{

std::ostringstream os;

auto b = begin(elements), e = end(elements);

if (b == e) {

return "";

}

std::copy(b, prev(e), std::ostream_iterator<Value>(os, delimiter));

os << *prev(e);

return os.str();

{

if (max_size - arg.size() > 0) {

return std::forward<T>(arg);

}

return ELLIPSIS;

const std::vector<remote_addr_t>& items,

const std::shared_ptr<const AbstractProcessManager>& manager,

ssize_t max_size)

{

std::vector<std::string> elements;

elements.reserve(items.size());

ssize_t remaining_size = max_size;

for (auto& item : items) {

LOG(DEBUG) << "Constructing sequence object " << elements.size()

<< " from addr: " << std::showbase << std::hex << item;

std::string item_str = Object(manager, item).toString(remaining_size);

remaining_size -= item_str.size() + 2;

if (remaining_size < (ssize_t)(ELLIPSIS.size() + 2)) {

elements.push_back(ELLIPSIS);

break;

}

elements.push_back(item_str);

}

return join(elements, ", ");

{

return std::all_of(val.cbegin(), val.cend(), [](auto& c) {

return static_cast<unsigned char>(c) < 127;

});

{

if (containsOnlyASCII(val)) {

return prefix + '"' + val + '"';

}

return "<BINARY>";

const std::shared_ptr<const AbstractProcessManager>& manager,

remote_addr_t addr)

{

d_manager = manager;

Structure<py_tuple_v> tuple(manager, addr);

ssize_t num_items = tuple.getField(&py_tuple_v::o_ob_size);

if (num_items == 0) {

LOG(DEBUG) << std::hex << std::showbase << "There are no elements in this tuple";

return;

}

d_items.resize(num_items);

manager->copyMemoryFromProcess(

tuple.getFieldRemoteAddress(&py_tuple_v::o_ob_item),

num_items * sizeof(PyObject*),

d_items.data());

{

const ssize_t remaining_size = max_size - 2; // Make room for the '(' and the ')'

return "(" + formatSequence(Items(), d_manager, remaining_size) + ")";

{

d_manager = manager;

Structure<py_list_v> list(manager, addr);

ssize_t num_items = list.getField(&py_list_v::o_ob_size);

if (num_items == 0) {

LOG(DEBUG) << std::hex << std::showbase << "There are no elements in this list";

return;

}

d_items.resize(num_items);

manager->copyMemoryFromProcess(

(remote_addr_t)list.getField(&py_list_v::o_ob_item),

num_items * sizeof(PyObject*),

d_items.data());

{

const ssize_t remaining_size = max_size - 2; // Make room for the '[' and the ']'

return "[" + formatSequence(Items(), d_manager, remaining_size) + "]";

const std::shared_ptr<const AbstractProcessManager>& manager,

remote_addr_t addr,

bool is_bool)

: d_is_bool(is_bool)

{

#ifdef ENVIRONMENT64

constexpr unsigned int shift = 30;

#else

constexpr unsigned int shift = 15;

#endif

Structure<py_long_v> longobj(manager, addr);

ssize_t size;

bool negative;

Py_ssize_t ob_size = longobj.getField(&py_long_v::o_ob_size);

if (manager->versionIsAtLeast(3, 12)) {

auto lv_tag = *reinterpret_cast<uintptr_t*>(&ob_size);

negative = (lv_tag & 3) == 2;

size = lv_tag >> 3;

} else {

negative = ob_size < 0;

size = std::abs(ob_size);

}

if (size == 0) {

d_value = 0;

return;

}

/* Python's Include/longobjrep.h has this declaration:

std::vector<digit> digits;

digits.resize(size);

manager->copyMemoryFromProcess(

longobj.getFieldRemoteAddress(&py_long_v::o_ob_digit),

sizeof(digit) * size,

digits.data());

for (ssize_t i = 0; i < size; ++i) {

long long factor;

if (__builtin_mul_overflow(digits[i], (1Lu << (ssize_t)(shift * i)), &factor)) {

d_overflowed = true;

return;

}

if (__builtin_add_overflow(d_value, factor, &d_value)) {

d_overflowed = true;

return;

}

}

if (negative) {

d_value = -1 * d_value;

}

{

if (d_is_bool) {

if (Value() > 0) {

return "True";

}

return "False";

}

if (Overflowed()) {

return "<UNRESOLVED BIG INT>";

}

return limitOutput(std::to_string(Value()), max_size);

const std::shared_ptr<const AbstractProcessManager>& manager,

Structure<py_dict_v>& dict,

ssize_t& num_items,

std::vector<Python3::PyDictKeyEntry>& valid_entries)

{

assert(manager->versionIsAtLeast(3, 0));

remote_addr_t keys_addr = dict.getField(&py_dict_v::o_ma_keys);

ssize_t dk_size = 0;

int dk_kind = 0;

Structure<py_dictkeys_v> keys(manager, keys_addr);

num_items = keys.getField(&py_dictkeys_v::o_dk_nentries);

dk_size = keys.getField(&py_dictkeys_v::o_dk_size);

if (manager->versionIsAtLeast(3, 11)) {

// We're reusing the o_dk_size offset for dk_log2_size. Fix up the value.

dk_size = 1L << dk_size;

// Added in 3.11

dk_kind = keys.getField(&py_dictkeys_v::o_dk_kind);

}

if (num_items == 0) {

LOG(DEBUG) << std::hex << std::showbase << "There are no elements in this dict";

return;

}

/*

ssize_t offset;

if (dk_size <= 0xFF) {

offset = dk_size;

} else if (dk_size <= 0xFFFF) {

offset = 2 * dk_size;

} else if (dk_size <= 0xFFFFFFFF) {

offset = 4 * dk_size;

} else {

offset = 8 * dk_size;

}

offset_t dk_indices_addr = keys.getFieldRemoteAddress(&py_dictkeys_v::o_dk_indices);

remote_addr_t entries_addr = dk_indices_addr + offset;

std::vector<Python3::PyDictKeyEntry> raw_entries;

raw_entries.resize(num_items);

if (dk_kind != 0) { // New PyDictUnicodeEntry

std::vector<Python3_11::PyDictUnicodeEntry> unicode_entries;

unicode_entries.resize(num_items);

manager->copyMemoryFromProcess(

entries_addr,

num_items * sizeof(Python3_11::PyDictUnicodeEntry),

unicode_entries.data());

std::transform(

unicode_entries.cbegin(),

unicode_entries.cend(),

std::back_inserter(raw_entries),

[](auto& entry) {

return Python3::PyDictKeyEntry{0, entry.me_key, entry.me_value};

});

} else {

manager->copyMemoryFromProcess(

entries_addr,

num_items * sizeof(Python3::PyDictKeyEntry),

raw_entries.data());

}

// Filter out the entries that are empty

std::copy_if(

make_move_iterator(raw_entries.cbegin()),

make_move_iterator(raw_entries.cend()),

std::back_inserter(valid_entries),

[](auto& entry) { return entry.me_key != 0; });

: d_manager(std::move(manager))

{

// For now, the layout that we use here only allows us to get Python3.6+ dictionaries

// as dictionaries before that have much more variability and are much harder to get.

if (d_manager->versionIsAtLeast(3, 6)) {

loadFromPython3(addr);

} else if (d_manager->versionIsAtLeast(3, 0)) {

d_invalid = true;

} else {

loadFromPython2(addr);

}

{

Structure<py_dict_v> dict(d_manager, addr);

ssize_t num_items;

std::vector<Python3::PyDictKeyEntry> valid_entries;

getDictEntries(d_manager, dict, num_items, valid_entries);

// Copy the keys

d_keys.reserve(valid_entries.size());

std::transform(

valid_entries.cbegin(),

valid_entries.cend(),

std::back_inserter(d_keys),

[](auto& entry) { return (remote_addr_t)entry.me_key; });

/* The DictObject can be in one of two forms.

remote_addr_t dictvalues_addr = dict.getField(&py_dict_v::o_ma_values);

Structure<py_dictvalues_v> dictvalues(d_manager, dictvalues_addr);

// Get the values in one copy if we are dealing with a split-table dictionary

if (dictvalues_addr != 0) {

d_values.resize(num_items);

auto values_addr = dictvalues.getFieldRemoteAddress(&py_dictvalues_v::o_values);

d_manager->copyMemoryFromProcess(values_addr, num_items * sizeof(PyObject*), d_values.data());

} else {

std::transform(

valid_entries.cbegin(),

valid_entries.cend(),

std::back_inserter(d_values),

[](auto& entry) { return (remote_addr_t)entry.me_value; });

}

{

Python2::PyDictObject dict;

d_manager->copyObjectFromProcess(addr, &dict);

ssize_t num_items = dict.ma_mask + 1;

std::vector<Python2::PyDictEntry> raw_entries;

raw_entries.resize(num_items);

auto entries_addr = (remote_addr_t)dict.ma_table;

d_manager->copyMemoryFromProcess(

entries_addr,

num_items * sizeof(Python2::PyDictEntry),

raw_entries.data());

std::vector<Python2::PyDictEntry> valid_entries;

// Filter out the entries that are empty

std::copy_if(

std::make_move_iterator(raw_entries.cbegin()),

std::make_move_iterator(raw_entries.cend()),

std::back_inserter(valid_entries),

[](auto& entry) { return entry.me_value != 0; });

// Copy the keys

std::vector<remote_addr_t> keys;

keys.reserve(valid_entries.size());

std::transform(

valid_entries.cbegin(),

valid_entries.cend(),

std::back_inserter(d_keys),

[](auto& entry) { return (remote_addr_t)entry.me_key; });

// Copy the values

d_values.reserve(valid_entries.size());

std::transform(

valid_entries.cbegin(),

valid_entries.cend(),

std::back_inserter(d_values),

[](auto& entry) { return (remote_addr_t)entry.me_value; });

{

if (Invalid()) {

return "<UNRESOLVED DICT OBJECT>";

}

std::vector<std::string> elements;

elements.reserve(Keys().size());

// Make room for the "{" and the "}"

ssize_t remaining_size = max_size - 2;

for (size_t i = 0; i < Keys().size(); ++i) {

const remote_addr_t key_addr = Keys()[i];

LOG(DEBUG) << "Constructing dictionary key " << i << " from addr: " << std::showbase << std::hex

<< key_addr;

std::string item_str = Object(d_manager, key_addr).toString(remaining_size);

item_str += ": ";

const remote_addr_t val_addr = Values()[i];

LOG(DEBUG) << "Constructing dictionary value " << i << " from addr: " << std::showbase

<< std::hex << val_addr;

item_str += Object(d_manager, val_addr).toString(remaining_size);

remaining_size -= item_str.size() + 2;

if (remaining_size < 5) {

elements.push_back(ELLIPSIS);

break;

}

elements.push_back(item_str);

}

return "{" + join(elements, ", ") + "}";

: d_addr(addr)

, d_classname(std::move(classname))

{

{

std::stringstream os;

os << "<" << std::hex << d_classname << " at 0x" << d_addr << ">";

std::string object_str = os.str();

return limitOutput(object_str, max_size);

: d_addr(addr)

, d_type_addr(0)

, d_classname()

, d_flags()

, d_manager(manager)

{

LOG(DEBUG) << std::hex << std::showbase << "Copying PyObject data from address " << addr;

Structure<py_object_v> obj(manager, addr);

try {

obj.copyFromRemote();

} catch (RemoteMemCopyError& ex) {

LOG(WARNING) << std::hex << std::showbase << "Failed to read PyObject data from address "

<< d_addr;

d_classname = "invalid object";

return;

}

d_type_addr = obj.getField(&py_object_v::o_ob_type);

LOG(DEBUG) << std::hex << std::showbase << "Copying typeobject from address " << d_type_addr;

Structure<py_type_v> cls(manager, d_type_addr);

try {

d_flags = cls.getField(&py_type_v::o_tp_flags);

} catch (RemoteMemCopyError& ex) {

LOG(WARNING) << std::hex << std::showbase << "Failed to read typeobject from address "

<< d_type_addr;

d_classname = "invalid object";

return;

}

remote_addr_t name_addr = cls.getField(&py_type_v::o_tp_name);

try {

d_classname = manager->getCStringFromAddress(name_addr);

} catch (RemoteMemCopyError& ex) {

// If the original ELF files are not available, we can try to guess the class

// name from other available information, specially for the types where the

// class name is needed to categorize then.

d_classname = guessClassName(cls);

}

LOG(DEBUG) << "Object class resolved to: " << d_classname;

{

// Check if we have enough room for an ellipsis and container surrounding

// characters and if not, replace the object with an ellipsis.

if (max_size <= 5) {

return ELLIPSIS;

}

try {

std::stringstream os;

std::visit(

overloaded{

[&](const auto& arg) { os << arg.toString(max_size); },

[&](const bool arg) { os << arg; },

[&](const long arg) { os << arg; },

[&](const double arg) { os << arg; },

[&](const std::string& arg) {

std::string truncated = arg;

if (static_cast<size_t>(max_size) < arg.size()) {

truncated = arg.substr(0, max_size - 3) + "...";

}

os << truncated;

},

},

toConcreteObject());

return os.str();

} catch (RemoteMemCopyError& ex) {

LOG(WARNING) << std::hex << std::showbase << "Failed to create a repr for object of type "

<< d_classname << " at address " << d_addr;

std::stringstream os;

os << std::hex << std::showbase << "<" << d_classname << " object at " << d_addr << ">";

return os.str();

}

{

_PyIntObject the_int;

d_manager->copyObjectFromProcess(d_addr, &the_int);

return the_int.ob_ival;

{

Structure<py_float_v> the_float(d_manager, d_addr);

return the_float.getField(&py_float_v::o_ob_fval);

{

if (toInteger() > 0) {

return true;

}

return false;

{

// clang-format off

constexpr long subclass_mask =

(Pystack_TPFLAGS_INT_SUBCLASS

| Pystack_TPFLAGS_LONG_SUBCLASS

| Pystack_TPFLAGS_LIST_SUBCLASS

| Pystack_TPFLAGS_TUPLE_SUBCLASS

| Pystack_TPFLAGS_BYTES_SUBCLASS

| Pystack_TPFLAGS_UNICODE_SUBCLASS

| Pystack_TPFLAGS_DICT_SUBCLASS

| Pystack_TPFLAGS_BASE_EXC_SUBCLASS

| Pystack_TPFLAGS_TYPE_SUBCLASS);

// clang-format on

const long subclass_flags = d_flags & subclass_mask;

if (subclass_flags == Pystack_TPFLAGS_BYTES_SUBCLASS) {

return d_manager->versionIsAtLeast(3, 0) ? ObjectType::BYTES : ObjectType::STRING;

} else if (subclass_flags == Pystack_TPFLAGS_UNICODE_SUBCLASS) {

return ObjectType::STRING;

} else if (subclass_flags == Pystack_TPFLAGS_INT_SUBCLASS) {

if (d_classname == "bool") {

return ObjectType::INT_BOOL;

}

return ObjectType::INT;

} else if (subclass_flags == Pystack_TPFLAGS_LONG_SUBCLASS) {

if (d_classname == "bool") {

return ObjectType::LONG_BOOL;

}

return ObjectType::LONG;

} else if (subclass_flags == Pystack_TPFLAGS_TUPLE_SUBCLASS) {

return ObjectType::TUPLE;

} else if (subclass_flags == Pystack_TPFLAGS_LIST_SUBCLASS) {

return ObjectType::LIST;

} else if (subclass_flags == Pystack_TPFLAGS_DICT_SUBCLASS) {

return ObjectType::DICT;

} else if (d_classname == "float") {

return ObjectType::FLOAT;

} else if (d_classname == "NoneType") {

return ObjectType::NONE;

} else if (d_classname == "code") {

return ObjectType::CODE;

}

return ObjectType::OTHER;

{

try {

switch (objectType()) {

case Object::ObjectType::STRING:

if (d_manager->versionIsAtLeast(3, 0)) {

return '"' + d_manager->getStringFromAddress(d_addr) + '"';

}

return normalizeBytesObjectRepresentation(d_manager->getStringFromAddress(d_addr), "");

case Object::ObjectType::BYTES:

return normalizeBytesObjectRepresentation(d_manager->getBytesFromAddress(d_addr));

case Object::ObjectType::NONE:

return NoneObject(d_addr);

case Object::ObjectType::INT:

return toInteger();

case Object::ObjectType::INT_BOOL:

return toBool();

case Object::ObjectType::LONG:

return LongObject(d_manager, d_addr);

case Object::ObjectType::LONG_BOOL:

return LongObject(d_manager, d_addr, true);

case Object::ObjectType::FLOAT:

return toFloat();

case Object::ObjectType::TUPLE:

return TupleObject(d_manager, d_addr);

case Object::ObjectType::LIST:

return ListObject(d_manager, d_addr);

case Object::ObjectType::DICT:

return DictObject(d_manager, d_addr);

case Object::ObjectType::CODE:

case Object::ObjectType::OTHER:

return GenericObject(d_addr, d_classname);

}

} catch (InvalidRemoteObject&) {

LOG(DEBUG) << std::hex << std::showbase << "Failed to identify object at address: " << d_addr;

}

return GenericObject(d_addr, d_classname);

{

remote_addr_t tp_repr = type.getField(&py_type_v::o_tp_repr);

if (tp_repr == d_manager->findSymbol("float_repr")) {

return "float";

}

if (tp_repr == d_manager->findSymbol("none_repr")) {

return "NoneType";

}

if (tp_repr == d_manager->findSymbol("bool_repr")) {

return "bool";

}

if (tp_repr == d_manager->findSymbol("code_repr")) {

return "PyCodeObject";

}

return "???";