ladybird/Userland/Utilities/matroska.cpp
Timothy Flynn 604d5f5bca AK+Everywhere: Do not implicitly copy variables in TRY macros
For example, consider cases where we want to propagate errors only in
specific instances:

    auto result = read_data(); // something like ErrorOr<ByteBuffer>
    if (result.is_error() && result.error().code() != EINTR)
        continue;
    auto bytes = TRY(result);

The TRY invocation will currently copy the byte buffer when the
expression (in this case, just a local variable) is stored into
_temporary_result.

This patch binds the expression to a reference to prevent such copies.
In less trival invocations (such as TRY(some_function()), this will
incur only temporary lifetime extensions, i.e. no functional change.
2023-02-10 09:08:52 +00:00

117 lines
5.9 KiB
C++

/*
* Copyright (c) 2021, Hunter Salyer <thefalsehonesty@gmail.com>
* Copyright (c) 2022, Gregory Bertilson <zaggy1024@gmail.com>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Function.h>
#include <LibCore/ArgsParser.h>
#include <LibMain/Main.h>
#include <LibVideo/Containers/Matroska/Reader.h>
#define TRY_PARSE(expression) \
({ \
auto&& _temporary_result = ((expression)); \
if (_temporary_result.is_error()) [[unlikely]] { \
outln("Encountered a parsing error: {}", _temporary_result.error().string_literal()); \
return Error::from_string_literal("Failed to parse :("); \
} \
static_assert(!::AK::Detail::IsLvalueReference<decltype(_temporary_result.release_value())>, \
"Do not return a reference from a fallible expression"); \
_temporary_result.release_value(); \
})
ErrorOr<int> serenity_main(Main::Arguments arguments)
{
StringView filename;
bool blocks = false;
bool cues = false;
u64 track_number = 0;
Core::ArgsParser args_parser;
args_parser.add_option(blocks, "Print blocks for each track.", "blocks", 'b');
args_parser.add_option(cues, "Print cue points for each track.", "cues", 'c');
args_parser.add_option<u64>(track_number, "Specify a track number to print info for, omit to print all of them.", "track", 't', "tracknumber");
args_parser.add_positional_argument(filename, "The video file to display.", "filename", Core::ArgsParser::Required::Yes);
args_parser.parse(arguments);
auto reader = TRY_PARSE(Video::Matroska::Reader::from_file(filename));
outln("DocType is {}", reader.header().doc_type.characters());
outln("DocTypeVersion is {}", reader.header().doc_type_version);
auto segment_information = TRY_PARSE(reader.segment_information());
outln("Timestamp scale is {}", segment_information.timestamp_scale());
outln("Muxing app is \"{}\"", segment_information.muxing_app().as_string().to_deprecated_string().characters());
outln("Writing app is \"{}\"", segment_information.writing_app().as_string().to_deprecated_string().characters());
outln("Document has {} tracks", TRY_PARSE(reader.track_count()));
TRY_PARSE(reader.for_each_track([&](Video::Matroska::TrackEntry const& track_entry) -> Video::DecoderErrorOr<IterationDecision> {
if (track_number != 0 && track_entry.track_number() != track_number)
return IterationDecision::Continue;
outln("\tTrack #{} with TrackID {}", track_entry.track_number(), track_entry.track_uid());
outln("\tTrack has TrackType {}", static_cast<u8>(track_entry.track_type()));
outln("\tTrack has Language \"{}\"", track_entry.language().characters());
outln("\tTrack has CodecID \"{}\"", track_entry.codec_id().characters());
outln("\tTrack has TrackTimestampScale {}", track_entry.timestamp_scale());
outln("\tTrack has CodecDelay {}", track_entry.codec_delay());
if (track_entry.track_type() == Video::Matroska::TrackEntry::TrackType::Video) {
auto const video_track = track_entry.video_track().value();
outln("\t\tVideo is {} pixels wide by {} pixels tall", video_track.pixel_width, video_track.pixel_height);
} else if (track_entry.track_type() == Video::Matroska::TrackEntry::TrackType::Audio) {
auto const audio_track = track_entry.audio_track().value();
outln("\t\tAudio has {} channels with a bit depth of {}", audio_track.channels, audio_track.bit_depth);
}
if (cues) {
auto const& cue_points = TRY(reader.cue_points_for_track(track_entry.track_number()));
if (cue_points.has_value()) {
outln("\tCues points:");
for (auto const& cue_point : cue_points.value()) {
outln("\t\tCue point at {}ms:", cue_point.timestamp().to_milliseconds());
auto const& track_position = cue_point.position_for_track(track_entry.track_number());
if (!track_position.has_value()) {
outln("\t\t\tCue point has no positions for this track, this should not happen");
continue;
}
outln("\t\t\tCluster position {}", track_position->cluster_position());
outln("\t\t\tBlock offset {}", track_position->block_offset());
}
} else {
outln("\tNo cue points exist for this track");
}
}
if (blocks) {
outln("\tBlocks:");
auto iterator = TRY(reader.create_sample_iterator(track_entry.track_number()));
while (true) {
auto block_result = iterator.next_block();
if (block_result.is_error()) {
if (block_result.error().category() == Video::DecoderErrorCategory::EndOfStream)
break;
return block_result.release_error();
}
auto block = block_result.release_value();
outln("\t\tBlock at timestamp {}ms:", block.timestamp().to_milliseconds());
if (block.only_keyframes())
outln("\t\t\tThis block contains only keyframes");
outln("\t\t\tContains {} frames", block.frame_count());
outln("\t\t\tLacing is {}", static_cast<u8>(block.lacing()));
}
}
if (track_number != 0)
return IterationDecision::Break;
return IterationDecision::Continue;
}));
return 0;
}