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path: root/src/ipa/libipa/module.h
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/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
 * Copyright (C) 2022, Ideas On Board
 *
 * module.h - IPA module
 */

#pragma once

#include <list>
#include <memory>
#include <string>
#include <vector>

#include <libcamera/base/log.h>
#include <libcamera/base/utils.h>

#include "libcamera/internal/yaml_parser.h"

#include "algorithm.h"

namespace libcamera {

LOG_DECLARE_CATEGORY(IPAModuleAlgo)

namespace ipa {

template<typename _Context, typename _FrameContext, typename _Config,
	 typename _Params, typename _Stats>
class Module : public Loggable
{
public:
	using Context = _Context;
	using FrameContext = _FrameContext;
	using Config = _Config;
	using Params = _Params;
	using Stats = _Stats;

	virtual ~Module() {}

	const std::list<std::unique_ptr<Algorithm<Module>>> &algorithms() const
	{
		return algorithms_;
	}

	int createAlgorithms(Context &context, const YamlObject &algorithms)
	{
		const auto &list = algorithms.asList();

		for (const auto &[i, algo] : utils::enumerate(list)) {
			if (!algo.isDictionary()) {
				LOG(IPAModuleAlgo, Error)
					<< "Invalid YAML syntax for algorithm " << i;
				algorithms_.clear();
				return -EINVAL;
			}

			int ret = createAlgorithm(context, algo);
			if (ret) {
				algorithms_.clear();
				return ret;
			}
		}

		return 0;
	}

	static void registerAlgorithm(AlgorithmFactoryBase<Module> *factory)
	{
		factories().push_back(factory);
	}

private:
	int createAlgorithm(Context &context, const YamlObject &data)
	{
		const auto &[name, algoData] = *data.asDict().begin();
		std::unique_ptr<Algorithm<Module>> algo = createAlgorithm(name);
		if (!algo) {
			LOG(IPAModuleAlgo, Error)
				<< "Algorithm '" << name << "' not found";
			return -EINVAL;
		}

		int ret = algo->init(context, algoData);
		if (ret) {
			LOG(IPAModuleAlgo, Error)
				<< "Algorithm '" << name << "' failed to initialize";
			return ret;
		}

		LOG(IPAModuleAlgo, Debug)
			<< "Instantiated algorithm '" << name << "'";

		algorithms_.push_back(std::move(algo));
		return 0;
	}

	static std::unique_ptr<Algorithm<Module>> createAlgorithm(const std::string &name)
	{
		for (const AlgorithmFactoryBase<Module> *factory : factories()) {
			if (factory->name() == name)
				return factory->create();
		}

		return nullptr;
	}

	static std::vector<AlgorithmFactoryBase<Module> *> &factories()
	{
		/*
		 * The static factories map is defined inside the function to ensure
		 * it gets initialized on first use, without any dependency on
		 * link order.
		 */
		static std::vector<AlgorithmFactoryBase<Module> *> factories;
		return factories;
	}

	std::list<std::unique_ptr<Algorithm<Module>>> algorithms_;
};

} /* namespace ipa */

} /* namespace libcamera */
an class="hl opt">) { width = (width + hAlignment - 1) / hAlignment * hAlignment; height = (height + vAlignment - 1) / vAlignment * vAlignment; return *this; } Size &boundTo(const Size &bound) { width = std::min(width, bound.width); height = std::min(height, bound.height); return *this; } Size &expandTo(const Size &expand) { width = std::max(width, expand.width); height = std::max(height, expand.height); return *this; } Size &growBy(const Size &margins) { width += margins.width; height += margins.height; return *this; } Size &shrinkBy(const Size &margins) { width = width > margins.width ? width - margins.width : 0; height = height > margins.height ? height - margins.height : 0; return *this; } __nodiscard constexpr Size alignedDownTo(unsigned int hAlignment, unsigned int vAlignment) const { return { width / hAlignment * hAlignment, height / vAlignment * vAlignment }; } __nodiscard constexpr Size alignedUpTo(unsigned int hAlignment, unsigned int vAlignment) const { return { (width + hAlignment - 1) / hAlignment * hAlignment, (height + vAlignment - 1) / vAlignment * vAlignment }; } __nodiscard constexpr Size boundedTo(const Size &bound) const { return { std::min(width, bound.width), std::min(height, bound.height) }; } __nodiscard constexpr Size expandedTo(const Size &expand) const { return { std::max(width, expand.width), std::max(height, expand.height) }; } __nodiscard constexpr Size grownBy(const Size &margins) const { return { width + margins.width, height + margins.height }; } __nodiscard constexpr Size shrunkBy(const Size &margins) const { return { width > margins.width ? width - margins.width : 0, height > margins.height ? height - margins.height : 0 }; } __nodiscard Size boundedToAspectRatio(const Size &ratio) const; __nodiscard Size expandedToAspectRatio(const Size &ratio) const; __nodiscard Rectangle centeredTo(const Point &center) const; Size operator*(float factor) const; Size operator/(float factor) const; Size &operator*=(float factor); Size &operator/=(float factor); }; bool operator==(const Size &lhs, const Size &rhs); bool operator<(const Size &lhs, const Size &rhs); static inline bool operator!=(const Size &lhs, const Size &rhs) { return !(lhs == rhs); } static inline bool operator<=(const Size &lhs, const Size &rhs) { return lhs < rhs || lhs == rhs; } static inline bool operator>(const Size &lhs, const Size &rhs) { return !(lhs <= rhs); } static inline bool operator>=(const Size &lhs, const Size &rhs) { return !(lhs < rhs); } class SizeRange { public: SizeRange() : hStep(0), vStep(0) { } SizeRange(const Size &size) : min(size), max(size), hStep(1), vStep(1) { } SizeRange(const Size &minSize, const Size &maxSize) : min(minSize), max(maxSize), hStep(1), vStep(1) { } SizeRange(const Size &minSize, const Size &maxSize, unsigned int hstep, unsigned int vstep) : min(minSize), max(maxSize), hStep(hstep), vStep(vstep) { } bool contains(const Size &size) const; std::string toString() const; Size min; Size max; unsigned int hStep; unsigned int vStep; }; bool operator==(const SizeRange &lhs, const SizeRange &rhs); static inline bool operator!=(const SizeRange &lhs, const SizeRange &rhs) { return !(lhs == rhs); } class Rectangle { public: constexpr Rectangle() : Rectangle(0, 0, 0, 0) { } constexpr Rectangle(int xpos, int ypos, const Size &size) : x(xpos), y(ypos), width(size.width), height(size.height) { } constexpr Rectangle(int xpos, int ypos, unsigned int w, unsigned int h) : x(xpos), y(ypos), width(w), height(h) { } constexpr explicit Rectangle(const Size &size) : x(0), y(0), width(size.width), height(size.height) { } int x; int y; unsigned int width; unsigned int height; bool isNull() const { return !width && !height; } const std::string toString() const; Point center() const; Size size() const { return { width, height }; } Point topLeft() const { return { x, y }; } Rectangle &scaleBy(const Size &numerator, const Size &denominator); Rectangle &translateBy(const Point &point); __nodiscard Rectangle boundedTo(const Rectangle &bound) const; __nodiscard Rectangle enclosedIn(const Rectangle &boundary) const; __nodiscard Rectangle scaledBy(const Size &numerator, const Size &denominator) const; __nodiscard Rectangle translatedBy(const Point &point) const; }; bool operator==(const Rectangle &lhs, const Rectangle &rhs); static inline bool operator!=(const Rectangle &lhs, const Rectangle &rhs) { return !(lhs == rhs); } } /* namespace libcamera */