tdesktop/Telegram/SourceFiles/ffmpeg/ffmpeg_utility.cpp

608 lines
16 KiB
C++

/*
This file is part of Telegram Desktop,
the official desktop application for the Telegram messaging service.
For license and copyright information please follow this link:
https://github.com/telegramdesktop/tdesktop/blob/master/LEGAL
*/
#include "ffmpeg/ffmpeg_utility.h"
#include "base/algorithm.h"
#include "logs.h"
#if !defined TDESKTOP_USE_PACKAGED && !defined Q_OS_WIN && !defined Q_OS_MAC
#include "base/platform/linux/base_linux_library.h"
#include <deque>
#endif // !TDESKTOP_USE_PACKAGED && !Q_OS_WIN && !Q_OS_MAC
#include <QImage>
#ifdef LIB_FFMPEG_USE_QT_PRIVATE_API
#include <private/qdrawhelper_p.h>
#endif // LIB_FFMPEG_USE_QT_PRIVATE_API
extern "C" {
#include <libavutil/opt.h>
} // extern "C"
namespace FFmpeg {
namespace {
// See https://github.com/telegramdesktop/tdesktop/issues/7225
constexpr auto kAlignImageBy = 64;
constexpr auto kImageFormat = QImage::Format_ARGB32_Premultiplied;
constexpr auto kMaxScaleByAspectRatio = 16;
constexpr auto kAvioBlockSize = 4096;
constexpr auto kTimeUnknown = std::numeric_limits<crl::time>::min();
constexpr auto kDurationMax = crl::time(std::numeric_limits<int>::max());
using GetFormatMethod = enum AVPixelFormat(*)(
struct AVCodecContext *s,
const enum AVPixelFormat *fmt);
struct HwAccelDescriptor {
GetFormatMethod getFormat = nullptr;
AVPixelFormat format = AV_PIX_FMT_NONE;
};
void AlignedImageBufferCleanupHandler(void* data) {
const auto buffer = static_cast<uchar*>(data);
delete[] buffer;
}
[[nodiscard]] bool IsValidAspectRatio(AVRational aspect) {
return (aspect.num > 0)
&& (aspect.den > 0)
&& (aspect.num <= aspect.den * kMaxScaleByAspectRatio)
&& (aspect.den <= aspect.num * kMaxScaleByAspectRatio);
}
[[nodiscard]] bool IsAlignedImage(const QImage &image) {
return !(reinterpret_cast<uintptr_t>(image.bits()) % kAlignImageBy)
&& !(image.bytesPerLine() % kAlignImageBy);
}
void UnPremultiplyLine(uchar *dst, const uchar *src, int intsCount) {
[[maybe_unused]] const auto udst = reinterpret_cast<uint*>(dst);
const auto usrc = reinterpret_cast<const uint*>(src);
#ifndef LIB_FFMPEG_USE_QT_PRIVATE_API
for (auto i = 0; i != intsCount; ++i) {
udst[i] = qUnpremultiply(usrc[i]);
}
#else // !LIB_FFMPEG_USE_QT_PRIVATE_API
static const auto layout = &qPixelLayouts[QImage::Format_ARGB32];
layout->storeFromARGB32PM(dst, usrc, 0, intsCount, nullptr, nullptr);
#endif // LIB_FFMPEG_USE_QT_PRIVATE_API
}
void PremultiplyLine(uchar *dst, const uchar *src, int intsCount) {
const auto udst = reinterpret_cast<uint*>(dst);
[[maybe_unused]] const auto usrc = reinterpret_cast<const uint*>(src);
#ifndef LIB_FFMPEG_USE_QT_PRIVATE_API
for (auto i = 0; i != intsCount; ++i) {
udst[i] = qPremultiply(usrc[i]);
}
#else // !LIB_FFMPEG_USE_QT_PRIVATE_API
static const auto layout = &qPixelLayouts[QImage::Format_ARGB32];
layout->fetchToARGB32PM(udst, src, 0, intsCount, nullptr, nullptr);
#endif // LIB_FFMPEG_USE_QT_PRIVATE_API
}
#if !defined TDESKTOP_USE_PACKAGED && !defined Q_OS_WIN && !defined Q_OS_MAC
[[nodiscard]] auto CheckHwLibs() {
auto list = std::deque{
AV_PIX_FMT_CUDA,
};
if (base::Platform::LoadLibrary("libvdpau.so.1")) {
list.push_front(AV_PIX_FMT_VDPAU);
}
if ([&] {
const auto list = std::array{
"libva-drm.so.2",
"libva-x11.so.2",
"libva.so.2",
"libdrm.so.2",
};
for (const auto lib : list) {
if (!base::Platform::LoadLibrary(lib)) {
return false;
}
}
return true;
}()) {
list.push_front(AV_PIX_FMT_VAAPI);
}
return list;
}
#endif // !TDESKTOP_USE_PACKAGED && !Q_OS_WIN && !Q_OS_MAC
[[nodiscard]] bool InitHw(AVCodecContext *context, AVHWDeviceType type) {
AVCodecContext *parent = static_cast<AVCodecContext*>(context->opaque);
auto hwDeviceContext = (AVBufferRef*)nullptr;
AvErrorWrap error = av_hwdevice_ctx_create(
&hwDeviceContext,
type,
nullptr,
nullptr,
0);
if (error || !hwDeviceContext) {
LogError(u"av_hwdevice_ctx_create"_q, error);
return false;
}
DEBUG_LOG(("Video Info: "
"Trying \"%1\" hardware acceleration for \"%2\" decoder."
).arg(
av_hwdevice_get_type_name(type),
context->codec->name));
if (parent->hw_device_ctx) {
av_buffer_unref(&parent->hw_device_ctx);
}
parent->hw_device_ctx = av_buffer_ref(hwDeviceContext);
av_buffer_unref(&hwDeviceContext);
context->hw_device_ctx = parent->hw_device_ctx;
return true;
}
[[nodiscard]] enum AVPixelFormat GetHwFormat(
AVCodecContext *context,
const enum AVPixelFormat *formats) {
const auto has = [&](enum AVPixelFormat format) {
const enum AVPixelFormat *p = nullptr;
for (p = formats; *p != AV_PIX_FMT_NONE; p++) {
if (*p == format) {
return true;
}
}
return false;
};
#if !defined TDESKTOP_USE_PACKAGED && !defined Q_OS_WIN && !defined Q_OS_MAC
static const auto list = CheckHwLibs();
#else // !TDESKTOP_USE_PACKAGED && !Q_OS_WIN && !Q_OS_MAC
const auto list = std::array{
#ifdef Q_OS_WIN
AV_PIX_FMT_D3D11,
AV_PIX_FMT_DXVA2_VLD,
AV_PIX_FMT_CUDA,
#elif defined Q_OS_MAC // Q_OS_WIN
AV_PIX_FMT_VIDEOTOOLBOX,
#else // Q_OS_WIN || Q_OS_MAC
AV_PIX_FMT_VAAPI,
AV_PIX_FMT_VDPAU,
AV_PIX_FMT_CUDA,
#endif // Q_OS_WIN || Q_OS_MAC
};
#endif // TDESKTOP_USE_PACKAGED || Q_OS_WIN || Q_OS_MAC
for (const auto format : list) {
if (!has(format)) {
continue;
}
const auto type = [&] {
switch (format) {
#ifdef Q_OS_WIN
case AV_PIX_FMT_D3D11: return AV_HWDEVICE_TYPE_D3D11VA;
case AV_PIX_FMT_DXVA2_VLD: return AV_HWDEVICE_TYPE_DXVA2;
case AV_PIX_FMT_CUDA: return AV_HWDEVICE_TYPE_CUDA;
#elif defined Q_OS_MAC // Q_OS_WIN
case AV_PIX_FMT_VIDEOTOOLBOX:
return AV_HWDEVICE_TYPE_VIDEOTOOLBOX;
#else // Q_OS_WIN || Q_OS_MAC
case AV_PIX_FMT_VAAPI: return AV_HWDEVICE_TYPE_VAAPI;
case AV_PIX_FMT_VDPAU: return AV_HWDEVICE_TYPE_VDPAU;
case AV_PIX_FMT_CUDA: return AV_HWDEVICE_TYPE_CUDA;
#endif // Q_OS_WIN || Q_OS_MAC
}
return AV_HWDEVICE_TYPE_NONE;
}();
if (type == AV_HWDEVICE_TYPE_NONE && context->hw_device_ctx) {
av_buffer_unref(&context->hw_device_ctx);
} else if (type != AV_HWDEVICE_TYPE_NONE && !InitHw(context, type)) {
continue;
}
return format;
}
enum AVPixelFormat result = AV_PIX_FMT_NONE;
for (const enum AVPixelFormat *p = formats; *p != AV_PIX_FMT_NONE; p++) {
result = *p;
}
return result;
}
template <AVPixelFormat Required>
enum AVPixelFormat GetFormatImplementation(
AVCodecContext *ctx,
const enum AVPixelFormat *pix_fmts) {
const enum AVPixelFormat *p = nullptr;
for (p = pix_fmts; *p != -1; p++) {
if (*p == Required) {
return *p;
}
}
return AV_PIX_FMT_NONE;
}
} // namespace
IOPointer MakeIOPointer(
void *opaque,
int(*read)(void *opaque, uint8_t *buffer, int bufferSize),
int(*write)(void *opaque, uint8_t *buffer, int bufferSize),
int64_t(*seek)(void *opaque, int64_t offset, int whence)) {
auto buffer = reinterpret_cast<uchar*>(av_malloc(kAvioBlockSize));
if (!buffer) {
LogError(u"av_malloc"_q);
return {};
}
auto result = IOPointer(avio_alloc_context(
buffer,
kAvioBlockSize,
write ? 1 : 0,
opaque,
read,
write,
seek));
if (!result) {
av_freep(&buffer);
LogError(u"avio_alloc_context"_q);
return {};
}
return result;
}
void IODeleter::operator()(AVIOContext *value) {
if (value) {
av_freep(&value->buffer);
avio_context_free(&value);
}
}
FormatPointer MakeFormatPointer(
void *opaque,
int(*read)(void *opaque, uint8_t *buffer, int bufferSize),
int(*write)(void *opaque, uint8_t *buffer, int bufferSize),
int64_t(*seek)(void *opaque, int64_t offset, int whence)) {
auto io = MakeIOPointer(opaque, read, write, seek);
if (!io) {
return {};
}
io->seekable = (seek != nullptr);
auto result = avformat_alloc_context();
if (!result) {
LogError(u"avformat_alloc_context"_q);
return {};
}
result->pb = io.get();
auto options = (AVDictionary*)nullptr;
const auto guard = gsl::finally([&] { av_dict_free(&options); });
av_dict_set(&options, "usetoc", "1", 0);
const auto error = AvErrorWrap(avformat_open_input(
&result,
nullptr,
nullptr,
&options));
if (error) {
// avformat_open_input freed 'result' in case an error happened.
LogError(u"avformat_open_input"_q, error);
return {};
}
if (seek) {
result->flags |= AVFMT_FLAG_FAST_SEEK;
}
// Now FormatPointer will own and free the IO context.
io.release();
return FormatPointer(result);
}
void FormatDeleter::operator()(AVFormatContext *value) {
if (value) {
const auto deleter = IOPointer(value->pb);
avformat_close_input(&value);
}
}
const AVCodec *FindDecoder(not_null<AVCodecContext*> context) {
// Force libvpx-vp9, because we need alpha channel support.
return (context->codec_id == AV_CODEC_ID_VP9)
? avcodec_find_decoder_by_name("libvpx-vp9")
: avcodec_find_decoder(context->codec_id);
}
CodecPointer MakeCodecPointer(CodecDescriptor descriptor) {
auto error = AvErrorWrap();
auto result = CodecPointer(avcodec_alloc_context3(nullptr));
const auto context = result.get();
if (!context) {
LogError(u"avcodec_alloc_context3"_q);
return {};
}
const auto stream = descriptor.stream;
error = avcodec_parameters_to_context(context, stream->codecpar);
if (error) {
LogError(u"avcodec_parameters_to_context"_q, error);
return {};
}
context->pkt_timebase = stream->time_base;
av_opt_set(context, "threads", "auto", 0);
av_opt_set_int(context, "refcounted_frames", 1, 0);
const auto codec = FindDecoder(context);
if (!codec) {
LogError(u"avcodec_find_decoder"_q, context->codec_id);
return {};
}
if (descriptor.hwAllowed) {
context->get_format = GetHwFormat;
context->opaque = context;
} else {
DEBUG_LOG(("Video Info: Using software \"%2\" decoder."
).arg(codec->name));
}
if ((error = avcodec_open2(context, codec, nullptr))) {
LogError(u"avcodec_open2"_q, error);
return {};
}
return result;
}
void CodecDeleter::operator()(AVCodecContext *value) {
if (value) {
avcodec_free_context(&value);
}
}
FramePointer MakeFramePointer() {
return FramePointer(av_frame_alloc());
}
FramePointer DuplicateFramePointer(AVFrame *frame) {
return frame
? FramePointer(av_frame_clone(frame))
: FramePointer();
}
bool FrameHasData(AVFrame *frame) {
return (frame && frame->data[0] != nullptr);
}
void ClearFrameMemory(AVFrame *frame) {
if (FrameHasData(frame)) {
av_frame_unref(frame);
}
}
void FrameDeleter::operator()(AVFrame *value) {
av_frame_free(&value);
}
SwscalePointer MakeSwscalePointer(
QSize srcSize,
int srcFormat,
QSize dstSize,
int dstFormat,
SwscalePointer *existing) {
// We have to use custom caching for SwsContext, because
// sws_getCachedContext checks passed flags with existing context flags,
// and re-creates context if they're different, but in the process of
// context creation the passed flags are modified before being written
// to the resulting context, so the caching doesn't work.
if (existing && (*existing) != nullptr) {
const auto &deleter = existing->get_deleter();
if (deleter.srcSize == srcSize
&& deleter.srcFormat == srcFormat
&& deleter.dstSize == dstSize
&& deleter.dstFormat == dstFormat) {
return std::move(*existing);
}
}
if (srcFormat <= AV_PIX_FMT_NONE || srcFormat >= AV_PIX_FMT_NB) {
LogError(u"frame->format"_q);
return SwscalePointer();
}
const auto result = sws_getCachedContext(
existing ? existing->release() : nullptr,
srcSize.width(),
srcSize.height(),
AVPixelFormat(srcFormat),
dstSize.width(),
dstSize.height(),
AVPixelFormat(dstFormat),
0,
nullptr,
nullptr,
nullptr);
if (!result) {
LogError(u"sws_getCachedContext"_q);
}
return SwscalePointer(
result,
{ srcSize, srcFormat, dstSize, dstFormat });
}
SwscalePointer MakeSwscalePointer(
not_null<AVFrame*> frame,
QSize resize,
SwscalePointer *existing) {
return MakeSwscalePointer(
QSize(frame->width, frame->height),
frame->format,
resize,
AV_PIX_FMT_BGRA,
existing);
}
void SwscaleDeleter::operator()(SwsContext *value) {
if (value) {
sws_freeContext(value);
}
}
void LogError(const QString &method) {
LOG(("Streaming Error: Error in %1.").arg(method));
}
void LogError(const QString &method, AvErrorWrap error) {
LOG(("Streaming Error: Error in %1 (code: %2, text: %3)."
).arg(method
).arg(error.code()
).arg(error.text()));
}
crl::time PtsToTime(int64_t pts, AVRational timeBase) {
return (pts == AV_NOPTS_VALUE || !timeBase.den)
? kTimeUnknown
: ((pts * 1000LL * timeBase.num) / timeBase.den);
}
crl::time PtsToTimeCeil(int64_t pts, AVRational timeBase) {
return (pts == AV_NOPTS_VALUE || !timeBase.den)
? kTimeUnknown
: ((pts * 1000LL * timeBase.num + timeBase.den - 1) / timeBase.den);
}
int64_t TimeToPts(crl::time time, AVRational timeBase) {
return (time == kTimeUnknown || !timeBase.num)
? AV_NOPTS_VALUE
: (time * timeBase.den) / (1000LL * timeBase.num);
}
crl::time PacketPosition(const Packet &packet, AVRational timeBase) {
const auto &native = packet.fields();
return PtsToTime(
(native.pts == AV_NOPTS_VALUE) ? native.dts : native.pts,
timeBase);
}
crl::time PacketDuration(const Packet &packet, AVRational timeBase) {
return PtsToTime(packet.fields().duration, timeBase);
}
int DurationByPacket(const Packet &packet, AVRational timeBase) {
const auto position = PacketPosition(packet, timeBase);
const auto duration = std::max(
PacketDuration(packet, timeBase),
crl::time(1));
const auto bad = [](crl::time time) {
return (time < 0) || (time > kDurationMax);
};
if (bad(position) || bad(duration) || bad(position + duration + 1)) {
LOG(("Streaming Error: Wrong duration by packet: %1 + %2"
).arg(position
).arg(duration));
return -1;
}
return int(position + duration + 1);
}
int ReadRotationFromMetadata(not_null<AVStream*> stream) {
const auto tag = av_dict_get(stream->metadata, "rotate", nullptr, 0);
if (tag && *tag->value) {
const auto string = QString::fromUtf8(tag->value);
auto ok = false;
const auto degrees = string.toInt(&ok);
if (ok && (degrees == 90 || degrees == 180 || degrees == 270)) {
return degrees;
}
}
return 0;
}
AVRational ValidateAspectRatio(AVRational aspect) {
return IsValidAspectRatio(aspect) ? aspect : kNormalAspect;
}
QSize CorrectByAspect(QSize size, AVRational aspect) {
Expects(IsValidAspectRatio(aspect));
return QSize(size.width() * av_q2d(aspect), size.height());
}
bool RotationSwapWidthHeight(int rotation) {
return (rotation == 90 || rotation == 270);
}
QSize TransposeSizeByRotation(QSize size, int rotation) {
return RotationSwapWidthHeight(rotation) ? size.transposed() : size;
}
bool GoodStorageForFrame(const QImage &storage, QSize size) {
return !storage.isNull()
&& (storage.format() == kImageFormat)
&& (storage.size() == size)
&& storage.isDetached()
&& IsAlignedImage(storage);
}
// Create a QImage of desired size where all the data is properly aligned.
QImage CreateFrameStorage(QSize size) {
const auto width = size.width();
const auto height = size.height();
const auto widthAlign = kAlignImageBy / kPixelBytesSize;
const auto neededWidth = width + ((width % widthAlign)
? (widthAlign - (width % widthAlign))
: 0);
const auto perLine = neededWidth * kPixelBytesSize;
const auto buffer = new uchar[perLine * height + kAlignImageBy];
const auto cleanupData = static_cast<void *>(buffer);
const auto address = reinterpret_cast<uintptr_t>(buffer);
const auto alignedBuffer = buffer + ((address % kAlignImageBy)
? (kAlignImageBy - (address % kAlignImageBy))
: 0);
return QImage(
alignedBuffer,
width,
height,
perLine,
kImageFormat,
AlignedImageBufferCleanupHandler,
cleanupData);
}
void UnPremultiply(QImage &dst, const QImage &src) {
// This creates QImage::Format_ARGB32_Premultiplied, but we use it
// as an image in QImage::Format_ARGB32 format.
if (!GoodStorageForFrame(dst, src.size())) {
dst = CreateFrameStorage(src.size());
}
const auto srcPerLine = src.bytesPerLine();
const auto dstPerLine = dst.bytesPerLine();
const auto width = src.width();
const auto height = src.height();
auto srcBytes = src.bits();
auto dstBytes = dst.bits();
if (srcPerLine != width * 4 || dstPerLine != width * 4) {
for (auto i = 0; i != height; ++i) {
UnPremultiplyLine(dstBytes, srcBytes, width);
srcBytes += srcPerLine;
dstBytes += dstPerLine;
}
} else {
UnPremultiplyLine(dstBytes, srcBytes, width * height);
}
}
void PremultiplyInplace(QImage &image) {
const auto perLine = image.bytesPerLine();
const auto width = image.width();
const auto height = image.height();
auto bytes = image.bits();
if (perLine != width * 4) {
for (auto i = 0; i != height; ++i) {
PremultiplyLine(bytes, bytes, width);
bytes += perLine;
}
} else {
PremultiplyLine(bytes, bytes, width * height);
}
}
} // namespace FFmpeg