shaka-packager/packager/media/formats/mp4/single_segment_segmenter.cc

235 lines
8.7 KiB
C++

// Copyright 2014 Google LLC. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
#include <packager/media/formats/mp4/single_segment_segmenter.h>
#include <algorithm>
#include <packager/file/file_util.h>
#include <packager/media/base/buffer_writer.h>
#include <packager/media/base/muxer_options.h>
#include <packager/media/event/progress_listener.h>
#include <packager/media/formats/mp4/key_frame_info.h>
namespace shaka {
namespace media {
namespace mp4 {
SingleSegmentSegmenter::SingleSegmentSegmenter(const MuxerOptions& options,
std::unique_ptr<FileType> ftyp,
std::unique_ptr<Movie> moov)
: Segmenter(options, std::move(ftyp), std::move(moov)) {}
SingleSegmentSegmenter::~SingleSegmentSegmenter() {
if (temp_file_)
temp_file_.release()->Close();
if (!temp_file_name_.empty()) {
if (!File::Delete(temp_file_name_.c_str()))
LOG(ERROR) << "Unable to delete temporary file " << temp_file_name_;
}
}
bool SingleSegmentSegmenter::GetInitRange(size_t* offset, size_t* size) {
// In Finalize, ftyp and moov gets written first so offset must be 0.
*offset = 0;
*size = ftyp()->ComputeSize() + moov()->ComputeSize();
return true;
}
bool SingleSegmentSegmenter::GetIndexRange(size_t* offset, size_t* size) {
// Index range is right after init range so the offset must be the size of
// ftyp and moov.
*offset = ftyp()->ComputeSize() + moov()->ComputeSize();
*size = options().mp4_params.generate_sidx_in_media_segments
? vod_sidx_->ComputeSize()
: 0;
return true;
}
std::vector<Range> SingleSegmentSegmenter::GetSegmentRanges() {
std::vector<Range> ranges;
uint64_t next_offset = ftyp()->ComputeSize() + moov()->ComputeSize() +
(options().mp4_params.generate_sidx_in_media_segments
? vod_sidx_->ComputeSize()
: 0) +
vod_sidx_->first_offset;
for (const SegmentReference& segment_reference : vod_sidx_->references) {
Range r;
r.start = next_offset;
// Ranges are inclusive, so -1 to the size.
r.end = r.start + segment_reference.referenced_size - 1;
next_offset = r.end + 1;
ranges.push_back(r);
}
return ranges;
}
Status SingleSegmentSegmenter::DoInitialize() {
// Single segment segmentation involves two stages:
// Stage 1: Create media subsegments from media samples
// Stage 2: Update media header (moov) which involves copying of media
// subsegments
// Assumes stage 2 takes similar amount of time as stage 1. The previous
// progress_target was set for stage 1. Times two to account for stage 2.
set_progress_target(progress_target() * 2);
if (!TempFilePath(options().temp_dir, &temp_file_name_))
return Status(error::FILE_FAILURE, "Unable to create temporary file.");
temp_file_.reset(File::Open(temp_file_name_.c_str(), "w"));
return temp_file_
? Status::OK
: Status(error::FILE_FAILURE,
"Cannot open file to write " + temp_file_name_);
}
Status SingleSegmentSegmenter::DoFinalize() {
DCHECK(temp_file_);
DCHECK(ftyp());
DCHECK(moov());
DCHECK(vod_sidx_);
// Close the temp file to prepare for reading later.
if (!temp_file_.release()->Close()) {
return Status(
error::FILE_FAILURE,
"Cannot close the temp file " + temp_file_name_ +
", possibly file permission issue or running out of disk space.");
}
std::unique_ptr<File, FileCloser> file(
File::Open(options().output_file_name.c_str(), "w"));
if (file == NULL) {
return Status(error::FILE_FAILURE,
"Cannot open file to write " + options().output_file_name);
}
LOG(INFO) << "Update media header (moov) and rewrite the file to '"
<< options().output_file_name << "'.";
// Write ftyp, moov and sidx to output file.
std::unique_ptr<BufferWriter> buffer(new BufferWriter());
ftyp()->Write(buffer.get());
moov()->Write(buffer.get());
if (options().mp4_params.generate_sidx_in_media_segments)
vod_sidx_->Write(buffer.get());
Status status = buffer->WriteToFile(file.get());
if (!status.ok())
return status;
// Load the temp file and write to output file.
std::unique_ptr<File, FileCloser> temp_file(
File::Open(temp_file_name_.c_str(), "r"));
if (temp_file == NULL) {
return Status(error::FILE_FAILURE,
"Cannot open file to read " + temp_file_name_);
}
// The target of 2nd stage of single segment segmentation.
const uint64_t re_segment_progress_target = progress_target() * 0.5;
const int kBufSize = 0x200000; // 2MB.
std::unique_ptr<uint8_t[]> buf(new uint8_t[kBufSize]);
while (true) {
int64_t size = temp_file->Read(buf.get(), kBufSize);
if (size == 0) {
break;
} else if (size < 0) {
return Status(error::FILE_FAILURE,
"Failed to read file " + temp_file_name_);
}
int64_t size_written = file->Write(buf.get(), size);
if (size_written != size) {
return Status(error::FILE_FAILURE,
"Failed to write file " + options().output_file_name);
}
UpdateProgress(static_cast<double>(size) / temp_file->Size() *
re_segment_progress_target);
}
if (!temp_file.release()->Close()) {
return Status(error::FILE_FAILURE, "Cannot close the temp file " +
temp_file_name_ + " after reading.");
}
if (!file.release()->Close()) {
return Status(
error::FILE_FAILURE,
"Cannot close file " + options().output_file_name +
", possibly file permission issue or running out of disk space.");
}
SetComplete();
return Status::OK;
}
Status SingleSegmentSegmenter::DoFinalizeSegment() {
DCHECK(sidx());
DCHECK(fragment_buffer());
// sidx() contains pre-generated segment references with one reference per
// fragment. In VOD, this segment is converted into a subsegment, i.e. one
// reference, which contains all the fragments in sidx().
std::vector<SegmentReference>& refs = sidx()->references;
SegmentReference& vod_ref = refs[0];
int64_t first_sap_time =
refs[0].sap_delta_time + refs[0].earliest_presentation_time;
for (uint32_t i = 1; i < refs.size(); ++i) {
vod_ref.referenced_size += refs[i].referenced_size;
// NOTE: We calculate subsegment duration based on the total duration of
// this subsegment instead of subtracting earliest_presentation_time as
// indicated in the spec.
vod_ref.subsegment_duration += refs[i].subsegment_duration;
vod_ref.earliest_presentation_time = std::min(
vod_ref.earliest_presentation_time, refs[i].earliest_presentation_time);
if (vod_ref.sap_type == SegmentReference::TypeUnknown &&
refs[i].sap_type != SegmentReference::TypeUnknown) {
vod_ref.sap_type = refs[i].sap_type;
first_sap_time =
refs[i].sap_delta_time + refs[i].earliest_presentation_time;
}
}
// Calculate sap delta time w.r.t. earliest_presentation_time.
if (vod_ref.sap_type != SegmentReference::TypeUnknown) {
vod_ref.sap_delta_time =
first_sap_time - vod_ref.earliest_presentation_time;
}
// Create segment if it does not exist yet.
if (vod_sidx_ == NULL) {
vod_sidx_.reset(new SegmentIndex());
vod_sidx_->reference_id = sidx()->reference_id;
vod_sidx_->timescale = sidx()->timescale;
vod_sidx_->earliest_presentation_time = vod_ref.earliest_presentation_time;
}
vod_sidx_->references.push_back(vod_ref);
if (muxer_listener()) {
for (const KeyFrameInfo& key_frame_info : key_frame_infos()) {
// Unlike multisegment-segmenter, there is no (sub)segment header (styp,
// sidx), so this is already the offset within the (sub)segment.
muxer_listener()->OnKeyFrame(key_frame_info.timestamp,
key_frame_info.start_byte_offset,
key_frame_info.size);
}
}
// Append fragment buffer to temp file.
size_t segment_size = fragment_buffer()->Size();
Status status = fragment_buffer()->WriteToFile(temp_file_.get());
if (!status.ok()) return status;
UpdateProgress(vod_ref.subsegment_duration);
if (muxer_listener()) {
muxer_listener()->OnSampleDurationReady(sample_duration());
muxer_listener()->OnNewSegment(options().output_file_name,
vod_ref.earliest_presentation_time,
vod_ref.subsegment_duration, segment_size);
}
return Status::OK;
}
} // namespace mp4
} // namespace media
} // namespace shaka