 8;
break;
case eFormatVectorOfChar:
case eFormatVectorOfSInt8:
case eFormatVectorOfUInt8:
case eFormatVectorOfSInt16:
case eFormatVectorOfUInt16:
case eFormatVectorOfSInt32:
case eFormatVectorOfUInt32:
case eFormatVectorOfSInt64:
case eFormatVectorOfUInt64:
case eFormatVectorOfFloat16:
case eFormatVectorOfFloat32:
case eFormatVectorOfFloat64:
case eFormatVectorOfUInt128:
if (!byte_size_option_set)
byte_size_value = 128;
if (!num_per_line_option_set)
m_num_per_line = 1;
if (!count_option_set)
count_value = 4;
break;
}
return error;
}
bool AnyOptionWasSet() const {
return m_num_per_line.OptionWasSet() || m_output_as_binary ||
m_view_as_type.OptionWasSet() || m_offset.OptionWasSet() ||
m_language_for_type.OptionWasSet();
}
OptionValueUInt64 m_num_per_line;
bool m_output_as_binary = false;
OptionValueString m_view_as_type;
bool m_force;
OptionValueUInt64 m_offset;
OptionValueLanguage m_language_for_type;
};
// Read memory from the inferior process
class CommandObjectMemoryRead : public CommandObjectParsed {
public:
CommandObjectMemoryRead(CommandInterpreter &interpreter)
: CommandObjectParsed(
interpreter, "memory read",
"Read from the memory of the current target process.", nullptr,
eCommandRequiresTarget | eCommandProcessMustBePaused),
m_option_group(), m_format_options(eFormatBytesWithASCII, 1, 8),
m_memory_options(), m_outfile_options(), m_varobj_options(),
m_next_addr(LLDB_INVALID_ADDRESS), m_prev_byte_size(0),
m_prev_format_options(eFormatBytesWithASCII, 1, 8),
m_prev_memory_options(), m_prev_outfile_options(),
m_prev_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 = eArgTypeAddressOrExpression;
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 = eArgTypeAddressOrExpression;
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);
// Add the "--format" and "--count" options to group 1 and 3
m_option_group.Append(&m_format_options,
OptionGroupFormat::OPTION_GROUP_FORMAT |
OptionGroupFormat::OPTION_GROUP_COUNT,
LLDB_OPT_SET_1 | LLDB_OPT_SET_2 | LLDB_OPT_SET_3);
m_option_group.Append(&m_format_options,
OptionGroupFormat::OPTION_GROUP_GDB_FMT,
LLDB_OPT_SET_1 | LLDB_OPT_SET_3);
// Add the "--size" option to group 1 and 2
m_option_group.Append(&m_format_options,
OptionGroupFormat::OPTION_GROUP_SIZE,
LLDB_OPT_SET_1 | LLDB_OPT_SET_2);
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();
}
~CommandObjectMemoryRead() override = default;
Options *GetOptions() override { return &m_option_group; }
const char *GetRepeatCommand(Args &current_command_args,
uint32_t index) override {
return m_cmd_name.c_str();
}
protected:
bool DoExecute(Args &command, CommandReturnObject &result) override {
// No need to check "target" for validity as eCommandRequiresTarget ensures
// it is valid
Target *target = m_exe_ctx.GetTargetPtr();
const size_t argc = command.GetArgumentCount();
if ((argc == 0 && m_next_addr == LLDB_INVALID_ADDRESS) || argc > 2) {
result.AppendErrorWithFormat("%s takes a start address expression with "
"an optional end address expression.\n",
m_cmd_name.c_str());
result.AppendWarning("Expressions should be quoted if they contain "
"spaces or other special characters.");
return false;
}
CompilerType compiler_type;
Status error;
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
const bool exact_match = false;
TypeList type_list;
uint32_t reference_count = 0;
uint32_t pointer_count = 0;
size_t idx;
#define ALL_KEYWORDS \
KEYWORD("const") \
KEYWORD("volatile") \
KEYWORD("restrict") \
KEYWORD("struct") \
KEYWORD("class") \
KEYWORD("union")
#define KEYWORD(s) s,
static const char *g_keywords[] = {ALL_KEYWORDS};
#undef KEYWORD
#define KEYWORD(s) (sizeof(s) - 1),
static const int g_keyword_lengths[] = {ALL_KEYWORDS};
#undef KEYWORD
#undef ALL_KEYWORDS
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 = g_keyword_lengths[i];
idx = 0;
while ((idx = type_str.find(keyword, idx)) != std::string::npos) {
if (type_str[idx + keyword_len] == ' ' ||
type_str[idx + keyword_len] == '\t') {
type_str.erase(idx, keyword_len + 1);
idx = 0;
} else {
idx += keyword_len;
}
}
}
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;
LLVM_FALLTHROUGH;
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);
return false;
}
break;
default:
done = true;
break;
}
}
}
llvm::DenseSet<lldb_private::SymbolFile *> searched_symbol_files;
ConstString lookup_type_name(type_str.c_str());
StackFrame *frame = m_exe_ctx.GetFramePtr();
ModuleSP search_first;
if (frame) {
search_first = frame->GetSymbolContext(eSymbolContextModule).module_sp;
}
target->GetImages().FindTypes(search_first.get(), lookup_type_name,
exact_match, 1, searched_symbol_files,
type_list);
if (type_list.GetSize() == 0 && lookup_type_name.GetCString()) {
LanguageType language_for_type =
m_memory_options.m_language_for_type.GetCurrentValue();
std::set<LanguageType> languages_to_check;
if (language_for_type != eLanguageTypeUnknown) {
languages_to_check.insert(language_for_type);
} else {
languages_to_check = Language::GetSupportedLanguages();
}
std::set<CompilerType> user_defined_types;
for (auto lang : languages_to_check) {
if (auto *persistent_vars =
target->GetPersistentExpressionStateForLanguage(lang)) {
if (llvm::Optional<CompilerType> type =
persistent_vars->GetCompilerTypeFromPersistentDecl(
lookup_type_name)) {
user_defined_types.emplace(*type);
}
}
}
if (user_defined_types.size() > 1) {
result.AppendErrorWithFormat(
"Mutiple types found matching raw type '%s', please disambiguate "
"by specifying the language with -x",
lookup_type_name.GetCString());
return false;
}
if (user_defined_types.size() == 1) {
compiler_type = *user_defined_types.begin();
}
}
if (!compiler_type.IsValid()) {
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);
return false;
} else {
TypeSP type_sp(type_list.GetTypeAtIndex(0));
compiler_type = type_sp->GetFullCompilerType();
}
}
while (pointer_count > 0) {
CompilerType pointer_type = compiler_type.GetPointerType();
if (pointer_type.IsValid())
compiler_type = pointer_type;
else {
result.AppendError("unable make a pointer type\n");
return false;
}
--pointer_count;
}
llvm::Optional<uint64_t> size = compiler_type.GetByteSize(nullptr);
if (!size) {
result.AppendErrorWithFormat(
"unable to get the byte size of the type '%s'\n",
view_as_type_cstr);
return false;
}
m_format_options.GetByteSizeValue() = *size;
if (!m_format_options.GetCountValue().OptionWasSet())
m_format_options.GetCountValue() = 1;
} else {
error = m_memory_options.FinalizeSettings(target, m_format_options);
}
// Look for invalid combinations of settings
if (error.Fail()) {
result.AppendError(error.AsCString());
return false;
}
lldb::addr_t addr;
size_t total_byte_size = 0;
if (argc == 0) {
// Use the last address and byte size and all options as they were if no
// options have been set
addr = m_next_addr;
total_byte_size = m_prev_byte_size;
compiler_type = m_prev_compiler_type;
if (!m_format_options.AnyOptionWasSet() &&
!m_memory_options.AnyOptionWasSet() &&
!m_outfile_options.AnyOptionWasSet() &&
!m_varobj_options.AnyOptionWasSet()) {
m_format_options = m_prev_format_options;
m_memory_options = m_prev_memory_options;
m_outfile_options = m_prev_outfile_options;
m_varobj_options = m_prev_varobj_options;
}
}
size_t item_count = m_format_options.GetCountValue().GetCurrentValue();
// TODO For non-8-bit byte addressable architectures this needs to be
// revisited to fully support all lldb's range of formatting options.
// Furthermore code memory reads (for those architectures) will not be
// correctly formatted even w/o formatting options.
size_t item_byte_size =
target->GetArchitecture().GetDataByteSize() > 1
? target->GetArchitecture().GetDataByteSize()
: m_format_options.GetByteSizeValue().GetCurrentValue();
const size_t num_per_line =
m_memory_options.m_num_per_line.GetCurrentValue();
if (total_byte_size == 0) {
total_byte_size = item_count * item_byte_size;
if (total_byte_size == 0)
total_byte_size = 32;
}
if (argc > 0)
addr = OptionArgParser::ToAddress(&m_exe_ctx, command[0].ref(),
LLDB_INVALID_ADDRESS, &error);
if (addr == LLDB_INVALID_ADDRESS) {
result.AppendError("invalid start address expression.");
result.AppendError(error.AsCString());
return false;
}
if (argc == 2) {
lldb::addr_t end_addr = OptionArgParser::ToAddress(
&m_exe_ctx, command[1].ref(), LLDB_INVALID_ADDRESS, nullptr);
if (end_addr == LLDB_INVALID_ADDRESS) {
result.AppendError("invalid end address expression.");
result.AppendError(error.AsCString());
return false;
} else if (end_addr <= addr) {
result.AppendErrorWithFormat(
"end address (0x%" PRIx64
") must be greater than the start address (0x%" PRIx64 ").\n",
end_addr, addr);
return false;
} else if (m_format_options.GetCountValue().OptionWasSet()) {
result.AppendErrorWithFormat(
"specify either the end address (0x%" PRIx64
") or the count (--count %" PRIu64 "), not both.\n",
end_addr, (uint64_t)item_count);
return false;
}
total_byte_size = end_addr - addr;
item_count = total_byte_size / item_byte_size;
}
uint32_t max_unforced_size = target->GetMaximumMemReadSize();
if (total_byte_size > max_unforced_size && !m_memory_options.m_force) {
result.AppendErrorWithFormat(
"Normally, \'memory read\' will not read over %" PRIu32
" bytes of data.\n",
max_unforced_size);
result.AppendErrorWithFormat(
"Please use --force to override this restriction just once.\n");
result.AppendErrorWithFormat("or set target.max-memory-read-size if you "
"will often need a larger limit.\n");
return false;
}
DataBufferSP data_sp;
size_t bytes_read = 0;
if (compiler_type.GetOpaqueQualType()) {
// Make sure we don't display our type as ASCII bytes like the default
// memory read
if (!m_format_options.GetFormatValue().OptionWasSet())
m_format_options.GetFormatValue().SetCurrentValue(eFormatDefault);
llvm::Optional<uint64_t> size = compiler_type.GetByteSize(nullptr);
if (!size) {
result.AppendError("can't get size of type");
return false;
}
bytes_read = *size * m_format_options.GetCountValue().GetCurrentValue();
if (argc > 0)
addr = addr + (*size * m_memory_options.m_offset.GetCurrentValue());
} else if (m_format_options.GetFormatValue().GetCurrentValue() !=
eFormatCString) {
data_sp = std::make_shared<DataBufferHeap>(total_byte_size, '\0');
if (data_sp->GetBytes() == nullptr) {
result.AppendErrorWithFormat(
"can't allocate 0x%" PRIx32
" bytes for the memory read buffer, specify a smaller size to read",
(uint32_t)total_byte_size);
return false;
}
Address address(addr, nullptr);
bytes_read = target->ReadMemory(address, data_sp->GetBytes(),
data_sp->GetByteSize(), error, true);
if (bytes_read == 0) {
const char *error_cstr = error.AsCString();
if (error_cstr && error_cstr[0]) {
result.AppendError(error_cstr);
} else {
result.AppendErrorWithFormat(
"failed to read memory from 0x%" PRIx64 ".\n", addr);
}
return false;
}
if (bytes_read < total_byte_size)
result.AppendWarningWithFormat(
"Not all bytes (%" PRIu64 "/%" PRIu64
") were able to be read from 0x%" PRIx64 ".\n",
(uint64_t)bytes_read, (uint64_t)total_byte_size, addr);
} else {
// we treat c-strings as a special case because they do not have a fixed
// size
if (m_format_options.GetByteSizeValue().OptionWasSet() &&
!m_format_options.HasGDBFormat())
item_byte_size = m_format_options.GetByteSizeValue().GetCurrentValue();
else
item_byte_size = target->GetMaximumSizeOfStringSummary();
if (!m_format_options.GetCountValue().OptionWasSet())
item_count = 1;
data_sp = std::make_shared<DataBufferHeap>(
(item_byte_size + 1) * item_count,
'\0'); // account for NULLs as necessary
if (data_sp->GetBytes() == nullptr) {
result.AppendErrorWithFormat(
"can't allocate 0x%" PRIx64
" bytes for the memory read buffer, specify a smaller size to read",
(uint64_t)((item_byte_size + 1) * item_count));
return false;
}
uint8_t *data_ptr = data_sp->GetBytes();
auto data_addr = addr;
auto count = item_count;
item_count = 0;
bool break_on_no_NULL = false;
while (item_count < count) {
std::string buffer;
buffer.resize(item_byte_size + 1, 0);
Status error;
size_t read = target->ReadCStringFromMemory(data_addr, &buffer[0],
item_byte_size + 1, error);
if (error.Fail()) {
result.AppendErrorWithFormat(
"failed to read memory from 0x%" PRIx64 ".\n", addr);
return false;
}
if (item_byte_size == read) {
result.AppendWarningWithFormat(
"unable to find a NULL terminated string at 0x%" PRIx64
".Consider increasing the maximum read length.\n",
data_addr);
--read;
break_on_no_NULL = true;
} else
++read; // account for final NULL byte
memcpy(data_ptr, &buffer[0], read);
data_ptr += read;
data_addr += read;
bytes_read += read;
item_count++; // if we break early we know we only read item_count
// strings
if (break_on_no_NULL)
break;
}
data_sp =
std::make_shared<DataBufferHeap>(data_sp->GetBytes(), bytes_read + 1);
}
m_next_addr = addr + bytes_read;
m_prev_byte_size = bytes_read;
m_prev_format_options = m_format_options;
m_prev_memory_options = m_memory_options;
m_prev_outfile_options = m_outfile_options;
m_prev_varobj_options = m_varobj_options;
m_prev_compiler_type = compiler_type;
std::unique_ptr<Stream> output_stream_storage;
Stream *output_stream_p = nullptr;
const FileSpec &outfile_spec =
m_outfile_options.GetFile().GetCurrentValue();
std::string path = outfile_spec.GetPath();
if (outfile_spec) {
File::OpenOptions open_options =
File::eOpenOptionWriteOnly | File::eOpenOptionCanCreate;
const bool append = m_outfile_options.GetAppend().GetCurrentValue();
open_options |=
append ? File::eOpenOptionAppend : File::eOpenOptionTruncate;
auto outfile = FileSystem::Instance().Open(outfile_spec, open_options);
if (outfile) {
auto outfile_stream_up =
std::make_unique<StreamFile>(std::move(outfile.get()));
if (m_memory_options.m_output_as_binary) {
const size_t bytes_written =
outfile_stream_up->Write(data_sp->GetBytes(), bytes_read);
if (bytes_written > 0) {
result.GetOutputStream().Printf(
"%zi bytes %s to '%s'\n", bytes_written,
append ? "appended" : "written", path.c_str());
return true;
} else {
result.AppendErrorWithFormat("Failed to write %" PRIu64
" bytes to '%s'.\n",
(uint64_t)bytes_read, path.c_str());
return false;
}
} else {
// We are going to write ASCII to the file just point the
// output_stream to our outfile_stream...
output_stream_storage = std::move(outfile_stream_up);
output_stream_p = output_stream_storage.get();
}
} else {
result.AppendErrorWithFormat("Failed to open file '%s' for %s:\n",
path.c_str(), append ? "append" : "write");
result.AppendError(llvm::toString(outfile.takeError()));
return false;
}
} else {
output_stream_p = &result.GetOutputStream();
}
ExecutionContextScope *exe_scope = m_exe_ctx.GetBestExecutionContextScope();
if (compiler_type.GetOpaqueQualType()) {
for (uint32_t i = 0; i < item_count; ++i) {
addr_t item_addr = addr + (i * item_byte_size);
Address address(item_addr);
StreamString name_strm;
name_strm.Printf("0x%" PRIx64, item_addr);
ValueObjectSP valobj_sp(ValueObjectMemory::Create(
exe_scope, name_strm.GetString(), address, compiler_type));
if (valobj_sp) {
Format format = m_format_options.GetFormat();
if (format != eFormatDefault)
valobj_sp->SetFormat(format);
DumpValueObjectOptions options(m_varobj_options.GetAsDumpOptions(
eLanguageRuntimeDescriptionDisplayVerbosityFull, format));
valobj_sp->Dump(*output_stream_p, options);
} else {
result.AppendErrorWithFormat(
"failed to create a value object for: (%s) %s\n",
view_as_type_cstr, name_strm.GetData());
return false;
}
}
return true;
}
result.SetStatus(eReturnStatusSuccessFinishResult);
DataExtractor data(data_sp, target->GetArchitecture().GetByteOrder(),
target->GetArchitecture().GetAddressByteSize(),
target->GetArchitecture().GetDataByteSize());
Format format = m_format_options.GetFormat();
if (((format == eFormatChar) || (format == eFormatCharPrintable)) &&
(item_byte_size != 1)) {
// if a count was not passed, or it is 1
if (!m_format_options.GetCountValue().OptionWasSet() || item_count == 1) {
// this turns requests such as
// memory read -fc -s10 -c1 *charPtrPtr
// which make no sense (what is a char of size 10?) into a request for
// fetching 10 chars of size 1 from the same memory location
format = eFormatCharArray;
item_count = item_byte_size;
item_byte_size = 1;
} else {
// here we passed a count, and it was not 1 so we have a byte_size and
// a count we could well multiply those, but instead let's just fail
result.AppendErrorWithFormat(
"reading memory as characters of size %" PRIu64 " is not supported",
(uint64_t)item_byte_size);
return false;
}
}
assert(output_stream_p);
size_t bytes_dumped = DumpDataExtractor(
data, output_stream_p, 0, format, item_byte_size, item_count,
num_per_line / target->GetArchitecture().GetDataByteSize(), addr, 0, 0,
exe_scope);
m_next_addr = addr + bytes_dumped;
output_stream_p->EOL();
return true;
}
OptionGroupOptions m_option_group;
OptionGroupFormat m_format_options;
OptionGroupReadMemory m_memory_options;
OptionGroupOutputFile m_outfile_options;
OptionGroupValueObjectDisplay m_varobj_options;
lldb::addr_t m_next_addr;
lldb::addr_t m_prev_byte_size;
OptionGroupFormat m_prev_format_options;
OptionGroupReadMemory m_prev_memory_options;
OptionGroupOutputFile m_prev_outfile_options;
OptionGroupValueObjectDisplay m_prev_varobj_options;
CompilerType m_prev_compiler_type;
};
#define LLDB_OPTIONS_memory_find
#include "CommandOptions.inc"
// Find the specified data in memory
class CommandObjectMemoryFind : public CommandObjectParsed {
public:
class OptionGroupFindMemory : public OptionGroup {
public:
OptionGroupFindMemory() : OptionGroup(), m_count(1), m_offset(0) {}
~OptionGroupFindMemory() override = default;
llvm::ArrayRef<OptionDefinition> GetDefinitions() override {
return llvm::makeArrayRef(g_memory_find_options);
}
Status SetOptionValue(uint32_t option_idx, llvm::StringRef option_value,
ExecutionContext *execution_context) override {
Status error;
const int short_option = g_memory_find_options[option_idx].short_option;
switch (short_option) {
case 'e':
m_expr.SetValueFromString(option_value);
break;
case 's':
m_string.SetValueFromString(option_value);
break;
case 'c':
if (m_count.SetValueFromString(option_value).Fail())
error.SetErrorString("unrecognized value for count");
break;
case 'o':
if (m_offset.SetValueFromString(option_value).Fail())
error.SetErrorString("unrecognized value for dump-offset");
break;
default:
llvm_unreachable("Unimplemented option");
}
return error;
}
void OptionParsingStarting(ExecutionContext *execution_context) override {
m_expr.Clear();
m_string.Clear();
m_count.Clear();
}
OptionValueString m_expr;
OptionValueString m_string;
OptionValueUInt64 m_count;
OptionValueUInt64 m_offset;
};
CommandObjectMemoryFind(CommandInterpreter &interpreter)
: CommandObjectParsed(
interpreter, "memory find",
"Find a value in the memory of the current target process.",
nullptr, eCommandRequiresProcess | eCommandProcessMustBeLaunched),
m_option_group(), m_memory_options() {
CommandArgumentEntry arg1;
CommandArgumentEntry arg2;
CommandArgumentData addr_arg;
CommandArgumentData value_arg;
// Define the first (and only) variant of this arg.
addr_arg.arg_type = eArgTypeAddressOrExpression;
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 = eArgTypeAddressOrExpression;
value_arg.arg_repetition = eArgRepeatPlain;
// 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);
m_option_group.Append(&m_memory_options);
m_option_group.Finalize();
}
~CommandObjectMemoryFind() override = default;
Options *GetOptions() override { return &m_option_group; }
protected:
class ProcessMemoryIterator {
public:
ProcessMemoryIterator(ProcessSP process_sp, lldb::addr_t base)
: m_process_sp(process_sp), m_base_addr(base), m_is_valid(true) {
lldbassert(process_sp.get() != nullptr);
}
bool IsValid() { return m_is_valid; }
uint8_t operator[](lldb::addr_t offset) {
if (!IsValid())
return 0;
uint8_t retval = 0;
Status error;
if (0 ==
m_process_sp->ReadMemory(m_base_addr + offset, &retval, 1, error)) {
m_is_valid = false;
return 0;
}
return retval;
}
private:
ProcessSP m_process_sp;
lldb::addr_t m_base_addr;
bool m_is_valid;
};
bool DoExecute(Args &command, CommandReturnObject &result) override {
// No need to check "process" for validity as eCommandRequiresProcess
// ensures it is valid
Process *process = m_exe_ctx.GetProcessPtr();
const size_t argc = command.GetArgumentCount();
if (argc != 2) {
result.AppendError("two addresses needed for memory find");
return false;
}
Status error;
lldb::addr_t low_addr = OptionArgParser::ToAddress(
&m_exe_ctx, command[0].ref(), LLDB_INVALID_ADDRESS, &error);
if (low_addr == LLDB_INVALID_ADDRESS || error.Fail()) {
result.AppendError("invalid low address");
return false;
}
lldb::addr_t high_addr = OptionArgParser::ToAddress(
&m_exe_ctx, command[1].ref(), LLDB_INVALID_ADDRESS, &error);
if (high_addr == LLDB_INVALID_ADDRESS || error.Fail()) {
result.AppendError("invalid high address");
return false;
}
if (high_addr <= low_addr) {
result.AppendError(
"starting address must be smaller than ending address");
return false;
}
lldb::addr_t found_location = LLDB_INVALID_ADDRESS;
DataBufferHeap buffer;
if (m_memory_options.m_string.OptionWasSet())
buffer.CopyData(m_memory_options.m_string.GetStringValue());
else if (m_memory_options.m_expr.OptionWasSet()) {
StackFrame *frame = m_exe_ctx.GetFramePtr();
ValueObjectSP result_sp;
if ((eExpressionCompleted ==
process->GetTarget().EvaluateExpression(
m_memory_options.m_expr.GetStringValue(), frame, result_sp)) &&
result_sp) {
uint64_t value = result_sp->GetValueAsUnsigned(0);
llvm::Optional<uint64_t> size =
result_sp->GetCompilerType().GetByteSize(nullptr);
if (!size)
return false;
switch (*size) {
case 1: {
uint8_t byte = (uint8_t)value;
buffer.CopyData(&byte, 1);
} break;
case 2: {
uint16_t word = (uint16_t)value;
buffer.CopyData(&word, 2);
} break;
case 4: {
uint32_t lword = (uint32_t)value;
buffer.CopyData(&lword, 4);
} break;
case 8: {
buffer.CopyData(&value, 8);
} break;
case 3:
case 5:
case 6:
case 7:
result.AppendError("unknown type. pass a string instead");
return false;
default:
result.AppendError(
"result size larger than 8 bytes. pass a string instead");
return false;
}
} else {
result.AppendError(
"expression evaluation failed. pass a string instead");
return false;
}
} else {
result.AppendError(
"please pass either a block of text, or an expression to evaluate.");
return false;
}
size_t count = m_memory_options.m_count.GetCurrentValue();
found_location = low_addr;
bool ever_found = false;
while (count) {
found_location = FastSearch(found_location, high_addr, buffer.GetBytes(),
buffer.GetByteSize());
if (found_location == LLDB_INVALID_ADDRESS) {
if (!ever_found) {
result.AppendMessage("data not found within the range.\n");
result.SetStatus(lldb::eReturnStatusSuccessFinishNoResult);
} else
result.AppendMessage("no more matches within the range.\n");
break;
}
result.AppendMessageWithFormat("data found at location: 0x%" PRIx64 "\n",
found_location);
DataBufferHeap dumpbuffer(32, 0);
process->ReadMemory(
found_location + m_memory_options.m_offset.GetCurrentValue(),
dumpbuffer.GetBytes(), dumpbuffer.GetByteSize(), error);
if (!error.Fail()) {
DataExtractor data(dumpbuffer.GetBytes(), dumpbuffer.GetByteSize(),
process->GetByteOrder(),
process->GetAddressByteSize());
DumpDataExtractor(
data, &result.GetOutputStream(), 0, lldb::eFormatBytesWithASCII, 1,
dumpbuffer.GetByteSize(), 16,
found_location + m_memory_options.m_offset.GetCurrentValue(), 0, 0);
result.GetOutputStream().EOL();
}
--count;
found_location++;
ever_found = true;
}
result.SetStatus(lldb::eReturnStatusSuccessFinishResult);
return true;
}
lldb::addr_t FastSearch(lldb::addr_t low, lldb::addr_t high, uint8_t *buffer,
size_t buffer_size) {
const size_t region_size = high - low;
if (region_size < buffer_size)
return LLDB_INVALID_ADDRESS;
std::vector<size_t> bad_char_heuristic(256, buffer_size);
ProcessSP process_sp = m_exe_ctx.GetProcessSP();
ProcessMemoryIterator iterator(process_sp, low);
for (size_t idx = 0; idx < buffer_size - 1; idx++) {
decltype(bad_char_heuristic)::size_type bcu_idx = buffer[idx];
bad_char_heuristic[bcu_idx] = buffer_size - idx - 1;
}
for (size_t s = 0; s <= (region_size - buffer_size);) {
int64_t j = buffer_size - 1;
while (j >= 0 && buffer[j] == iterator[s + j])
j--;
if (j < 0)
return low + s;
else
s += bad_char_heuristic[iterator[s + buffer_size - 1]];
}
return LLDB_INVALID_ADDRESS;
}
OptionGroupOptions m_option_group;
OptionGroupFindMemory m_memory_options;
};
#define LLDB_OPTIONS_memory_write
#include "CommandOptions.inc"
// Write memory to the inferior process
class CommandObjectMemoryWrite : public CommandObjectParsed {
public:
class OptionGroupWriteMemory : public OptionGroup {
public:
OptionGroupWriteMemory() : OptionGroup() {}
~OptionGroupWriteMemory() override = default;
llvm::ArrayRef<OptionDefinition> GetDefinitions() override {
return llvm::makeArrayRef(g_memory_write_options);
}
Status SetOptionValue(uint32_t option_idx, llvm::StringRef option_value,
ExecutionContext *execution_context) override {
Status error;
const int short_option = g_memory_write_options[option_idx].short_option;
switch (short_option) {
case 'i':
m_infile.SetFile(option_value, FileSpec::Style::native);
FileSystem::Instance().Resolve(m_infile);
if (!FileSystem::Instance().Exists(m_infile)) {
m_infile.Clear();
error.SetErrorStringWithFormat("input file does not exist: '%s'",
option_value.str().c_str());
}
break;
case 'o': {
if (option_value.getAsInteger(0, m_infile_offset)) {
m_infile_offset = 0;
error.SetErrorStringWithFormat("invalid offset string '%s'",
option_value.str().c_str());
}
} break;
default:
llvm_unreachable("Unimplemented option");
}
return error;
}
void OptionParsingStarting(ExecutionContext *execution_context) override {
m_infile.Clear();
m_infile_offset = 0;
}
FileSpec m_infile;
off_t m_infile_offset;
};
CommandObjectMemoryWrite(CommandInterpreter &interpreter)
: CommandObjectParsed(
interpreter, "memory write",
"Write to the memory of the current target process.", nullptr,
eCommandRequiresProcess | eCommandProcessMustBeLaunched),
m_option_group(),
m_format_options(
eFormatBytes, 1, UINT64_MAX,
{std::make_tuple(
eArgTypeFormat,
"The format to use for each of the value to be written."),
std::make_tuple(
eArgTypeByteSize,
"The size in bytes to write from input file or each value.")}),
m_memory_options() {
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;
value_arg.arg_opt_set_association = LLDB_OPT_SET_1;
// 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);
m_option_group.Append(&m_format_options,
OptionGroupFormat::OPTION_GROUP_FORMAT,
LLDB_OPT_SET_1);
m_option_group.Append(&m_format_options,
OptionGroupFormat::OPTION_GROUP_SIZE,
LLDB_OPT_SET_1 | LLDB_OPT_SET_2);
m_option_group.Append(&m_memory_options, LLDB_OPT_SET_ALL, LLDB_OPT_SET_2);
m_option_group.Finalize();
}
~CommandObjectMemoryWrite() override = default;
Options *GetOptions() override { return &m_option_group; }
protected:
bool DoExecute(Args &command, CommandReturnObject &result) override {
// No need to check "process" for validity as eCommandRequiresProcess
// ensures it is valid
Process *process = m_exe_ctx.GetProcessPtr();
const size_t argc = command.GetArgumentCount();
if (m_memory_options.m_infile) {
if (argc < 1) {
result.AppendErrorWithFormat(
"%s takes a destination address when writing file contents.\n",
m_cmd_name.c_str());
return false;
}
if (argc > 1) {
result.AppendErrorWithFormat(
"%s takes only a destination address when writing file contents.\n",
m_cmd_name.c_str());
return false;
}
} else if (argc < 2) {
result.AppendErrorWithFormat(
"%s takes a destination address and at least one value.\n",
m_cmd_name.c_str());
return false;
}
StreamString buffer(
Stream::eBinary,
process->GetTarget().GetArchitecture().GetAddressByteSize(),
process->GetTarget().GetArchitecture().GetByteOrder());
OptionValueUInt64 &byte_size_value = m_format_options.GetByteSizeValue();
size_t item_byte_size = byte_size_value.GetCurrentValue();
Status error;
lldb::addr_t addr = OptionArgParser::ToAddress(
&m_exe_ctx, command[0].ref(), LLDB_INVALID_ADDRESS, &error);
if (addr == LLDB_INVALID_ADDRESS) {
result.AppendError("invalid address expression\n");
result.AppendError(error.AsCString());
return false;
}
if (m_memory_options.m_infile) {
size_t length = SIZE_MAX;
if (item_byte_size > 1)
length = item_byte_size;
auto data_sp = FileSystem::Instance().CreateDataBuffer(
m_memory_options.m_infile.GetPath(), length,
m_memory_options.m_infile_offset);
if (data_sp) {
length = data_sp->GetByteSize();
if (length > 0) {
Status error;
size_t bytes_written =
process->WriteMemory(addr, data_sp->GetBytes(), length, error);
if (bytes_written == length) {
// All bytes written
result.GetOutputStream().Printf(
"%" PRIu64 " bytes were written to 0x%" PRIx64 "\n",
(uint64_t)bytes_written, addr);
result.SetStatus(eReturnStatusSuccessFinishResult);
} else if (bytes_written > 0) {
// Some byte written
result.GetOutputStream().Printf(
"%" PRIu64 " bytes of %" PRIu64
" requested were written to 0x%" PRIx64 "\n",
(uint64_t)bytes_written, (uint64_t)length, addr);
result.SetStatus(eReturnStatusSuccessFinishResult);
} else {
result.AppendErrorWithFormat("Memory write to 0x%" PRIx64
" failed: %s.\n",
addr, error.AsCString());
}
}
} else {
result.AppendErrorWithFormat("Unable to read contents of file.\n");
}
return result.Succeeded();
} else if (item_byte_size == 0) {
if (m_format_options.GetFormat() == 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;
for (auto &entry : command) {
switch (m_format_options.GetFormat()) {
case kNumFormats:
case eFormatFloat: // TODO: add support for floats soon
case eFormatCharPrintable:
case eFormatBytesWithASCII:
case eFormatComplex:
case eFormatEnum:
case eFormatUnicode8:
case eFormatUnicode16:
case eFormatUnicode32:
case eFormatVectorOfChar:
case eFormatVectorOfSInt8:
case eFormatVectorOfUInt8:
case eFormatVectorOfSInt16:
case eFormatVectorOfUInt16:
case eFormatVectorOfSInt32:
case eFormatVectorOfUInt32:
case eFormatVectorOfSInt64:
case eFormatVectorOfUInt64:
case eFormatVectorOfFloat16:
case eFormatVectorOfFloat32:
case eFormatVectorOfFloat64:
case eFormatVectorOfUInt128:
case eFormatOSType:
case eFormatComplexInteger:
case eFormatAddressInfo:
case eFormatHexFloat:
case eFormatInstruction:
case eFormatVoid:
result.AppendError("unsupported format for writing memory");
return false;
case eFormatDefault:
case eFormatBytes:
case eFormatHex:
case eFormatHexUppercase:
case eFormatPointer: {
// Decode hex bytes
// Be careful, getAsInteger with a radix of 16 rejects "0xab" so we
// have to special case that:
bool success = false;
if (entry.ref().startswith("0x"))
success = !entry.ref().getAsInteger(0, uval64);
if (!success)
success = !entry.ref().getAsInteger(16, uval64);
if (!success) {
result.AppendErrorWithFormat(
"'%s' is not a valid hex string value.\n", entry.c_str());
return false;
} else if (!llvm::isUIntN(item_byte_size * 8, uval64)) {
result.AppendErrorWithFormat("Value 0x%" PRIx64
" is too large to fit in a %" PRIu64
" byte unsigned integer value.\n",
uval64, (uint64_t)item_byte_size);
return false;
}
buffer.PutMaxHex64(uval64, item_byte_size);
break;
}
case eFormatBoolean:
uval64 = OptionArgParser::ToBoolean(entry.ref(), false, &success);
if (!success) {
result.AppendErrorWithFormat(
"'%s' is not a valid boolean string value.\n", entry.c_str());
return false;
}
buffer.PutMaxHex64(uval64, item_byte_size);
break;
case eFormatBinary:
if (entry.ref().getAsInteger(2, uval64)) {
result.AppendErrorWithFormat(
"'%s' is not a valid binary string value.\n", entry.c_str());
return false;
} else if (!llvm::isUIntN(item_byte_size * 8, uval64)) {
result.AppendErrorWithFormat("Value 0x%" PRIx64
" is too large to fit in a %" PRIu64
" byte unsigned integer value.\n",
uval64, (uint64_t)item_byte_size);
return false;
}
buffer.PutMaxHex64(uval64, item_byte_size);
break;
case eFormatCharArray:
case eFormatChar:
case eFormatCString: {
if (entry.ref().empty())
break;
size_t len = entry.ref().size();
// Include the NULL for C strings...
if (m_format_options.GetFormat() == eFormatCString)
++len;
Status error;
if (process->WriteMemory(addr, entry.c_str(), len, error) == len) {
addr += len;
} else {
result.AppendErrorWithFormat("Memory write to 0x%" PRIx64
" failed: %s.\n",
addr, error.AsCString());
return false;
}
break;
}
case eFormatDecimal:
if (entry.ref().getAsInteger(0, sval64)) {
result.AppendErrorWithFormat(
"'%s' is not a valid signed decimal value.\n", entry.c_str());
return false;
} else if (!llvm::isIntN(item_byte_size * 8, sval64)) {
result.AppendErrorWithFormat(
"Value %" PRIi64 " is too large or small to fit in a %" PRIu64
" byte signed integer value.\n",
sval64, (uint64_t)item_byte_size);
return false;
}
buffer.PutMaxHex64(sval64, item_byte_size);
break;
case eFormatUnsigned:
if (entry.ref().getAsInteger(0, uval64)) {
result.AppendErrorWithFormat(
"'%s' is not a valid unsigned decimal string value.\n",
entry.c_str());
return false;
} else if (!llvm::isUIntN(item_byte_size * 8, uval64)) {
result.AppendErrorWithFormat("Value %" PRIu64
" is too large to fit in a %" PRIu64
" byte unsigned integer value.\n",
uval64, (uint64_t)item_byte_size);
return false;
}
buffer.PutMaxHex64(uval64, item_byte_size);
break;
case eFormatOctal:
if (entry.ref().getAsInteger(8, uval64)) {
result.AppendErrorWithFormat(
"'%s' is not a valid octal string value.\n", entry.c_str());
return false;
} else if (!llvm::isUIntN(item_byte_size * 8, uval64)) {
result.AppendErrorWithFormat("Value %" PRIo64
" is too large to fit in a %" PRIu64
" byte unsigned integer value.\n",
uval64, (uint64_t)item_byte_size);
return false;
}
buffer.PutMaxHex64(uval64, item_byte_size);
break;
}
}
if (!buffer.GetString().empty()) {
Status error;
if (process->WriteMemory(addr, buffer.GetString().data(),
buffer.GetString().size(),
error) == buffer.GetString().size())
return true;
else {
result.AppendErrorWithFormat("Memory write to 0x%" PRIx64
" failed: %s.\n",
addr, error.AsCString());
return false;
}
}
return true;
}
OptionGroupOptions m_option_group;
OptionGroupFormat m_format_options;
OptionGroupWriteMemory m_memory_options;
};
// Get malloc/free history of a memory address.
class CommandObjectMemoryHistory : public CommandObjectParsed {
public:
CommandObjectMemoryHistory(CommandInterpreter &interpreter)
: CommandObjectParsed(interpreter, "memory history",
"Print recorded stack traces for "
"allocation/deallocation events "
"associated with an address.",
nullptr,
eCommandRequiresTarget | eCommandRequiresProcess |
eCommandProcessMustBePaused |
eCommandProcessMustBeLaunched) {
CommandArgumentEntry arg1;
CommandArgumentData addr_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);
// Push the data for the first argument into the m_arguments vector.
m_arguments.push_back(arg1);
}
~CommandObjectMemoryHistory() override = default;
const char *GetRepeatCommand(Args &current_command_args,
uint32_t index) override {
return m_cmd_name.c_str();
}
protected:
bool DoExecute(Args &command, CommandReturnObject &result) override {
const size_t argc = command.GetArgumentCount();
if (argc == 0 || argc > 1) {
result.AppendErrorWithFormat("%s takes an address expression",
m_cmd_name.c_str());
return false;
}
Status error;
lldb::addr_t addr = OptionArgParser::ToAddress(
&m_exe_ctx, command[0].ref(), LLDB_INVALID_ADDRESS, &error);
if (addr == LLDB_INVALID_ADDRESS) {
result.AppendError("invalid address expression");
result.AppendError(error.AsCString());
return false;
}
Stream *output_stream = &result.GetOutputStream();
const ProcessSP &process_sp = m_exe_ctx.GetProcessSP();
const MemoryHistorySP &memory_history =
MemoryHistory::FindPlugin(process_sp);
if (!memory_history) {
result.AppendError("no available memory history provider");
return false;
}
HistoryThreads thread_list = memory_history->GetHistoryThreads(addr);
const bool stop_format = false;
for (auto thread : thread_list) {
thread->GetStatus(*output_stream, 0, UINT32_MAX, 0, stop_format);
}
result.SetStatus(eReturnStatusSuccessFinishResult);
return true;
}
};
// CommandObjectMemoryRegion
#pragma mark CommandObjectMemoryRegion
class CommandObjectMemoryRegion : public CommandObjectParsed {
public:
CommandObjectMemoryRegion(CommandInterpreter &interpreter)
: CommandObjectParsed(interpreter, "memory region",
"Get information on the memory region containing "
"an address in the current target process.",
"memory region ADDR",
eCommandRequiresProcess | eCommandTryTargetAPILock |
eCommandProcessMustBeLaunched),
m_prev_end_addr(LLDB_INVALID_ADDRESS) {}
~CommandObjectMemoryRegion() override = default;
protected:
bool DoExecute(Args &command, CommandReturnObject &result) override {
ProcessSP process_sp = m_exe_ctx.GetProcessSP();
if (!process_sp) {
m_prev_end_addr = LLDB_INVALID_ADDRESS;
result.AppendError("invalid process");
return false;
}
Status error;
lldb::addr_t load_addr = m_prev_end_addr;
m_prev_end_addr = LLDB_INVALID_ADDRESS;
const size_t argc = command.GetArgumentCount();
if (argc > 1 || (argc == 0 && load_addr == LLDB_INVALID_ADDRESS)) {
result.AppendErrorWithFormat("'%s' takes one argument:\nUsage: %s\n",
m_cmd_name.c_str(), m_cmd_syntax.c_str());
return false;
}
if (argc == 1) {
auto load_addr_str = command[0].ref();
load_addr = OptionArgParser::ToAddress(&m_exe_ctx, load_addr_str,
LLDB_INVALID_ADDRESS, &error);
if (error.Fail() || load_addr == LLDB_INVALID_ADDRESS) {
result.AppendErrorWithFormat("invalid address argument \"%s\": %s\n",
command[0].c_str(), error.AsCString());
return false;
}
}
lldb_private::MemoryRegionInfo range_info;
error = process_sp->GetMemoryRegionInfo(load_addr, range_info);
if (error.Success()) {
lldb_private::Address addr;
ConstString name = range_info.GetName();
ConstString section_name;
if (process_sp->GetTarget().ResolveLoadAddress(load_addr, addr)) {
SectionSP section_sp(addr.GetSection());
if (section_sp) {
// Got the top most section, not the deepest section
while (section_sp->GetParent())
section_sp = section_sp->GetParent();
section_name = section_sp->GetName();
}
}
result.AppendMessageWithFormatv(
"[{0:x16}-{1:x16}) {2:r}{3:w}{4:x}{5}{6}{7}{8}",
range_info.GetRange().GetRangeBase(),
range_info.GetRange().GetRangeEnd(), range_info.GetReadable(),
range_info.GetWritable(), range_info.GetExecutable(), name ? " " : "",
name, section_name ? " " : "", section_name);
MemoryRegionInfo::OptionalBool memory_tagged =
range_info.GetMemoryTagged();
if (memory_tagged == MemoryRegionInfo::OptionalBool::eYes)
result.AppendMessage("memory tagging: enabled");
const llvm::Optional<std::vector<addr_t>> &dirty_page_list =
range_info.GetDirtyPageList();
if (dirty_page_list.hasValue()) {
const size_t page_count = dirty_page_list.getValue().size();
result.AppendMessageWithFormat(
"Modified memory (dirty) page list provided, %zu entries.\n",
page_count);
if (page_count > 0) {
bool print_comma = false;
result.AppendMessageWithFormat("Dirty pages: ");
for (size_t i = 0; i < page_count; i++) {
if (print_comma)
result.AppendMessageWithFormat(", ");
else
print_comma = true;
result.AppendMessageWithFormat("0x%" PRIx64,
dirty_page_list.getValue()[i]);
}
result.AppendMessageWithFormat(".\n");
}
}
m_prev_end_addr = range_info.GetRange().GetRangeEnd();
result.SetStatus(eReturnStatusSuccessFinishResult);
return true;
}
result.AppendErrorWithFormat("%s\n", error.AsCString());
return false;
}
const char *GetRepeatCommand(Args &current_command_args,
uint32_t index) override {
// If we repeat this command, repeat it without any arguments so we can
// show the next memory range
return m_cmd_name.c_str();
}
lldb::addr_t m_prev_end_addr;
};
// CommandObjectMemory
CommandObjectMemory::CommandObjectMemory(CommandInterpreter &interpreter)
: CommandObjectMultiword(
interpreter, "memory",
"Commands for operating on memory in the current target process.",
"memory <subcommand> [<subcommand-options>]") {
LoadSubCommand("find",
CommandObjectSP(new CommandObjectMemoryFind(interpreter)));
LoadSubCommand("read",
CommandObjectSP(new CommandObjectMemoryRead(interpreter)));
LoadSubCommand("write",
CommandObjectSP(new CommandObjectMemoryWrite(interpreter)));
LoadSubCommand("history",
CommandObjectSP(new CommandObjectMemoryHistory(interpreter)));
LoadSubCommand("region",
CommandObjectSP(new CommandObjectMemoryRegion(interpreter)));
LoadSubCommand("tag",
CommandObjectSP(new CommandObjectMemoryTag(interpreter)));
}
CommandObjectMemory::~CommandObjectMemory() = default;