rtspTransmit/includes/rtcp/rtc/nalunit.hpp

/**
 * Copyright (c) 2020 Filip Klembara (in2core)
 *
 * This Source Code Form is subject to the terms of the Mozilla Public
 * License, v. 2.0. If a copy of the MPL was not distributed with this
 * file, You can obtain one at https://mozilla.org/MPL/2.0/.
 */

#ifndef RTC_NAL_UNIT_H
#define RTC_NAL_UNIT_H

#if RTC_ENABLE_MEDIA

#include "common.hpp"

#include <cassert>

namespace rtc {

#pragma pack(push, 1)

/// Nalu header
struct RTC_CPP_EXPORT NalUnitHeader {
	uint8_t _first = 0;

	bool forbiddenBit() const { return _first >> 7; }
	uint8_t nri() const { return _first >> 5 & 0x03; }
	uint8_t idc() const { return _first & 0x60; }
	uint8_t unitType() const { return _first & 0x1F; }

	void setForbiddenBit(bool isSet) { _first = (_first & 0x7F) | (isSet << 7); }
	void setNRI(uint8_t nri) { _first = (_first & 0x9F) | ((nri & 0x03) << 5); }
	void setUnitType(uint8_t type) { _first = (_first & 0xE0) | (type & 0x1F); }
};

/// Nalu fragment header
struct RTC_CPP_EXPORT NalUnitFragmentHeader {
	uint8_t _first = 0;

	bool isStart() const { return _first >> 7; }
	bool reservedBit6() const { return (_first >> 5) & 0x01; }
	bool isEnd() const { return (_first >> 6) & 0x01; }
	uint8_t unitType() const { return _first & 0x1F; }

	void setStart(bool isSet) { _first = (_first & 0x7F) | (isSet << 7); }
	void setEnd(bool isSet) { _first = (_first & 0xBF) | (isSet << 6); }
	void setReservedBit6(bool isSet) { _first = (_first & 0xDF) | (isSet << 5); }
	void setUnitType(uint8_t type) { _first = (_first & 0xE0) | (type & 0x1F); }
};

#pragma pack(pop)

enum NalUnitStartSequenceMatch {
	NUSM_noMatch,
	NUSM_firstZero,
	NUSM_secondZero,
	NUSM_thirdZero,
	NUSM_shortMatch,
	NUSM_longMatch
};

static const size_t H264_NAL_HEADER_SIZE = 1;
static const size_t H265_NAL_HEADER_SIZE = 2;
/// Nal unit
struct RTC_CPP_EXPORT NalUnit : binary {
	enum class Type { H264, H265 };

	NalUnit(const NalUnit &unit) = default;
	NalUnit(size_t size, bool includingHeader = true, Type type = Type::H264)
	    : binary(size + (includingHeader
	                         ? 0
	                         : (type == Type::H264 ? H264_NAL_HEADER_SIZE : H265_NAL_HEADER_SIZE))) {}
	NalUnit(binary &&data) : binary(std::move(data)) {}
	NalUnit(Type type = Type::H264)
	    : binary(type == Type::H264 ? H264_NAL_HEADER_SIZE : H265_NAL_HEADER_SIZE) {}
	template <typename Iterator> NalUnit(Iterator begin_, Iterator end_) : binary(begin_, end_) {}

	bool forbiddenBit() const { return header()->forbiddenBit(); }
	uint8_t nri() const { return header()->nri(); }
	uint8_t unitType() const { return header()->unitType(); }

	binary payload() const {
		assert(size() >= 1);
		return {begin() + 1, end()};
	}

	void setForbiddenBit(bool isSet) { header()->setForbiddenBit(isSet); }
	void setNRI(uint8_t nri) { header()->setNRI(nri); }
	void setUnitType(uint8_t type) { header()->setUnitType(type); }

	void setPayload(binary payload) {
		assert(size() >= 1);
		erase(begin() + 1, end());
		insert(end(), payload.begin(), payload.end());
	}

	/// NAL unit separator
	enum class Separator {
		Length = RTC_NAL_SEPARATOR_LENGTH, // first 4 bytes are NAL unit length
		LongStartSequence = RTC_NAL_SEPARATOR_LONG_START_SEQUENCE,   // 0x00, 0x00, 0x00, 0x01
		ShortStartSequence = RTC_NAL_SEPARATOR_SHORT_START_SEQUENCE, // 0x00, 0x00, 0x01
		StartSequence = RTC_NAL_SEPARATOR_START_SEQUENCE, // LongStartSequence or ShortStartSequence
	};

	static NalUnitStartSequenceMatch StartSequenceMatchSucc(NalUnitStartSequenceMatch match,
	                                                        std::byte _byte, Separator separator) {
		assert(separator != Separator::Length);
		auto byte = (uint8_t)_byte;
		auto detectShort =
		    separator == Separator::ShortStartSequence || separator == Separator::StartSequence;
		auto detectLong =
		    separator == Separator::LongStartSequence || separator == Separator::StartSequence;
		switch (match) {
		case NUSM_noMatch:
			if (byte == 0x00) {
				return NUSM_firstZero;
			}
			break;
		case NUSM_firstZero:
			if (byte == 0x00) {
				return NUSM_secondZero;
			}
			break;
		case NUSM_secondZero:
			if (byte == 0x00 && detectLong) {
				return NUSM_thirdZero;
			} else if (byte == 0x00 && detectShort) {
				return NUSM_secondZero;
			} else if (byte == 0x01 && detectShort) {
				return NUSM_shortMatch;
			}
			break;
		case NUSM_thirdZero:
			if (byte == 0x00 && detectLong) {
				return NUSM_thirdZero;
			} else if (byte == 0x01 && detectLong) {
				return NUSM_longMatch;
			}
			break;
		case NUSM_shortMatch:
			return NUSM_shortMatch;
		case NUSM_longMatch:
			return NUSM_longMatch;
		}
		return NUSM_noMatch;
	}

protected:
	const NalUnitHeader *header() const {
		assert(size() >= 1);
		return reinterpret_cast<const NalUnitHeader *>(data());
	}

	NalUnitHeader *header() {
		assert(size() >= 1);
		return reinterpret_cast<NalUnitHeader *>(data());
	}
};

/// Nal unit fragment A
struct RTC_CPP_EXPORT NalUnitFragmentA : NalUnit {
	static std::vector<shared_ptr<NalUnitFragmentA>> fragmentsFrom(shared_ptr<NalUnit> nalu,
	                                                               uint16_t maxFragmentSize);

	enum class FragmentType { Start, Middle, End };

	NalUnitFragmentA(FragmentType type, bool forbiddenBit, uint8_t nri, uint8_t unitType,
	                 binary data);

	uint8_t unitType() const { return fragmentHeader()->unitType(); }

	binary payload() const {
		assert(size() >= 2);
		return {begin() + 2, end()};
	}

	FragmentType type() const {
		if (fragmentHeader()->isStart()) {
			return FragmentType::Start;
		} else if (fragmentHeader()->isEnd()) {
			return FragmentType::End;
		} else {
			return FragmentType::Middle;
		}
	}

	void setUnitType(uint8_t type) { fragmentHeader()->setUnitType(type); }

	void setPayload(binary payload) {
		assert(size() >= 2);
		erase(begin() + 2, end());
		insert(end(), payload.begin(), payload.end());
	}

	void setFragmentType(FragmentType type);

protected:
	const uint8_t nal_type_fu_A = 28;

	NalUnitHeader *fragmentIndicator() { return reinterpret_cast<NalUnitHeader *>(data()); }

	const NalUnitHeader *fragmentIndicator() const {
		return reinterpret_cast<const NalUnitHeader *>(data());
	}

	NalUnitFragmentHeader *fragmentHeader() {
		return reinterpret_cast<NalUnitFragmentHeader *>(fragmentIndicator() + 1);
	}

	const NalUnitFragmentHeader *fragmentHeader() const {
		return reinterpret_cast<const NalUnitFragmentHeader *>(fragmentIndicator() + 1);
	}
};

class RTC_CPP_EXPORT NalUnits : public std::vector<shared_ptr<NalUnit>> {
public:
	static const uint16_t defaultMaximumFragmentSize =
	    uint16_t(RTC_DEFAULT_MTU - 12 - 8 - 40); // SRTP/UDP/IPv6

	std::vector<shared_ptr<binary>> generateFragments(uint16_t maxFragmentSize);
};

} // namespace rtc

#endif /* RTC_ENABLE_MEDIA */

#endif /* RTC_NAL_UNIT_H */
1 2024-03-21 16:36:26 +08:00			`/**`
			`* Copyright (c) 2020 Filip Klembara (in2core)`
			`*`
			`* This Source Code Form is subject to the terms of the Mozilla Public`
			`* License, v. 2.0. If a copy of the MPL was not distributed with this`
			`* file, You can obtain one at https://mozilla.org/MPL/2.0/.`
			`*/`

			`#ifndef RTC_NAL_UNIT_H`
			`#define RTC_NAL_UNIT_H`

			`#if RTC_ENABLE_MEDIA`

			`#include "common.hpp"`

			`#include <cassert>`

			`namespace rtc {`

			`#pragma pack(push, 1)`

			`/// Nalu header`
			`struct RTC_CPP_EXPORT NalUnitHeader {`
			`uint8_t _first = 0;`

			`bool forbiddenBit() const { return _first >> 7; }`
			`uint8_t nri() const { return _first >> 5 & 0x03; }`
			`uint8_t idc() const { return _first & 0x60; }`
			`uint8_t unitType() const { return _first & 0x1F; }`

			`void setForbiddenBit(bool isSet) { _first = (_first & 0x7F) \| (isSet << 7); }`
			`void setNRI(uint8_t nri) { _first = (_first & 0x9F) \| ((nri & 0x03) << 5); }`
			`void setUnitType(uint8_t type) { _first = (_first & 0xE0) \| (type & 0x1F); }`
			`};`

			`/// Nalu fragment header`
			`struct RTC_CPP_EXPORT NalUnitFragmentHeader {`
			`uint8_t _first = 0;`

			`bool isStart() const { return _first >> 7; }`
			`bool reservedBit6() const { return (_first >> 5) & 0x01; }`
			`bool isEnd() const { return (_first >> 6) & 0x01; }`
			`uint8_t unitType() const { return _first & 0x1F; }`

			`void setStart(bool isSet) { _first = (_first & 0x7F) \| (isSet << 7); }`
			`void setEnd(bool isSet) { _first = (_first & 0xBF) \| (isSet << 6); }`
			`void setReservedBit6(bool isSet) { _first = (_first & 0xDF) \| (isSet << 5); }`
			`void setUnitType(uint8_t type) { _first = (_first & 0xE0) \| (type & 0x1F); }`
			`};`

			`#pragma pack(pop)`

			`enum NalUnitStartSequenceMatch {`
			`NUSM_noMatch,`
			`NUSM_firstZero,`
			`NUSM_secondZero,`
			`NUSM_thirdZero,`
			`NUSM_shortMatch,`
			`NUSM_longMatch`
			`};`

			`static const size_t H264_NAL_HEADER_SIZE = 1;`
			`static const size_t H265_NAL_HEADER_SIZE = 2;`
			`/// Nal unit`
			`struct RTC_CPP_EXPORT NalUnit : binary {`
			`enum class Type { H264, H265 };`

			`NalUnit(const NalUnit &unit) = default;`
			`NalUnit(size_t size, bool includingHeader = true, Type type = Type::H264)`
			`: binary(size + (includingHeader`
			`? 0`
			`: (type == Type::H264 ? H264_NAL_HEADER_SIZE : H265_NAL_HEADER_SIZE))) {}`
			`NalUnit(binary &&data) : binary(std::move(data)) {}`
			`NalUnit(Type type = Type::H264)`
			`: binary(type == Type::H264 ? H264_NAL_HEADER_SIZE : H265_NAL_HEADER_SIZE) {}`
			`template <typename Iterator> NalUnit(Iterator begin_, Iterator end_) : binary(begin_, end_) {}`

			`bool forbiddenBit() const { return header()->forbiddenBit(); }`
			`uint8_t nri() const { return header()->nri(); }`
			`uint8_t unitType() const { return header()->unitType(); }`

			`binary payload() const {`
			`assert(size() >= 1);`
			`return {begin() + 1, end()};`
			`}`

			`void setForbiddenBit(bool isSet) { header()->setForbiddenBit(isSet); }`
			`void setNRI(uint8_t nri) { header()->setNRI(nri); }`
			`void setUnitType(uint8_t type) { header()->setUnitType(type); }`

			`void setPayload(binary payload) {`
			`assert(size() >= 1);`
			`erase(begin() + 1, end());`
			`insert(end(), payload.begin(), payload.end());`
			`}`

			`/// NAL unit separator`
			`enum class Separator {`
			`Length = RTC_NAL_SEPARATOR_LENGTH, // first 4 bytes are NAL unit length`
			`LongStartSequence = RTC_NAL_SEPARATOR_LONG_START_SEQUENCE, // 0x00, 0x00, 0x00, 0x01`
			`ShortStartSequence = RTC_NAL_SEPARATOR_SHORT_START_SEQUENCE, // 0x00, 0x00, 0x01`
			`StartSequence = RTC_NAL_SEPARATOR_START_SEQUENCE, // LongStartSequence or ShortStartSequence`
			`};`

			`static NalUnitStartSequenceMatch StartSequenceMatchSucc(NalUnitStartSequenceMatch match,`
			`std::byte _byte, Separator separator) {`
			`assert(separator != Separator::Length);`
			`auto byte = (uint8_t)_byte;`
			`auto detectShort =`
			`separator == Separator::ShortStartSequence \|\| separator == Separator::StartSequence;`
			`auto detectLong =`
			`separator == Separator::LongStartSequence \|\| separator == Separator::StartSequence;`
			`switch (match) {`
			`case NUSM_noMatch:`
			`if (byte == 0x00) {`
			`return NUSM_firstZero;`
			`}`
			`break;`
			`case NUSM_firstZero:`
			`if (byte == 0x00) {`
			`return NUSM_secondZero;`
			`}`
			`break;`
			`case NUSM_secondZero:`
			`if (byte == 0x00 && detectLong) {`
			`return NUSM_thirdZero;`
			`} else if (byte == 0x00 && detectShort) {`
			`return NUSM_secondZero;`
			`} else if (byte == 0x01 && detectShort) {`
			`return NUSM_shortMatch;`
			`}`
			`break;`
			`case NUSM_thirdZero:`
			`if (byte == 0x00 && detectLong) {`
			`return NUSM_thirdZero;`
			`} else if (byte == 0x01 && detectLong) {`
			`return NUSM_longMatch;`
			`}`
			`break;`
			`case NUSM_shortMatch:`
			`return NUSM_shortMatch;`
			`case NUSM_longMatch:`
			`return NUSM_longMatch;`
			`}`
			`return NUSM_noMatch;`
			`}`

			`protected:`
			`const NalUnitHeader *header() const {`
			`assert(size() >= 1);`
			`return reinterpret_cast<const NalUnitHeader *>(data());`
			`}`

			`NalUnitHeader *header() {`
			`assert(size() >= 1);`
			`return reinterpret_cast<NalUnitHeader *>(data());`
			`}`
			`};`

			`/// Nal unit fragment A`
			`struct RTC_CPP_EXPORT NalUnitFragmentA : NalUnit {`
			`static std::vector<shared_ptr<NalUnitFragmentA>> fragmentsFrom(shared_ptr<NalUnit> nalu,`
			`uint16_t maxFragmentSize);`

			`enum class FragmentType { Start, Middle, End };`

			`NalUnitFragmentA(FragmentType type, bool forbiddenBit, uint8_t nri, uint8_t unitType,`
			`binary data);`

			`uint8_t unitType() const { return fragmentHeader()->unitType(); }`

			`binary payload() const {`
			`assert(size() >= 2);`
			`return {begin() + 2, end()};`
			`}`

			`FragmentType type() const {`
			`if (fragmentHeader()->isStart()) {`
			`return FragmentType::Start;`
			`} else if (fragmentHeader()->isEnd()) {`
			`return FragmentType::End;`
			`} else {`
			`return FragmentType::Middle;`
			`}`
			`}`

			`void setUnitType(uint8_t type) { fragmentHeader()->setUnitType(type); }`

			`void setPayload(binary payload) {`
			`assert(size() >= 2);`
			`erase(begin() + 2, end());`
			`insert(end(), payload.begin(), payload.end());`
			`}`

			`void setFragmentType(FragmentType type);`

			`protected:`
			`const uint8_t nal_type_fu_A = 28;`

			`NalUnitHeader fragmentIndicator() { return reinterpret_cast<NalUnitHeader >(data()); }`

			`const NalUnitHeader *fragmentIndicator() const {`
			`return reinterpret_cast<const NalUnitHeader *>(data());`
			`}`

			`NalUnitFragmentHeader *fragmentHeader() {`
			`return reinterpret_cast<NalUnitFragmentHeader *>(fragmentIndicator() + 1);`
			`}`

			`const NalUnitFragmentHeader *fragmentHeader() const {`
			`return reinterpret_cast<const NalUnitFragmentHeader *>(fragmentIndicator() + 1);`
			`}`
			`};`

			`class RTC_CPP_EXPORT NalUnits : public std::vector<shared_ptr<NalUnit>> {`
			`public:`
			`static const uint16_t defaultMaximumFragmentSize =`
			`uint16_t(RTC_DEFAULT_MTU - 12 - 8 - 40); // SRTP/UDP/IPv6`

			`std::vector<shared_ptr<binary>> generateFragments(uint16_t maxFragmentSize);`
			`};`

			`} // namespace rtc`

			`#endif /* RTC_ENABLE_MEDIA */`

			`#endif /* RTC_NAL_UNIT_H */`