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ivalue.cpp
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ivalue.cpp
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#include <ATen/core/ivalue.h>
#include <ATen/core/Dict.h>
#include <ATen/core/Formatting.h>
#include <ATen/core/class_type.h>
#include <ATen/core/enum_type.h>
#include <ATen/core/function.h>
#include <ATen/core/jit_type.h>
#include <ATen/core/stack.h>
#include <ATen/core/type_factory.h>
#include <c10/util/irange.h>
#include <c10/util/StringUtil.h>
#include <c10/util/hash.h>
#include <cmath>
#include <iostream>
namespace c10 {
bool _fastEqualsForContainer(const IValue& lhs, const IValue& rhs) {
if (lhs.is(rhs)) {
// Like Python, for containers we consider identity equality to be
// sufficient but not necessary for value equality
return true;
}
return lhs == rhs;
}
namespace ivalue {
// This is in ivalue.cpp because we need to access Type::annotation_str, which
// is declared in jit_type.h
void checkCustomClassType(const ClassType* expected_type, const Type* actual_type) {
// NB: doing pointer comparison here
// If in the future there ever arises a need to call operator== on custom class
// Type's, this needs to be changed!
TORCH_CHECK(actual_type == static_cast<const Type*>(expected_type),
"Tried to convert an IValue of type ",
actual_type ? actual_type->repr_str() : std::string("*NULL*"),
" to custom class type ",
expected_type ? expected_type->repr_str() : std::string("*NULL*"));
}
TORCH_API c10::intrusive_ptr<ConstantString> ConstantString::create(
std::string str_) {
return c10::make_intrusive<ConstantString>(std::move(str_));
}
TORCH_API c10::intrusive_ptr<ConstantString> ConstantString::create(
c10::string_view str_) {
return c10::make_intrusive<ConstantString>(std::string(str_));
}
TORCH_API c10::intrusive_ptr<ConstantString> ConstantString::create(
const char* str_) {
return c10::make_intrusive<ConstantString>(std::string(str_));
}
bool operator==(const ivalue::Tuple& lhs, const ivalue::Tuple& rhs) {
return lhs.size() == rhs.size() &&
// see [container equality]
std::equal(
lhs.elements().cbegin(),
lhs.elements().cend(),
rhs.elements().cbegin(),
_fastEqualsForContainer);
}
bool operator==(const ivalue::EnumHolder& lhs, const ivalue::EnumHolder& rhs) {
return lhs.name() == rhs.name() && *rhs.type() == *lhs.type();
}
const std::string ivalue::EnumHolder::qualifiedClassName() const {
return type_->qualifiedClassName().qualifiedName();
}
const std::string ivalue::EnumHolder::unqualifiedClassName() const {
return type_->qualifiedClassName().name();
}
} // namespace ivalue
c10::TypePtr IValue::TagType<c10::Type>::get(const IValue& v) {
switch (v.tag) {
case Tag::None:
return NoneType::get();
case Tag::Tensor:
return TensorType::create(v.toTensor());
case Tag::Storage:
return StorageType::get();
case Tag::Double:
return FloatType::get();
case Tag::ComplexDouble:
return ComplexType::get();
case Tag::Int:
return IntType::get();
case Tag::SymInt:
return c10::SymIntType::get();
case Tag::SymFloat:
return c10::SymFloatType::get();
case Tag::Bool:
return BoolType::get();
case Tag::String:
return StringType::get();
case Tag::Blob:
return AnyType::get();
case Tag::GenericDict: {
auto d = v.toGenericDict();
return DictType::create(d.keyType(), d.valueType());
}
case Tag::GenericList:
return ListType::create(v.toList().elementType());
case Tag::Future:
return FutureType::create(v.toFuture()->elementType());
case Tag::RRef:
return RRefType::create(v.toRRef()->type());
case Tag::Device:
return DeviceObjType::get();
case Tag::Stream:
return StreamObjType::get();
case Tag::Object:
return v.toObjectRef().type();
case Tag::PyObject:
return PyObjectType::get();
case Tag::Uninitialized:
return AnyType::get();
case Tag::Capsule:
return CapsuleType::get();
case Tag::Tuple:
return v.toTupleRef().type();
case Tag::Generator:
return GeneratorType::get();
case Tag::Quantizer:
return QuantizerType::get();
case Tag::Enum:
return v.toEnumHolder()->type();
}
// switch above is complete but this silences compiler warnings
TORCH_INTERNAL_ASSERT(false, "unhandled case in IValue::type()");
}
void IValue::visit(const std::function<bool (const IValue &)>& visitor) const {
if (visitor(*this)) {
// Shortcut
return;
}
switch (this->tag) {
case Tag::Tuple:
case Tag::GenericList: {
c10::ArrayRef<IValue> elems;
if (isTuple()) {
elems = this->toTupleRef().elements();
} else {
elems = this->toListRef();
}
for (auto& elem : elems) {
elem.visit(visitor);
}
break;
}
case Tag::GenericDict:
for (const auto& pair : this->toGenericDict()) {
pair.value().visit(visitor);
pair.key().visit(visitor);
}
break;
case Tag::Object: {
auto obj_type = type()->expect<ClassType>();
auto obj_value = toObject();
auto attributes = obj_type->getAttributes();
for (const auto& attr: attributes) {
auto attribute = obj_value->getAttr(attr.getName());
attribute.visit(visitor);
}
break;
}
case Tag::PyObject: {
c10::intrusive_ptr<at::ivalue::PyObjectHolder> py_obj = toPyObjectHolder();
auto match = py_obj->tryToInferType();
if (match.success()) {
auto contained_value = py_obj->toIValue(match.type());
contained_value.visit(visitor);
}
break;
}
default:
break;
}
}
void IValue::getSubValues(HashAliasedIValues& subValues) const {
switch (this->tag) {
case Tag::Tensor:
subValues.insert(*this);
return;
case Tag::Tuple:
case Tag::GenericList: {
subValues.insert(*this);
c10::ArrayRef<IValue> elems;
if (isTuple()) {
elems = this->toTupleRef().elements();
} else {
elems = this->toListRef();
}
for (auto& elem : elems) {
elem.getSubValues(subValues);
}
break;
}
case Tag::GenericDict:
subValues.insert(*this);
for (const auto& pair : this->toGenericDict()) {
pair.value().getSubValues(subValues);
pair.key().getSubValues(subValues);
}
break;
case Tag::Object: {
// Record Object IValue and its attributes.
subValues.insert(*this);
auto obj_type = type()->expect<ClassType>();
auto obj_value = toObject();
auto attributes = obj_type->getAttributes();
for (const auto& attr: attributes) {
auto attribute = obj_value->getAttr(attr.getName());
attribute.getSubValues(subValues);
}
break;
}
case Tag::PyObject: {
subValues.insert(*this);
c10::intrusive_ptr<at::ivalue::PyObjectHolder> py_obj = toPyObjectHolder();
auto match = py_obj->tryToInferType();
TORCH_CHECK_TYPE(match.success(),
"Cannot infer type of ", py_obj->toStr(), ": ", match.reason());
auto contained_value = py_obj->toIValue(match.type());
contained_value.getSubValues(subValues);
break;
}
case Tag::Future:
case Tag::Device:
case Tag::Uninitialized:
case Tag::Capsule:
TORCH_CHECK_TYPE(
false, "Cannot inspect value of type ", this->tagKind());
// Fall through
default:
// don't record scalars.
break;
}
}
bool IValue::overlaps(const IValue& rhs) const {
HashAliasedIValues rhsSubValues, thisSubValues;
rhs.getSubValues(rhsSubValues);
getSubValues(thisSubValues);
for (auto& sub : thisSubValues) {
if (rhsSubValues.count(sub)) {
return true;
}
}
return false;
}
bool operator!=(const IValue& lhs, const IValue& rhs) {
return !(lhs == rhs);
}
bool operator==(const IValue& lhs, const IValue& rhs) {
IValue eq = lhs.equals(rhs);
if (eq.isBool()) {
return eq.toBool();
}
// The only case we don't return bool is for tensor comparison. In Python,
// `bool()` is called on the return value of `__eq__` if the return value is
// not a boolean. Mimic that behavior here.
TORCH_INTERNAL_ASSERT(eq.isTensor());
return eq.toTensor().is_nonzero();
}
bool IValue::ptrEqual(const IValue& lhs, const IValue& rhs) {
TORCH_INTERNAL_ASSERT(lhs.isIntrusivePtr());
TORCH_INTERNAL_ASSERT(rhs.isIntrusivePtr());
return lhs.tag == rhs.tag &&
lhs.payload.u.as_intrusive_ptr == rhs.payload.u.as_intrusive_ptr;
}
IValue IValue::equals(const IValue& rhs) const {
const IValue& lhs = *this;
switch (lhs.tag) {
case Tag::None:
// In Python you're not supposed to do this comparison apparently. Not
// sure if we should warn here or what
return rhs.isNone();
case Tag::Tensor: {
if (!rhs.isTensor()) {
return false;
}
return lhs.toTensor().eq(rhs.toTensor());
}
case Tag::Storage:
return rhs.isStorage() && lhs.toStorage().unsafeGetStorageImpl() == rhs.toStorage().unsafeGetStorageImpl();
case Tag::Double:
return rhs.isDouble() && lhs.toDouble() == rhs.toDouble();
case Tag::ComplexDouble:
return rhs.isComplexDouble() && lhs.toComplexDouble() == rhs.toComplexDouble();
case Tag::Int:
return rhs.isInt() && lhs.toInt() == rhs.toInt();
case Tag::SymInt:
return rhs.isSymInt() && lhs.toSymInt() == rhs.toSymInt();
case Tag::SymFloat:
// NB: this doesn't actually work as sym floats don't have equality
// defined
return rhs.isSymFloat() && lhs.toSymFloat() == rhs.toSymFloat();
case Tag::Bool:
return rhs.isBool() && lhs.toBool() == rhs.toBool();
case Tag::String:
return rhs.isString() && lhs.toStringRef() == rhs.toStringRef();
case Tag::GenericDict:
return rhs.isGenericDict() && lhs.toGenericDict() == rhs.toGenericDict();
case Tag::Tuple:
return rhs.isTuple() && *lhs.toTuple() == *rhs.toTuple();
case Tag::Stream:
return rhs.isStream() && lhs.toStream() == rhs.toStream();
case Tag::Device:
return rhs.isDevice() && lhs.toDevice() == rhs.toDevice();
case Tag::GenericList:
return rhs.isList() && lhs.toList() == rhs.toList();
case Tag::Blob:
case Tag::Future:
case Tag::RRef:
case Tag::Object:
case Tag::PyObject:
case Tag::Capsule:
case Tag::Generator:
case Tag::Quantizer:
return ptrEqual(lhs, rhs);
case Tag::Enum:
return lhs.toEnumHolder()->is(*rhs.toEnumHolder());
case Tag::Uninitialized:
// Unitialized ivalues show up in no-ops when the compiler can prove a
// value will never be used. Just return false on any equality comparison.
return false;
}
// the above switch should be exhaustive
TORCH_INTERNAL_ASSERT(false, "we should never reach here")
}
size_t IValue::hash(const IValue& v) {
switch (v.tag) {
case Tag::None:
return 0;
case Tag::Bool:
return c10::get_hash(v.payload.u.as_bool);
case Tag::Double:
return c10::get_hash(v.payload.u.as_double);
case Tag::Tensor:
// Tensor __hash__ is equivalent to `id()`, so take the pointer value of
// the tensor to emulate it
return c10::get_hash(v.payload.as_tensor.unsafeGetTensorImpl());
// NOLINTNEXTLINE(bugprone-branch-clone)
case Tag::Storage:
return c10::get_hash(v.payload.u.as_int);
case Tag::Int:
return c10::get_hash(v.payload.u.as_int);
// NB: these are technically strict aliasing violations
case Tag::SymInt:
return c10::get_hash(v.payload.u.as_int);
case Tag::SymFloat:
return c10::get_hash(v.payload.u.as_int);
case Tag::String:
return c10::get_hash(v.toStringRef());
case Tag::Tuple:
return c10::get_hash(*v.toTuple());
case Tag::Device:
return c10::get_hash(v.toDevice());
case Tag::GenericDict:
case Tag::GenericList:
case Tag::Blob:
case Tag::Future:
case Tag::RRef:
case Tag::Object:
case Tag::PyObject:
case Tag::Capsule:
case Tag::Generator:
case Tag::Quantizer:
case Tag::ComplexDouble:
case Tag::Enum:
case Tag::Stream:
case Tag::Uninitialized:
throw std::runtime_error(
"unhashable type: '" + v.type()->repr_str() + "'");
}
// the above switch should be exhaustive
TORCH_INTERNAL_ASSERT(false, "we should never reach here")
}
static bool isUndefinedTensor(const IValue& iv) {
return iv.isTensor() && !iv.toTensor().defined();
}
bool IValue::is(const IValue& rhs) const {
const IValue& lhs = *this;
// Special handling for undefined tensors:
// 1. Undefined_tensor is None and vice versa.
if ((isUndefinedTensor(lhs) && rhs.isNone()) ||
(lhs.isNone() && isUndefinedTensor(rhs))) {
return true;
}
// 2. Undefined_tensor is Undefined_tensor.
if (isUndefinedTensor(lhs) && isUndefinedTensor(rhs)) {
return true;
}
if (lhs.isTensor()) {
// Use the standard way of comparing two tensors for identity
return rhs.isTensor() && lhs.toTensor().is_same(rhs.toTensor());
}
if (lhs.isIntrusivePtr()) {
return rhs.isIntrusivePtr() && ptrEqual(lhs, rhs);
}
return lhs == rhs;
}
template <typename T>
inline bool IValue::isListOf() const {
// note: avoids calling type() to avoid extra referencing counting for the returned type.
if (!isList()) {
return false;
}
const auto& ty = static_cast<detail::ListImpl*>(payload.u.as_intrusive_ptr)->elementType;
if (ty->kind() == T::Kind) {
return true;
}
return *ty == *TypeFactory::get<T>();
}
bool IValue::isDoubleList() const {
return isListOf<c10::FloatType>();
}
bool IValue::isComplexDoubleList() const {
return isListOf<c10::ComplexType>();
}
bool IValue::isTensorList() const {
return isListOf<c10::TensorType>();
}
bool IValue::isOptionalTensorList() const {
if (!isList()) {
return false;
}
const auto& ty = static_cast<detail::ListImpl*>(payload.u.as_intrusive_ptr)->elementType;
const auto expected_ty = c10::getTypePtr<c10::optional<at::Tensor>>();
return expected_ty == ty;
}
bool IValue::isIntList() const {
return isListOf<c10::IntType>();
}
bool IValue::isBoolList() const {
return isListOf<c10::BoolType>();
}
namespace {
using IValueFormatter = std::function<void(std::ostream&, const IValue&)>;
template <class T>
std::ostream& printList(
std::ostream& out,
const T& list,
const std::string start,
const std::string finish,
IValueFormatter formatter) {
out << start;
for (const auto i : c10::irange(list.size())) {
if (i > 0) {
out << ", ";
}
formatter(out, IValue(list[i]));
}
out << finish;
return out;
}
// Properly disambiguate the type of an empty list
std::ostream& printMaybeAnnotatedList(
std::ostream& out,
const IValue& the_list,
IValueFormatter formatter) {
auto list_elem_type = the_list.type()->containedType(0);
if (the_list.toListRef().size() == 0 ||
!elementTypeCanBeInferredFromMembers(list_elem_type)) {
out << "annotate(" << the_list.type<c10::Type>()->annotation_str() << ", ";
printList(out, the_list.toListRef(), "[", "]", formatter);
out << ")";
return out;
} else {
return printList(out, the_list.toListRef(), "[", "]", formatter);
}
}
template <typename Dict>
std::ostream& printDict(
std::ostream& out,
const Dict& v,
IValueFormatter formatter) {
out << "{";
bool first = true;
for (const auto& pair : v) {
if (!first) {
out << ", ";
}
formatter(out, pair.key());
out << ": ";
formatter(out, pair.value());
first = false;
}
out << "}";
return out;
}
}
// Properly disambiguate the type of an empty dict
std::ostream& printMaybeAnnotatedDict(
std::ostream& out,
const IValue& the_dict,
IValueFormatter formatter) {
auto value_type = the_dict.type()->castRaw<DictType>()->getValueType();
if (the_dict.toGenericDict().size() == 0 ||
!elementTypeCanBeInferredFromMembers(value_type)) {
out << "annotate(" << the_dict.type<c10::Type>()->annotation_str() << ",";
printDict(out, the_dict.toGenericDict(), formatter) << ")";
} else {
return printDict(out, the_dict.toGenericDict(), formatter);
}
return out;
}
std::ostream& printComplex(std::ostream & out, const IValue & v) {
c10::complex<double> d = v.toComplexDouble();
IValue real(d.real()), imag(std::abs(d.imag()));
auto sign = "";
if (d.imag() >= 0) {
sign = "+";
} else {
sign = "-";
}
return out << real << sign << imag << "j";
}
std::ostream& IValue::repr(
std::ostream& out,
std::function<bool(std::ostream&, const IValue& v)>
customFormatter) const {
// First check if the caller has provided a custom formatter. Use that if possible.
if (customFormatter(out, *this)) {
return out;
}
const IValue& v = *this;
// continue to use custom formatter in recursion
auto formatter = [&](std::ostream& out, const IValue& input) {
input.repr(out, customFormatter);
};
switch (v.tag) {
case IValue::Tag::None:
return out << v.toNone();
case IValue::Tag::Double: {
double d = v.toDouble();
int c = std::fpclassify(d);
if ((c == FP_NORMAL || c == FP_ZERO ) && std::abs(d) < 1e10) {
int64_t i = int64_t(d);
if (double(i) == d) {
// -0.0 (signed zero) needs to be parsed as -0.
if (i == 0 && std::signbit(d)) {
return out << "-" << i << ".";
}
return out << i << ".";
}
}
auto orig_prec = out.precision();
return out << std::setprecision(std::numeric_limits<double>::max_digits10)
<< d << std::setprecision(orig_prec);
}
case IValue::Tag::ComplexDouble: {
return printComplex(out, v);
}
case IValue::Tag::Int:
return out << v.toInt();
case IValue::Tag::SymInt:
return out << v.toSymInt();
case IValue::Tag::SymFloat:
return out << v.toSymFloat();
case IValue::Tag::Bool:
return out << (v.toBool() ? "True" : "False");
case IValue::Tag::Tuple: {
const auto& elements = v.toTupleRef().elements();
const auto& finish = elements.size() == 1 ? ",)" : ")";
return printList(out, elements, "(", finish, formatter);
}
case IValue::Tag::String:
c10::printQuotedString(out, v.toStringRef());
return out;
case IValue::Tag::GenericList: {
return printMaybeAnnotatedList(out, *this, formatter);
}
case IValue::Tag::Device: {
std::stringstream device_stream;
device_stream << v.toDevice();
out << "torch.device(";
c10::printQuotedString(out, device_stream.str());
return out << ")";
}
case IValue::Tag::GenericDict:
return printMaybeAnnotatedDict(out, v, formatter);
case IValue::Tag::Enum: {
auto enum_holder = v.toEnumHolder();
return out << enum_holder->qualifiedClassName() << "." <<
enum_holder->name();
}
case IValue::Tag::Object: {
TORCH_INTERNAL_ASSERT(false, "repr() not defined on: ", v.tagKind(), ". Perhaps you've frozen a module with custom classes?");
}
default:
TORCH_INTERNAL_ASSERT(false, "repr() not defined on: ", v.tagKind());
}
}
bool simpleClassTypeArg(const Argument& arg, const ClassTypePtr& type) {
return arg.type() == type && !arg.kwarg_only() && !arg.default_value();
}
torch::jit::Function* checkObjectSortSchema(const c10::ClassTypePtr& t, std::stringstream& why_not) {
if (auto method = t->findMethod("__lt__")) {
const auto& lt_schema = method->getSchema();
const auto& schema_args = lt_schema.arguments();
bool error =
(schema_args.size() != 2 ||
!simpleClassTypeArg(schema_args[0], t) ||
!simpleClassTypeArg(schema_args[1], t) ||
lt_schema.returns().size() != 1 ||
lt_schema.returns()[0].type() != BoolType::get());
if (!error) {
return method;
}
}
why_not << "To sort a list of " << t->repr_str()
<< " it must define a "
<< "__lt__ method with two inputs of type "
<< t->repr_str() << " that "
<< "returns a bool";
return nullptr;
}
IValueComparator getLessThanComparator(const IValue& v) {
if (v.isTensor()) {
return [](const IValue& a, const IValue& b) {
return a.toTensor().lt(b.toTensor()).is_nonzero();
};
}
if (v.isDouble()) {
return [](const IValue& a, const IValue& b) {
return a.toDouble() < b.toDouble();
};
}
if (v.isInt()) {
return [](const IValue& a, const IValue& b) {
return a.toInt() < b.toInt();
};
}
if (v.isBool()) {
return [](const IValue& a, const IValue& b) {
return a.toBool() == false && b.toBool() == true;
};
}
if (v.isString()) {
return [](const IValue& a, const IValue& b) {
return a.toStringRef() < b.toStringRef();
};
}
if (v.isTuple()) {
const auto& elements = v.toTupleRef().elements();
size_t n = elements.size();
std::vector<IValueComparator> elements_lts;
elements_lts.reserve(n);
for (const auto i : c10::irange(n)) {
elements_lts.push_back(getLessThanComparator(elements[i]));
}
return [elements_lts=std::move(elements_lts), n](const IValue& a, const IValue& b) {
const auto& a_elements = a.toTupleRef().elements();
const auto& b_elements = b.toTupleRef().elements();
for (const auto i : c10::irange(n)) {
if (elements_lts[i](a_elements[i], b_elements[i])) {
return true;
}
if (a_elements[i] == b_elements[i]) {
continue;
}
return false;
}
// Reaching here means two tuples are equal.
return false;
};
}
if (v.isObject()) {
std::stringstream why_not;
torch::jit::Function* lt_func =
checkObjectSortSchema(v.type()->expect<ClassType>(), why_not);
if (!lt_func) {
AT_ERROR(why_not.str());
}
return [lt_func](const IValue& a, const IValue& b) {
// Quick pass to satisfy "strict weak ordering" requirement
if (a.is(b)) {
return false;
}
torch::jit::Stack sort_stack;
sort_stack.push_back(a);
sort_stack.push_back(b);
lt_func->run(sort_stack);
return torch::jit::pop(sort_stack).toBool();
};
}
AT_ERROR("IValues of type: ", v.tagKind(), " are not comparable");
}
IValueComparator getGreaterThanComparator(const IValue& v) {
auto lt = getLessThanComparator(v);
return [lt = std::move(lt)](const IValue& a, const IValue& b) {
return lt(b, a); // gt(a, b) === lt(b, a)
};
}
std::ostream& operator<<(std::ostream& out, const ivalue::EnumHolder& v) {
out << v.qualifiedClassName() << "." << v.name();
return out;
}
std::ostream& operator<<(std::ostream & out, const IValue & v) {
auto formatter = [&](std::ostream& out, const IValue& v) {
out << v;
};
switch(v.tag) {
case IValue::Tag::None:
return out << v.toNone();
case IValue::Tag::Tensor:
return out << v.toTensor();
case IValue::Tag::Storage:
return out << v.toStorage().unsafeGetStorageImpl();
case IValue::Tag::Double: {
double d = v.toDouble();
int c = std::fpclassify(d);
if (c == FP_NORMAL || c == FP_ZERO) {
int64_t i = int64_t(d);
if (double(i) == d) {
return out << i << ".";
}
}
auto orig_prec = out.precision();
return out
<< std::setprecision(std::numeric_limits<double>::max_digits10)
<< v.toDouble()
<< std::setprecision(orig_prec);
} case IValue::Tag::ComplexDouble: {
return printComplex(out, v);
} case IValue::Tag::Int:
return out << v.toInt();
case IValue::Tag::SymInt:
return out << v.toSymInt();
case IValue::Tag::SymFloat:
return out << v.toSymFloat();
case IValue::Tag::Bool:
return out << (v.toBool() ? "True" : "False");
case IValue::Tag::Tuple: {
const auto& elements = v.toTupleRef().elements();
const auto& finish = elements.size() == 1 ? ",)" : ")";
return printList(out, elements, "(", finish, formatter);
}
case IValue::Tag::String:
return out << v.toStringRef();
case IValue::Tag::Blob:
return out << *v.toBlob();
case IValue::Tag::Capsule:
return out << "Capsule";
case IValue::Tag::GenericList:
return printList(out, v.toList(), "[", "]", formatter);
case IValue::Tag::RRef:
return out << "RRef";
case IValue::Tag::Future:
return out << "Future";
case IValue::Tag::Uninitialized:
return out << "Uninitialized";
case IValue::Tag::Device:
return out << v.toDevice();
case IValue::Tag::Stream:
return out << v.toStream();
case IValue::Tag::GenericDict:
return printDict(out, v.toGenericDict(), formatter);
case IValue::Tag::PyObject: {
auto py_obj = v.toPyObject();
return out << "<PyObject at" << py_obj << ">";
}
case IValue::Tag::Generator:
return out << "Generator";
case IValue::Tag::Quantizer:
return out << "Quantizer";
case IValue::Tag::Object: {
// TODO we should attempt to call __str__ if the object defines it.
auto obj = v.toObject();
// print this out the way python would do it
return out << "<" << obj->name() << " object at " << obj.get() << ">";
}
case IValue::Tag::Enum: {
auto enum_holder = v.toEnumHolder();
return out << "Enum<" << enum_holder->unqualifiedClassName() << "." <<
enum_holder->name() << ">";
}
}
AT_ERROR("Tag not found: ", v.tagKind());
}
#undef TORCH_FORALL_TAGS
void IValue::dump() const {
std::cout << *this << "\n";
}
std::shared_ptr<ClassType> ivalue::Object::type() const {
return type_.type_->expect<ClassType>();
}
c10::intrusive_ptr<ivalue::Object> ivalue::Object::create(
ClassTypePtr classType, size_t numSlots) {
return ivalue::Object::create(
StrongTypePtr(nullptr, std::move(classType)), numSlots);
}
IValue IValue::deepcopy() const {
IValue::HashAliasedIValueMap memo;
return deepcopy(memo);
}
IValue IValue::deepcopy(
IValue::HashAliasedIValueMap& memo) const {
if (memo.count(*this)) {
return memo.at(*this);
}
IValue copy;
switch(tag) {
case IValue::Tag::Tensor:
copy = IValue(toTensor().clone());
break;
case IValue::Tag::Tuple: {
std::vector<IValue> copied_tuple;
for (const auto& e : toTupleRef().elements()) {
copied_tuple.push_back(e.deepcopy(memo));
}
copy = IValue(ivalue::Tuple::create(copied_tuple));
}
break;
case IValue::Tag::GenericList: {
auto list = toList();
auto copied_list = c10::impl::GenericList(list.elementType());
for (IValue v : list) {
copied_list.push_back(v.deepcopy(memo));
}
copy = IValue(copied_list);
}
break;
case IValue::Tag::GenericDict: {
auto dict = toGenericDict();
auto copied_dict = c10::impl::GenericDict(dict.keyType(), dict.valueType());
for (const auto& entry : dict) {
copied_dict.insert(entry.key().deepcopy(memo), entry.value().deepcopy(memo));
}
copy = IValue(copied_dict);
}
break;
case IValue::Tag::Object: {
auto class_type = type()->expect<ClassType>();
if (class_type->hasMethod("__getstate__") &&
class_type->hasMethod("__setstate__")) {
copy = ivalue::Object::create(
c10::StrongTypePtr(class_type->compilation_unit(), type()),
class_type->numAttributes());
auto state = class_type->getMethod("__getstate__")({*this});
class_type->getMethod("__setstate__")({copy, std::move(state)});
} else {
copy = IValue(toObject()->deepcopy(memo));
}
} break;
case IValue::Tag::Enum: {
auto enum_holder = toEnumHolder();
copy = IValue(c10::make_intrusive<ivalue::EnumHolder>(
enum_holder->type(),
enum_holder->name(),
enum_holder->value().deepcopy(memo)));
} break;
case IValue::Tag::String:
case IValue::Tag::None:
case IValue::Tag::Double:
case IValue::Tag::Int:
case IValue::Tag::SymInt:
case IValue::Tag::SymFloat:
case IValue::Tag::Bool:
case IValue::Tag::Device:
case IValue::Tag::Uninitialized: {
copy = *this;
} break;
default: {
AT_ERROR("Can't deepcopy IValue with tag: ", tagKind());
}
}
// NB: this doesn't work if an object contains itself, and it may
// come up in the future when we expand the object system, we will
// have a follow up PR to fix this when it becomes an issue.
if (!isAliasOf(copy)) {
memo[*this] = copy;
}
return copy;
}
void IValue::reportToTensorTypeError() const {
TORCH_CHECK(false, "Expected Tensor but got ", tagKind());
}
std::string ivalue::Object::name() const {
return type()->name()->qualifiedName();
}
IValue ivalue::Object::getAttr(const std::string& name) const {
const size_t slot = type()->getAttributeSlot(name);
return getSlot(slot);
}
void ivalue::Object::setAttr(const std::string& name, IValue v) {
const size_t slot = type()->getAttributeSlot(name);
setSlot(slot, std::move(v));
}
void ivalue::Object::unsafeRemoveAttr(const std::string& name) {
const size_t slot = type()->getAttributeSlot(name);
unsafeRemoveSlot(slot);
}
void ivalue::Object::resizeObject(size_t slot) {
AT_ASSERT(slot < type()->numAttributes());
slots_.resize(type()->numAttributes());
}
c10::intrusive_ptr<ivalue::Object> ivalue::Object::copy() const {
auto object = ivalue::Object::create(type_, type()->numAttributes());
for (const auto i : c10::irange(slots_.size())) {
object->setSlot(i, slots_[i]);
}
return object;
}
c10::intrusive_ptr<ivalue::Object> ivalue::Object::copy_to_weak_compilation_ref() const {
auto object = ivalue::Object::create(
WeakOrStrongTypePtr(type_.asWeakTypePtr()), type()->numAttributes());
for (const auto i : c10::irange(slots_.size())) {
object->setSlot(i, slots_[i]);
}
return object;
}
c10::intrusive_ptr<ivalue::Object> ivalue::Object::deepcopy() const {
IValue::HashAliasedIValueMap memo;
return deepcopy(memo);
}
c10::intrusive_ptr<ivalue::Object> ivalue::Object::deepcopy(IValue::HashAliasedIValueMap& memo) const {
auto cu = type_.cu_;
auto object = ivalue::Object::create(WeakOrStrongTypePtr(type_.cu_, type_.type_), type()->numAttributes());
for (const auto i : c10::irange(slots_.size())) {
if (*slots_[i].type() == *c10::TypeFactory::get<CapsuleType>()) {
// If we've gotten here, it means that we have *not* copied this
// class via __getstate__ and __setstate__. That fact and the
// fact that we have a Capsule attribute mean that this is a
// custom C++ class without serialization methods defined.