video-libs / opencv /sources /modules /gapi /src /compiler /gmodelbuilder.cpp

ffmpeg (v6.0/v7.x), gensim, numpy, opencv

be94e5d verified 7 months ago

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	// This file is part of OpenCV project.
	// It is subject to the license terms in the LICENSE file found in the top-level directory
	// of this distribution and at http://opencv.org/license.html.
	//
	// Copyright (C) 2018-2020 Intel Corporation


	////////////////////////////////////////////////////////////////////////////////
	//
	// FIXME: "I personally hate this file"
	// - Dmitry
	//
	////////////////////////////////////////////////////////////////////////////////
	#include "precomp.hpp"

	#include <utility> // tuple
	#include <stack> // stack
	#include <vector> // vector
	#include <unordered_set> // unordered_set
	#include <type_traits> // is_same

	#include <ade/util/zip_range.hpp> // util::indexed

	#include "api/gorigin.hpp"
	#include "api/gproto_priv.hpp" // descriptor_of and other GProtoArg-related
	#include "api/gcall_priv.hpp"
	#include "api/gnode_priv.hpp"

	#include "compiler/gmodelbuilder.hpp"
	#include "compiler/gmodel_priv.hpp"

	namespace {


	// TODO: move to helpers and cover with internal tests?
	template<typename T> struct GVisited
	{
	typedef std::unordered_set<T> VTs;

	bool visited(const T& t) const { return m_visited.find(t) != m_visited.end(); }
	void visit (const T& t) { m_visited.insert(t); }
	const VTs& visited() const { return m_visited; }

	private:
	VTs m_visited;
	};

	template<typename T, typename U = T> struct GVisitedTracker: protected GVisited<T>
	{
	typedef std::vector<U> TUs;

	void visit(const T& t, const U& u) { GVisited<T>::visit(t); m_tracked.push_back(u); }
	const TUs& tracked() const { return m_tracked; }
	using GVisited<T>::visited;

	private:
	TUs m_tracked;
	};

	} // namespace

	cv::gimpl::Unrolled cv::gimpl::unrollExpr(const GProtoArgs &ins,
	const GProtoArgs &outs)
	{
	// FIXME: Who's gonna check if ins/outs are not EMPTY?
	// FIXME: operator== for GObjects? (test if the same object or not)
	using GObjId = const cv::GOrigin*;

	GVisitedTracker<const GNode::Priv*, cv::GNode> ops;
	GVisited<GObjId> reached_sources;
	cv::GOriginSet origins;

	// Cache input argument objects for a faster look-up
	// While the only reliable way to identify a Data object is Origin
	// (multiple data objects may refer to the same Origin as result of
	// multuple yield() calls), input objects can be uniquely identified
	// by its `priv` address. Here we rely on this to verify if the expression
	// we unroll actually matches the protocol specified to us by user.
	std::unordered_set<GObjId> in_objs_p;
	for (const auto& in_obj : ins)
	{
	// Objects are guaranteed to remain alive while this method
	// is working, so it is safe to keep pointers here and below
	in_objs_p.insert(&proto::origin_of(in_obj));
	}

	// Recursive expression traversal
	std::stack<cv::GProtoArg> data_objs(std::deque<cv::GProtoArg>(outs.begin(), outs.end()));
	while (!data_objs.empty())
	{
	const auto obj = data_objs.top();
	const auto &obj_p = proto::origin_of(obj);
	data_objs.pop();

	const auto &origin = obj_p;
	origins.insert(origin); // TODO: Put Object description here later on

	// If this Object is listed in the protocol, don't dive deeper (even
	// if it is in fact a result of operation). Our computation is
	// bounded by this data slot, so terminate this recursion path early.
	if (in_objs_p.find(&obj_p) != in_objs_p.end())
	{
	reached_sources.visit(&obj_p);
	continue;
	}

	const cv::GNode &node = origin.node;
	switch (node.shape())
	{
	case cv::GNode::NodeShape::EMPTY:
	// TODO: Own exception type?
	util::throw_error(std::logic_error("Empty node reached!"));
	break;

	case cv::GNode::NodeShape::PARAM:
	case cv::GNode::NodeShape::CONST_BOUNDED:
	// No preceding operation to this data object - so the data object is either a GComputation
	// parameter or a constant (compile-time) value
	// Record it to check if protocol matches expression tree later
	if (!reached_sources.visited(&obj_p))
	reached_sources.visit(&obj_p);
	break;

	case cv::GNode::NodeShape::CALL:
	if (!ops.visited(&node.priv()))
	{
	// This operation hasn't been visited yet - mark it so,
	// then add its operands to stack to continue recursion.
	ops.visit(&node.priv(), node);

	const cv::GCall& call = origin.node.call();
	const cv::GCall::Priv& call_p = call.priv();

	// Put the outputs object description of the node
	// so that they are not lost if they are not consumed by other operations
	GAPI_Assert(call_p.m_k.outCtors.size() == call_p.m_k.outShapes.size());
	for (const auto it : ade::util::indexed(ade::util::zip(call_p.m_k.outShapes,
	call_p.m_k.outCtors,
	call_p.m_k.outKinds)))
	{
	auto port = ade::util::index(it);
	auto &val = ade::util::value(it);
	auto shape = std::get<0>(val);
	auto ctor = std::get<1>(val);
	auto kind = std::get<2>(val);
	// NB: Probably this fixes all other "missing host ctor"
	// problems.
	// TODO: Clean-up the old workarounds if it really is.
	GOrigin org {shape, node, port, std::move(ctor), kind};
	origins.insert(org);
	}

	for (const auto &arg : call_p.m_args)
	{
	if (proto::is_dynamic(arg))
	{
	data_objs.push(proto::rewrap(arg)); // Dive deeper
	}
	}
	}
	break;

	default:
	// Unsupported node shape
	GAPI_Error("InternalError");
	break;
	}
	}

	// Check if protocol mentions data_objs which weren't reached during traversal
	const auto missing_reached_sources = [&reached_sources](GObjId p) {
	return reached_sources.visited().find(p) == reached_sources.visited().end();
	};
	if (ade::util::any_of(in_objs_p, missing_reached_sources))
	{
	// TODO: Own exception type or a return code?
	util::throw_error(std::logic_error("Data object listed in Protocol "
	"wasn\'t reached during unroll"));
	}

	// Check if there endpoint (parameter) data_objs which are not listed in protocol
	const auto missing_in_proto = [&in_objs_p](GObjId p) {
	return p->node.shape() != cv::GNode::NodeShape::CONST_BOUNDED &&
	in_objs_p.find(p) == in_objs_p.end();
	};
	if (ade::util::any_of(reached_sources.visited(), missing_in_proto))
	{
	// TODO: Own exception type or a return code?
	util::throw_error(std::logic_error("Data object reached during unroll "
	"wasn\'t found in Protocol"));
	}

	return cv::gimpl::Unrolled{ops.tracked(), origins};
	}


	cv::gimpl::GModelBuilder::GModelBuilder(ade::Graph &g)
	: m_g(g), m_gm(g)
	{
	}

	cv::gimpl::GModelBuilder::ProtoSlots
	cv::gimpl::GModelBuilder::put(const GProtoArgs &ins, const GProtoArgs &outs)
	{
	const auto unrolled = cv::gimpl::unrollExpr(ins, outs);

	// First, put all operations and its arguments into graph.
	for (const auto &op_expr_node : unrolled.all_ops)
	{
	GAPI_Assert(op_expr_node.shape() == GNode::NodeShape::CALL);
	const GCall& call = op_expr_node.call();
	const GCall::Priv& call_p = call.priv();
	ade::NodeHandle call_h = put_OpNode(op_expr_node);

	for (const auto it : ade::util::indexed(call_p.m_args))
	{
	const auto in_port = ade::util::index(it);
	const auto& in_arg = ade::util::value(it);

	if (proto::is_dynamic(in_arg))
	{
	ade::NodeHandle data_h = put_DataNode(proto::origin_of(in_arg));
	cv::gimpl::GModel::linkIn(m_gm, call_h, data_h, in_port);
	}
	}
	}

	// Then iterate via all "origins", instantiate (if not yet) Data graph nodes
	// and connect these nodes with their producers in graph
	for (const auto &origin : unrolled.all_data)
	{
	const cv::GNode& prod = origin.node;
	GAPI_Assert(prod.shape() != cv::GNode::NodeShape::EMPTY);

	ade::NodeHandle data_h = put_DataNode(origin);
	if (prod.shape() == cv::GNode::NodeShape::CALL)
	{
	ade::NodeHandle call_h = put_OpNode(prod);
	cv::gimpl::GModel::linkOut(m_gm, call_h, data_h, origin.port);
	}
	}

	// Mark graph data nodes as INPUTs and OUTPUTs respectively (according to the protocol)
	for (const auto &arg : ins)
	{
	ade::NodeHandle nh = put_DataNode(proto::origin_of(arg));
	m_gm.metadata(nh).get<Data>().storage = Data::Storage::INPUT;
	}
	for (const auto &arg : outs)
	{
	ade::NodeHandle nh = put_DataNode(proto::origin_of(arg));
	m_gm.metadata(nh).get<Data>().storage = Data::Storage::OUTPUT;
	}

	// And, finally, store data object layout in meta
	GModel::LayoutGraph lg(m_g);
	lg.metadata().set(Layout{m_graph_data});

	// After graph is generated, specify which data objects are actually
	// computation entry/exit points.
	using NodeDescr = std::pair<std::vector<RcDesc>,
	std::vector<ade::NodeHandle> >;

	const auto get_proto_slots = [&](const GProtoArgs &proto) -> NodeDescr
	{
	NodeDescr slots;

	slots.first.reserve(proto.size());
	slots.second.reserve(proto.size());

	for (const auto &arg : proto)
	{
	ade::NodeHandle nh = put_DataNode(proto::origin_of(arg));
	const auto &desc = m_gm.metadata(nh).get<Data>();
	//These extra empty {} are to please GCC (-Wmissing-field-initializers)
	slots.first.push_back(RcDesc{desc.rc, desc.shape, {}});
	slots.second.push_back(nh);
	}
	return slots;
	};

	auto in_slots = get_proto_slots(ins);
	auto out_slots = get_proto_slots(outs);
	return ProtoSlots{in_slots.first, out_slots.first,
	in_slots.second, out_slots.second};
	}

	ade::NodeHandle cv::gimpl::GModelBuilder::put_OpNode(const cv::GNode &node)
	{
	const auto& node_p = node.priv();
	const auto it = m_graph_ops.find(&node_p);
	if (it == m_graph_ops.end())
	{
	GAPI_Assert(node.shape() == GNode::NodeShape::CALL);
	const auto &call_p = node.call().priv();
	auto nh = cv::gimpl::GModel::mkOpNode(m_gm, call_p.m_k, call_p.m_args, call_p.m_params, node_p.m_island);
	m_graph_ops[&node_p] = nh;
	return nh;
	}
	else return it->second;
	}

	// FIXME: rename to get_DataNode (and same for Op)
	ade::NodeHandle cv::gimpl::GModelBuilder::put_DataNode(const GOrigin &origin)
	{
	const auto it = m_graph_data.find(origin);
	if (it == m_graph_data.end())
	{
	auto nh = cv::gimpl::GModel::mkDataNode(m_gm, origin);
	m_graph_data[origin] = nh;
	return nh;
	}
	else
	{
	// FIXME: One of the ugliest workarounds ever
	if (it->first.ctor.index() == it->first.ctor.index_of<cv::util::monostate>()
	&& origin.ctor.index() != origin.ctor.index_of<cv::util::monostate>()) {
	// meanwhile update existing object
	m_gm.metadata(it->second).get<Data>().ctor = origin.ctor;
	}
	return it->second;
	}
	}