mirror of https://github.com/odrling/Aegisub
325 lines
11 KiB
C++
325 lines
11 KiB
C++
// Copyright (c) 2010, Thomas Goyne <plorkyeran@aegisub.org>
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//
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// Permission to use, copy, modify, and distribute this software for any
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// purpose with or without fee is hereby granted, provided that the above
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// copyright notice and this permission notice appear in all copies.
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//
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// THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
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// WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
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// MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
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// ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
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// WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
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// ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
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// OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
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/// @file vfr.cpp
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/// @brief Framerate handling of all sorts
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/// @ingroup libaegisub video_input
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#include "libaegisub/vfr.h"
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#include "libaegisub/charset.h"
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#include "libaegisub/io.h"
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#include "libaegisub/line_iterator.h"
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#include <algorithm>
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#include <boost/interprocess/streams/bufferstream.hpp>
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#include <boost/range/algorithm.hpp>
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#include <cmath>
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#include <functional>
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#include <iterator>
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namespace {
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static const int64_t default_denominator = 1000000000;
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using agi::line_iterator;
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using namespace agi::vfr;
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/// @brief Verify that timecodes monotonically increase
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/// @param timecodes List of timecodes to check
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void validate_timecodes(std::vector<int> const& timecodes) {
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if (timecodes.size() <= 1)
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throw InvalidFramerate("Must have at least two timecodes to do anything useful");
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if (!is_sorted(timecodes.begin(), timecodes.end()))
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throw InvalidFramerate("Timecodes are out of order");
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if (timecodes.front() == timecodes.back())
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throw InvalidFramerate("Timecodes are all identical");
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}
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/// @brief Shift timecodes so that frame 0 starts at time 0
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/// @param timecodes List of timecodes to normalize
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void normalize_timecodes(std::vector<int> &timecodes) {
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if (int front = timecodes.front())
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boost::for_each(timecodes, [=](int &tc) { tc -= front; });
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}
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// A "start,end,fps" line in a v1 timecode file
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struct TimecodeRange {
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int start;
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int end;
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double fps;
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bool operator<(TimecodeRange const& cmp) const { return start < cmp.start; }
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};
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/// @brief Parse a single line of a v1 timecode file
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/// @param str Line to parse
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/// @return The line in TimecodeRange form, or TimecodeRange() if it's a comment
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TimecodeRange v1_parse_line(std::string const& str) {
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if (str.empty() || str[0] == '#') return TimecodeRange();
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boost::interprocess::ibufferstream ss(str.data(), str.size());
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TimecodeRange range;
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char comma1 = 0, comma2 = 0;
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ss >> range.start >> comma1 >> range.end >> comma2 >> range.fps;
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if (ss.fail() || comma1 != ',' || comma2 != ',' || !ss.eof())
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throw MalformedLine(str);
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if (range.start < 0 || range.end < 0)
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throw InvalidFramerate("Cannot specify frame rate for negative frames.");
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if (range.end < range.start)
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throw InvalidFramerate("End frame must be greater than or equal to start frame");
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if (range.fps <= 0.)
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throw InvalidFramerate("FPS must be greater than zero");
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if (range.fps > 1000.)
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// This is our limitation, not mkvmerge's
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// mkvmerge uses nanoseconds internally
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throw InvalidFramerate("FPS must be at most 1000");
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return range;
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}
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/// @brief Parse a v1 timecode file
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/// @param file Iterator of lines in the file
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/// @param line Header of file with assumed fps
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/// @param[out] timecodes Vector filled with frame start times
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/// @param[out] last Unrounded time of the last frame
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/// @return Assumed fps times one million
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int64_t v1_parse(line_iterator<std::string> file, std::string line, std::vector<int> &timecodes, int64_t &last) {
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double fps = atof(line.substr(7).c_str());
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if (fps <= 0.) throw InvalidFramerate("Assumed FPS must be greater than zero");
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if (fps > 1000.) throw InvalidFramerate("Assumed FPS must not be greater than 1000");
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std::vector<TimecodeRange> ranges;
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for (auto const& line : file) {
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auto range = v1_parse_line(line);
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if (range.fps != 0)
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ranges.push_back(range);
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}
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std::sort(begin(ranges), end(ranges));
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if (!ranges.empty())
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timecodes.reserve(ranges.back().end + 2);
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double time = 0.;
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int frame = 0;
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for (auto const& range : ranges) {
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if (frame > range.start) {
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// mkvmerge allows overlapping timecode ranges, but does completely
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// broken things with them
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throw InvalidFramerate("Override ranges must not overlap");
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}
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for (; frame < range.start; ++frame) {
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timecodes.push_back(int(time + .5));
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time += 1000. / fps;
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}
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for (; frame <= range.end; ++frame) {
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timecodes.push_back(int(time + .5));
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time += 1000. / range.fps;
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}
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}
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timecodes.push_back(int(time + .5));
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last = int64_t(time * fps * default_denominator);
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return int64_t(fps * default_denominator);
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}
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}
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namespace agi { namespace vfr {
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Framerate::Framerate(double fps)
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: denominator(default_denominator)
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, numerator(int64_t(fps * denominator))
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{
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if (fps < 0.) throw InvalidFramerate("FPS must be greater than zero");
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if (fps > 1000.) throw InvalidFramerate("FPS must not be greater than 1000");
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timecodes.push_back(0);
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}
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Framerate::Framerate(int64_t numerator, int64_t denominator, bool drop)
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: denominator(denominator)
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, numerator(numerator)
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, drop(drop && numerator % denominator != 0)
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{
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if (numerator <= 0 || denominator <= 0)
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throw InvalidFramerate("Numerator and denominator must both be greater than zero");
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if (numerator / denominator > 1000) throw InvalidFramerate("FPS must not be greater than 1000");
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timecodes.push_back(0);
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}
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void Framerate::SetFromTimecodes() {
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validate_timecodes(timecodes);
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normalize_timecodes(timecodes);
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denominator = default_denominator;
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numerator = (timecodes.size() - 1) * denominator * 1000 / timecodes.back();
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last = (timecodes.size() - 1) * denominator * 1000;
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}
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Framerate::Framerate(std::vector<int> timecodes)
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: timecodes(std::move(timecodes))
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{
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SetFromTimecodes();
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}
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Framerate::Framerate(std::initializer_list<int> timecodes)
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: timecodes(timecodes)
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{
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SetFromTimecodes();
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}
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Framerate::Framerate(fs::path const& filename)
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: denominator(default_denominator)
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{
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auto file = agi::io::Open(filename);
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auto encoding = agi::charset::Detect(filename);
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auto line = *line_iterator<std::string>(*file, encoding);
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if (line == "# timecode format v2") {
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copy(line_iterator<int>(*file, encoding), line_iterator<int>(), back_inserter(timecodes));
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SetFromTimecodes();
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return;
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}
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if (line == "# timecode format v1" || line.substr(0, 7) == "Assume ") {
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if (line[0] == '#')
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line = *line_iterator<std::string>(*file, encoding);
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numerator = v1_parse(line_iterator<std::string>(*file, encoding), line, timecodes, last);
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return;
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}
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throw UnknownFormat(line);
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}
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void Framerate::Save(fs::path const& filename, int length) const {
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agi::io::Save file(filename);
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auto &out = file.Get();
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out << "# timecode format v2\n";
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boost::copy(timecodes, std::ostream_iterator<int>(out, "\n"));
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for (int written = (int)timecodes.size(); written < length; ++written)
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out << TimeAtFrame(written) << std::endl;
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}
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int Framerate::FrameAtTime(int ms, Time type) const {
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// With X ms per frame, this should return 0 for:
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// EXACT: [0, X - 1]
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// START: [1 - X , 0]
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// END: [1, X]
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// There are two properties we take advantage of here:
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// 1. START and END's ranges are adjacent, meaning doing the calculations
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// for END and adding one gives us START
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// 2. END is EXACT plus one ms, meaning we can subtract one ms to get EXACT
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// Combining these allows us to easily calculate START and END in terms of
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// EXACT
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if (type == START)
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return FrameAtTime(ms - 1) + 1;
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if (type == END)
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return FrameAtTime(ms - 1);
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if (ms < 0)
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return int((ms * numerator / denominator - 999) / 1000);
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if (ms > timecodes.back())
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return int((ms * numerator - last + denominator - 1) / denominator / 1000) + (int)timecodes.size() - 1;
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return (int)distance(lower_bound(timecodes.rbegin(), timecodes.rend(), ms, std::greater<int>()), timecodes.rend()) - 1;
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}
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int Framerate::TimeAtFrame(int frame, Time type) const {
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if (type == START) {
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int prev = TimeAtFrame(frame - 1);
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int cur = TimeAtFrame(frame);
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// + 1 as these need to round up for the case of two frames 1 ms apart
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return prev + (cur - prev + 1) / 2;
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}
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if (type == END) {
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int cur = TimeAtFrame(frame);
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int next = TimeAtFrame(frame + 1);
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return cur + (next - cur + 1) / 2;
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}
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if (frame < 0)
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return (int)(frame * denominator * 1000 / numerator);
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if (frame >= (signed)timecodes.size()) {
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int64_t frames_past_end = frame - (int)timecodes.size() + 1;
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return int((frames_past_end * 1000 * denominator + last + numerator / 2) / numerator);
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}
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return timecodes[frame];
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}
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void Framerate::SmpteAtFrame(int frame, int *h, int *m, int *s, int *f) const {
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frame = std::max(frame, 0);
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int ifps = (int)ceil(FPS());
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if (drop && denominator == 1001 && numerator % 30000 == 0) {
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// NTSC skips the first two frames of every minute except for multiples
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// of ten. For multiples of NTSC, simply multiplying the number of
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// frames skips seems like the most sensible option.
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const int drop_factor = int(numerator / 30000);
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const int one_minute = 60 * 30 * drop_factor - drop_factor * 2;
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const int ten_minutes = 60 * 10 * 30 * drop_factor - drop_factor * 18;
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const int ten_minute_groups = frame / ten_minutes;
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const int last_ten_minutes = frame % ten_minutes;
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frame += ten_minute_groups * 18 * drop_factor;
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frame += (last_ten_minutes - 2 * drop_factor) / one_minute * 2 * drop_factor;
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}
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// Non-integral frame rates other than NTSC aren't supported by SMPTE
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// timecodes, but the user has asked for it so just give something that
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// resembles a valid timecode which is no more than half a frame off
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// wallclock time
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else if (drop && ifps != FPS()) {
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frame = int(frame / FPS() * ifps + 0.5);
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}
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*h = frame / (ifps * 60 * 60);
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*m = (frame / (ifps * 60)) % 60;
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*s = (frame / ifps) % 60;
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*f = frame % ifps;
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}
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void Framerate::SmpteAtTime(int ms, int *h, int *m, int *s, int *f) const {
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SmpteAtFrame(FrameAtTime(ms), h, m, s, f);
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}
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int Framerate::FrameAtSmpte(int h, int m, int s, int f) const {
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int ifps = (int)ceil(FPS());
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if (drop && denominator == 1001 && numerator % 30000 == 0) {
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const int drop_factor = int(numerator / 30000);
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const int one_minute = 60 * 30 * drop_factor - drop_factor * 2;
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const int ten_minutes = 60 * 10 * 30 * drop_factor - drop_factor * 18;
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const int ten_m = m / 10;
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m = m % 10;
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// The specified frame doesn't actually exist so skip forward to the
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// next frame that does
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if (m != 0 && s == 0 && f < 2 * drop_factor)
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f = 2 * drop_factor;
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return h * ten_minutes * 6 + ten_m * ten_minutes + m * one_minute + s * ifps + f;
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}
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else if (drop && ifps != FPS()) {
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int frame = (h * 60 * 60 + m * 60 + s) * ifps + f;
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return int((double)frame / ifps * FPS() + 0.5);
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}
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return (h * 60 * 60 + m * 60 + s) * ifps + f;
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}
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int Framerate::TimeAtSmpte(int h, int m, int s, int f) const {
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return TimeAtFrame(FrameAtSmpte(h, m, s, f));
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}
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} }
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