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export_bytecode.cpp
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export_bytecode.cpp
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#include <torch/csrc/jit/serialization/export_bytecode.h>
#include <utility>
#include <torch/csrc/jit/operator_upgraders/version_map.h>
#include <torch/csrc/jit/runtime/instruction.h>
#include <torch/csrc/jit/serialization/export.h>
#include <c10/util/Exception.h>
#include <torch/csrc/jit/api/function_impl.h>
#include <torch/csrc/jit/api/method.h>
#include <torch/csrc/jit/backends/backend_debug_handler.h>
#include <torch/csrc/jit/backends/backend_debug_info.h>
#include <torch/csrc/jit/frontend/source_range.h>
#include <torch/csrc/jit/ir/attributes.h>
#include <torch/csrc/jit/ir/ir.h>
#include <torch/csrc/jit/ir/type_hashing.h>
#include <torch/csrc/jit/mobile/function.h>
#include <torch/csrc/jit/mobile/interpreter.h>
#include <torch/csrc/jit/mobile/method.h>
#include <torch/csrc/jit/mobile/module.h>
#include <torch/csrc/jit/passes/inliner.h>
#include <torch/csrc/jit/serialization/callstack_debug_info_serialization.h>
#include <torch/csrc/jit/serialization/import_export_constants.h>
#include <torch/csrc/jit/serialization/import_export_functions.h>
#include <torch/csrc/jit/serialization/import_export_helpers.h>
#include <torch/csrc/jit/serialization/pickle.h>
#include <torch/csrc/jit/serialization/python_print.h>
#include <torch/csrc/jit/serialization/source_range_serialization.h>
#include <torch/csrc/jit/serialization/type_name_uniquer.h>
#include <caffe2/serialize/inline_container.h>
namespace torch::jit {
std::vector<Method> gatherGetSetStates(ObjectPtr obj) {
std::vector<Method> methods;
// Use DFS on IValue's to traverse dependencies of module._ivalue and
// add all setstate/getstates to initial stack.
std::vector<ObjectPtr> ivalue_stack;
ivalue_stack.emplace_back(obj);
while (!ivalue_stack.empty()) {
ObjectPtr cur = ivalue_stack.back();
ivalue_stack.pop_back();
auto type = cur->type();
Function* setstate = type->findMethod("__setstate__");
Function* getstate = type->findMethod("__getstate__");
if (getstate && setstate) {
if (setstate->isGraphFunction()) {
methods.emplace_back(cur, setstate);
}
if (getstate->isGraphFunction()) {
methods.emplace_back(cur, getstate);
}
} else {
for (size_t i = 0, n = type->numAttributes(); i < n; ++i) {
IValue field = cur->getSlot(i);
if (field.isObject()) {
ivalue_stack.emplace_back(field.toObject());
}
}
}
}
return methods;
}
std::vector<Method> findAllDependentFunctions(
const Module& module,
Graph& graph) {
std::vector<Method> methods;
std::unordered_set<c10::string_view> called_method_names;
auto nodes = findAllNodes(graph, c10::prim::CallMethod, true);
for (Node* node : nodes) {
if (auto iface = node->input(0)->type()->castRaw<InterfaceType>()) {
const FunctionSchema* schema = iface->getMethod(node->s(attr::name));
called_method_names.insert(schema->name());
}
}
for (const auto& submodule : module.modules()) {
for (const auto& m : submodule.get_methods()) {
if (called_method_names.find(m.function().qualname().name()) !=
called_method_names.end()) {
methods.emplace_back(m);
}
}
}
return methods;
}
// NOTE: order of functions returned will be:
// 1. functions originated from the methods passed in will be first
// 2. All the dependent functions will come afterwards.
// This order is meaningful because currently mobile Module looks up
// methods with linear search.
std::vector<std::unique_ptr<GraphFunction>> inlineFunctions(
const std::vector<Method>& initial_methods,
bool incl_dependent_functions) {
std::set<std::pair<std::string, Function*>> visited;
std::deque<Method> stack;
std::copy(
initial_methods.begin(),
initial_methods.end(),
std::back_inserter(stack));
std::vector<std::unique_ptr<GraphFunction>> inlined_functions;
while (!stack.empty()) {
Method cur = stack.front();
stack.pop_front();
auto tup = std::make_pair(
cur.owner()._ivalue()->type()->name()->qualifiedName(),
&cur.function());
if (visited.find(tup) != visited.end()) {
continue;
}
visited.insert(tup);
const auto& f = toGraphFunction(cur.function());
auto graph = f.graph()->copyUnique();
Inline(*graph);
c10::QualifiedName qn(*cur.owner()._ivalue()->type()->name(), f.name());
if (incl_dependent_functions) {
std::vector<Method> dependent_methods =
findAllDependentFunctions(cur.owner(), *graph);
std::copy(
dependent_methods.begin(),
dependent_methods.end(),
std::back_inserter(stack));
}
auto inlined_func = std::make_unique<GraphFunction>(
qn, std::move(graph), f.function_creator());
inlined_func->setSchema(f.getSchema());
inlined_functions.emplace_back(std::move(inlined_func));
}
return inlined_functions;
}
mobile::Code compileGraphToMobileCode(
const std::string& name,
const std::shared_ptr<Graph>& graph,
const CompilationOptions& compilation_options,
BackendDebugInfoRecorder& debug_info_recorder) {
MobileCode code(
graph,
name,
compilation_options.enable_default_value_for_unspecified_arg,
compilation_options.enable_default_args_before_out_args,
compilation_options.enable_emit_promoted_ops);
mobile::Code mobile_code;
// operator names
std::vector<std::string> method_names;
std::vector<int64_t> op_debug_handles;
int next_new_op_index = 0;
auto op_to_specified_args = code.op_to_num_specified_args();
for (size_t i = 0; i < code.instructions().size(); ++i) {
Instruction ins = code.instructions()[i];
if ((ins.op == OP || ins.op == OPN) && ins.X == next_new_op_index) {
// Found a new op (assumes new operators ordered by ascending ins.X)
auto node = code.instructions_source()[i];
const c10::OperatorName& opname = node->schema().operator_name();
auto unique_name = c10::toString(opname);
// For operator with vararg, adding default arguments would be confusing
// and is not allowed. For an operator with num_args = -1, it means the
// number of arguments is not available for this operator, we don't do any
// backward compatibility adaptation at runtime.
c10::optional<int> num_args = c10::nullopt;
auto it = op_to_specified_args.find(unique_name);
if (it != op_to_specified_args.end()) {
num_args = it->second;
}
mobile_code.operator_input_sizes_.emplace_back(num_args.value_or(-1));
mobile_code.op_names_.emplace_back(opname);
auto func = mobile::makeOperatorFunction(opname, num_args);
TORCH_INTERNAL_ASSERT(
func.has_value(),
"Operator with name: ",
toString(opname),
" not found");
mobile_code.operators_.emplace_back(*func);
next_new_op_index++;
}
// CALL nodes at this point represent built-in (i.e. non-Graph)
// functions that were not inlined. Here we convert the CALL
// instructions for these functions into INTERFACE_CALL instructions
// s.t. at runtime, we will look up the Function* on the Type of the
// 0th argument in the stack and call that directly.
if (ins.op == CALL) {
auto node = code.instructions_source()[i];
if (node->kind() == prim::CallMethod) {
// NB: replacing instruction
auto method_name_idx =
code.constant_table().size() + method_names.size();
method_names.emplace_back(node->s(attr::name));
ins = Instruction{
INTERFACE_CALL,
static_cast<int32_t>(method_name_idx),
static_cast<uint16_t>(node->inputs().size())};
} else {
TORCH_INTERNAL_ASSERT(
false, "Unsupported node kind on CALL opcode for mobile");
}
} else if (ins.op == RET) {
auto node = code.instructions_source()[i];
for (const auto& input : node->inputs()) {
const auto& input_type = input->type();
if (input_type->kind() == TypeKind::ListType ||
input_type->kind() == TypeKind::DictType) {
for (const TypePtr& element_type : input_type->containedTypes()) {
TORCH_CHECK(
element_type->kind() != TypeKind::ClassType,
"Returning a list or dictionary with pytorch class type ",
"is not supported in mobile module "
"(List[Foo] or Dict[int, Foo] for class Foo(torch.nn.Module)). "
"Workaround: instead of using pytorch class as their element type, ",
"use a combination of list, dictionary, and single types.");
}
}
}
} else {
TORCH_CHECK(
isOpSupportedInMobile(ins.op),
toString(ins.op),
" is not supported in mobile module.");
}
auto node = code.instructions_source()[i];
int64_t debug_handle = debug_info_recorder.getNextDebugHandle(node);
// Note 1-to-1 correspondence between instructions and debug handles
mobile_code.instructions_.emplace_back(ins);
mobile_code.debug_handles_.emplace_back(debug_handle);
}
// copy constants
mobile_code.constants_ = code.constant_table();
// Make a copy of the constants and append the method names
// that we emitted for the converted INTERFACE_CALL nodes above.
for (auto& method_name : method_names) {
mobile_code.constants_.emplace_back(method_name);
}
mobile_code.types_ = code.type_table();
mobile_code.register_size_ = code.register_size();
return mobile_code;
}
std::unique_ptr<mobile::Function> convertJitFunctionToMobileFunction(
const GraphFunction& function,
const CompilationOptions& options) {
BackendDebugInfoRecorder debug_handle;
auto mobileCode = compileGraphToMobileCode(
function.name(), function.graph(), options, debug_handle);
const auto& schema = function.getSchema();
return std::make_unique<mobile::Function>(
function.qualname(), std::move(mobileCode), schema);
}
IValue convertMobileFunctionToCodeTable(
const mobile::Function& func,
const CompilationOptions& compilation_options) {
auto code = func.get_code();
std::vector<IValue> instructions;
instructions.reserve(code.instructions_.size());
for (Instruction ins : code.instructions_) {
instructions.emplace_back(to_tuple({toString(ins.op), ins.X, ins.N}));
}
std::vector<IValue> operators;
operators.reserve(code.op_names_.size());
for (unsigned i = 0; i < code.op_names_.size(); ++i) {
const auto& opname = code.op_names_[i];
const int size = code.operator_input_sizes_[i];
if (compilation_options.enable_default_value_for_unspecified_arg) {
operators.emplace_back(to_tuple({opname.name, opname.overload_name}));
} else {
operators.emplace_back(
to_tuple({opname.name, opname.overload_name, size}));
}
}
std::vector<IValue> types;
for (const TypePtr& t : code.types_) {
std::string type_str = t->annotation_str();
types.emplace_back(type_str);
}
auto register_size = static_cast<int>(code.register_size_);
auto codeTable = Table(
{{"instructions", to_tuple(instructions)},
{"operators", to_tuple(operators)},
{"constants", to_tuple(code.constants_)},
{"types", to_tuple(types)},
{"register_size", register_size}});
return codeTable;
}
void checkSchema(const c10::FunctionSchema& schema) {
TORCH_CHECK(
schema.overload_name().empty(), // @TODO: is this check correct?
"Overloads are not supported in mobile modules.");
TORCH_CHECK(
!schema.is_vararg(), "Python *args are not supported in mobile modules.");
TORCH_CHECK(
!schema.is_varret(),
"A variable number of return values is not supported in mobile modules.");
}
bool isLoweredModule(const Module& m) {
c10::QualifiedName type_name;
if (m.type()->name()) {
type_name = m.type()->name().value();
}
bool isLoweredModule = false;
for (const auto& atom : type_name.atoms()) {
if (atom == "LoweredModule") {
isLoweredModule = true;
break;
}
}
return isLoweredModule;
}
// Check if the global static map of backend debug info
// contains debug info for this module and any of its children.
// If so combine all the maps together and return one.
void getBackendDebugInfoMap(
const Module& m,
BackendDebugInfoMapType& debug_map) {
if (isLoweredModule(m)) {
auto backend_debug_info =
m.attr("__backend_debug_info").toCustomClass<PyTorchBackendDebugInfo>();
const auto& map = backend_debug_info->getDebugInfoMap();
if (map) {
debug_map.insert(map.value().begin(), map.value().end());
}
}
for (const auto& c : m.children()) {
getBackendDebugInfoMap(c, debug_map);
}
}
uint64_t get_min_operator_version_from_version_map(
const mobile::Module& module) {
uint64_t min_version = caffe2::serialize::kMinSupportedFileFormatVersion;
for (const auto& func : module.compilation_unit().methods()) {
for (const auto& op_name : func->get_code().op_names_) {
auto schema_name = op_name.overload_name.empty()
? op_name.name
: op_name.name + "." + op_name.overload_name;
auto version_entry = get_operator_version_map().find(schema_name);
if (version_entry != get_operator_version_map().end()) {
const auto& entry = version_entry->second;
min_version = std::max(
min_version, uint64_t(entry[entry.size() - 1].bumped_at_version));
}
}
}
return min_version;
}
mobile::Module jitModuleToMobile(
const Module& module,
const CompilationOptions& options) {
std::shared_ptr<mobile::CompilationUnit> mcu =
std::make_shared<mobile::CompilationUnit>();
BackendDebugInfoRecorder debug_info_recorder;
std::vector<Method> methods_to_export = module.get_methods();
std::vector<Method> getsetstates = gatherGetSetStates(module._ivalue());
std::copy(
getsetstates.begin(),
getsetstates.end(),
std::back_inserter(methods_to_export));
for (const auto& func :
inlineFunctions(methods_to_export, options.incl_interface_call)) {
auto mobile_code = compileGraphToMobileCode(
func->name(), func->graph(), options, debug_info_recorder);
const auto& schema = func->getSchema();
checkSchema(schema);
auto mobile_func = std::make_unique<mobile::Function>(
func->qualname(), std::move(mobile_code), schema);
mcu->register_function(std::move(mobile_func));
}
mobile::Module m(module._ivalue(), mcu);
m.setHasDebugHandles(true);
BackendDebugInfoMapType backend_debug_info_map;
getBackendDebugInfoMap(module, backend_debug_info_map);
auto debug_handle_cs_ptr_map = debug_info_recorder.stopRecording();
debug_handle_cs_ptr_map.insert(
backend_debug_info_map.begin(), backend_debug_info_map.end());
m.setDebugTable(MobileDebugTable(
debug_handle_cs_ptr_map.begin(), debug_handle_cs_ptr_map.end()));
m.set_min_operator_version(get_min_operator_version_from_version_map(m));
m.set_bytecode_version(options.model_version);
return m;
}
} // namespace torch::jit