winamp/Src/external_dependencies/openmpt-trunk/mptrack/Mod2wave.cpp

1402 lines
44 KiB
C++
Raw Normal View History

2024-09-24 14:54:57 +02:00
/*
* mod2wave.cpp
* ------------
* Purpose: Module to WAV conversion (dialog + conversion code).
* Notes : (currently none)
* Authors: OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*/
#include "stdafx.h"
#include "Mptrack.h"
#include "Sndfile.h"
#include "Dlsbank.h"
#include "Mainfrm.h"
#include "Mpdlgs.h"
#include "mod2wave.h"
#include "WAVTools.h"
#include "../common/mptString.h"
#include "../common/version.h"
#include "../soundlib/MixerLoops.h"
#include "openmpt/soundbase/Dither.hpp"
#include "../common/Dither.h"
#include "../soundlib/AudioReadTarget.h"
#include "../soundlib/plugins/PlugInterface.h"
#include "../common/mptFileIO.h"
#include "mpt/audio/span.hpp"
#include <variant>
#include "mpt/io/io.hpp"
#include "mpt/io/io_stdstream.hpp"
OPENMPT_NAMESPACE_BEGIN
extern const TCHAR *gszChnCfgNames[3];
template <typename Tsample>
static CSoundFile::samplecount_t ReadInterleaved(CSoundFile &sndFile, Tsample *outputBuffer, std::size_t channels, CSoundFile::samplecount_t count, DithersOpenMPT &dithers)
{
sndFile.ResetMixStat();
MPT_ASSERT(sndFile.m_MixerSettings.gnChannels == channels);
AudioTargetBuffer<mpt::audio_span_interleaved<Tsample>, DithersOpenMPT> target(mpt::audio_span_interleaved<Tsample>(outputBuffer, channels, count), dithers);
return sndFile.Read(count, target);
}
///////////////////////////////////////////////////
// CWaveConvert - setup for converting a wave file
BEGIN_MESSAGE_MAP(CWaveConvert, CDialog)
ON_COMMAND(IDC_CHECK2, &CWaveConvert::OnCheckTimeLimit)
ON_COMMAND(IDC_CHECK4, &CWaveConvert::OnCheckChannelMode)
ON_COMMAND(IDC_CHECK6, &CWaveConvert::OnCheckInstrMode)
ON_COMMAND(IDC_RADIO1, &CWaveConvert::UpdateDialog)
ON_COMMAND(IDC_RADIO2, &CWaveConvert::UpdateDialog)
ON_COMMAND(IDC_RADIO3, &CWaveConvert::UpdateDialog)
ON_COMMAND(IDC_RADIO4, &CWaveConvert::OnExportModeChanged)
ON_COMMAND(IDC_RADIO5, &CWaveConvert::OnExportModeChanged)
ON_COMMAND(IDC_PLAYEROPTIONS, &CWaveConvert::OnPlayerOptions)
ON_CBN_SELCHANGE(IDC_COMBO5, &CWaveConvert::OnFileTypeChanged)
ON_CBN_SELCHANGE(IDC_COMBO1, &CWaveConvert::OnSamplerateChanged)
ON_CBN_SELCHANGE(IDC_COMBO4, &CWaveConvert::OnChannelsChanged)
ON_CBN_SELCHANGE(IDC_COMBO6, &CWaveConvert::OnDitherChanged)
ON_CBN_SELCHANGE(IDC_COMBO2, &CWaveConvert::OnFormatChanged)
ON_CBN_SELCHANGE(IDC_COMBO9, &CWaveConvert::OnSampleSlotChanged)
END_MESSAGE_MAP()
CWaveConvert::CWaveConvert(CWnd *parent, ORDERINDEX minOrder, ORDERINDEX maxOrder, ORDERINDEX numOrders, CSoundFile &sndFile, const std::vector<EncoderFactoryBase*> &encFactories)
: CDialog(IDD_WAVECONVERT, parent)
, m_Settings(theApp.GetSettings(), encFactories)
, m_SndFile(sndFile)
{
ASSERT(!encFactories.empty());
encTraits = m_Settings.GetTraits();
m_bGivePlugsIdleTime = false;
if(minOrder != ORDERINDEX_INVALID && maxOrder != ORDERINDEX_INVALID)
{
// render selection
m_Settings.minOrder = minOrder;
m_Settings.maxOrder = maxOrder;
}
m_Settings.repeatCount = 1;
m_Settings.minSequence = m_Settings.maxSequence = m_SndFile.Order.GetCurrentSequenceIndex();
m_nNumOrders = numOrders;
m_dwSongLimit = 0;
}
void CWaveConvert::DoDataExchange(CDataExchange *pDX)
{
CDialog::DoDataExchange(pDX);
DDX_Control(pDX, IDC_COMBO5, m_CbnFileType);
DDX_Control(pDX, IDC_COMBO1, m_CbnSampleRate);
DDX_Control(pDX, IDC_COMBO4, m_CbnChannels);
DDX_Control(pDX, IDC_COMBO6, m_CbnDither);
DDX_Control(pDX, IDC_COMBO2, m_CbnSampleFormat);
DDX_Control(pDX, IDC_SPIN3, m_SpinMinOrder);
DDX_Control(pDX, IDC_SPIN4, m_SpinMaxOrder);
DDX_Control(pDX, IDC_SPIN5, m_SpinLoopCount);
DDX_Control(pDX, IDC_SPIN6, m_SpinMinSequence);
DDX_Control(pDX, IDC_SPIN7, m_SpinMaxSequence);
DDX_Control(pDX, IDC_COMBO9, m_CbnSampleSlot);
DDX_Control(pDX, IDC_COMBO3, m_CbnGenre);
DDX_Control(pDX, IDC_EDIT10, m_EditGenre);
DDX_Control(pDX, IDC_EDIT11, m_EditTitle);
DDX_Control(pDX, IDC_EDIT6, m_EditAuthor);
DDX_Control(pDX, IDC_EDIT7, m_EditAlbum);
DDX_Control(pDX, IDC_EDIT8, m_EditURL);
DDX_Control(pDX, IDC_EDIT9, m_EditYear);
}
BOOL CWaveConvert::OnInitDialog()
{
CDialog::OnInitDialog();
CheckDlgButton(IDC_CHECK5, BST_UNCHECKED); // Normalize
CheckDlgButton(IDC_CHECK3, BST_CHECKED); // Cue points
CheckDlgButton(IDC_CHECK4, BST_UNCHECKED);
CheckDlgButton(IDC_CHECK6, BST_UNCHECKED);
const bool selection = (m_Settings.minOrder != ORDERINDEX_INVALID && m_Settings.maxOrder != ORDERINDEX_INVALID);
CheckRadioButton(IDC_RADIO1, IDC_RADIO3, selection ? IDC_RADIO2 : IDC_RADIO1);
if(selection)
{
SetDlgItemInt(IDC_EDIT3, m_Settings.minOrder);
SetDlgItemInt(IDC_EDIT4, m_Settings.maxOrder);
}
m_SpinMinOrder.SetRange32(0, m_nNumOrders);
m_SpinMaxOrder.SetRange32(0, m_nNumOrders);
const SEQUENCEINDEX numSequences = m_SndFile.Order.GetNumSequences();
const BOOL enableSeq = numSequences > 1 ? TRUE : FALSE;
GetDlgItem(IDC_RADIO3)->EnableWindow(enableSeq);
m_SpinMinSequence.SetRange32(1, numSequences);
m_SpinMaxSequence.SetRange32(1, numSequences);
SetDlgItemInt(IDC_EDIT12, m_Settings.minSequence + 1);
SetDlgItemInt(IDC_EDIT13, m_Settings.maxSequence + 1);
SetDlgItemInt(IDC_EDIT5, m_Settings.repeatCount, FALSE);
m_SpinLoopCount.SetRange32(1, int16_max);
FillFileTypes();
FillSamplerates();
FillChannels();
FillFormats();
FillDither();
LoadTags();
m_EditYear.SetLimitText(4);
m_EditTitle.SetWindowText(mpt::ToCString(m_Settings.Tags.title));
m_EditAuthor.SetWindowText(mpt::ToCString(m_Settings.Tags.artist));
m_EditURL.SetWindowText(mpt::ToCString(m_Settings.Tags.url));
m_EditAlbum.SetWindowText(mpt::ToCString(m_Settings.Tags.album));
m_EditYear.SetWindowText(mpt::ToCString(m_Settings.Tags.year));
m_EditGenre.SetWindowText(mpt::ToCString(m_Settings.Tags.genre));
FillTags();
// Plugin quirk options are only available if there are any plugins loaded.
GetDlgItem(IDC_GIVEPLUGSIDLETIME)->EnableWindow(FALSE);
GetDlgItem(IDC_RENDERSILENCE)->EnableWindow(FALSE);
#ifndef NO_PLUGINS
for(const auto &plug : m_SndFile.m_MixPlugins)
{
if(plug.pMixPlugin != nullptr)
{
GetDlgItem(IDC_GIVEPLUGSIDLETIME)->EnableWindow(TRUE);
GetDlgItem(IDC_RENDERSILENCE)->EnableWindow(TRUE);
break;
}
}
#endif // NO_PLUGINS
// Fill list of sample slots to render into
if(m_SndFile.GetNextFreeSample() != SAMPLEINDEX_INVALID)
{
m_CbnSampleSlot.SetItemData(m_CbnSampleSlot.AddString(_T("<empty slot>")), 0);
}
CString s;
for(SAMPLEINDEX smp = 1; smp <= m_SndFile.GetNumSamples(); smp++)
{
s.Format(_T("%02u: %s%s"), smp, m_SndFile.GetSample(smp).HasSampleData() ? _T("*") : _T(""), mpt::ToCString(m_SndFile.GetCharsetInternal(), m_SndFile.GetSampleName(smp)).GetString());
m_CbnSampleSlot.SetItemData(m_CbnSampleSlot.AddString(s), smp);
}
if(m_Settings.sampleSlot > m_SndFile.GetNumSamples()) m_Settings.sampleSlot = 0;
m_CbnSampleSlot.SetCurSel(m_Settings.sampleSlot);
CheckRadioButton(IDC_RADIO4, IDC_RADIO5, m_Settings.outputToSample ? IDC_RADIO5 : IDC_RADIO4);
UpdateDialog();
return TRUE;
}
void CWaveConvert::LoadTags()
{
m_Settings.Tags.title = mpt::ToUnicode(mpt::Charset::Locale, m_SndFile.GetTitle());
m_Settings.Tags.comments = mpt::ToUnicode(mpt::Charset::Locale, m_SndFile.m_songMessage.GetFormatted(SongMessage::leLF));
m_Settings.Tags.artist = m_SndFile.m_songArtist;
m_Settings.Tags.album = m_Settings.storedTags.album;
m_Settings.Tags.trackno = m_Settings.storedTags.trackno;
m_Settings.Tags.year = m_Settings.storedTags.year;
m_Settings.Tags.url = m_Settings.storedTags.url;
m_Settings.Tags.genre = m_Settings.storedTags.genre;
}
void CWaveConvert::SaveTags()
{
m_Settings.storedTags.artist = m_Settings.Tags.artist;
m_Settings.storedTags.album = m_Settings.Tags.album;
m_Settings.storedTags.trackno = m_Settings.Tags.trackno;
m_Settings.storedTags.year = m_Settings.Tags.year;
m_Settings.storedTags.url = m_Settings.Tags.url;
m_Settings.storedTags.genre = m_Settings.Tags.genre;
}
void CWaveConvert::FillTags()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
DWORD_PTR dwFormat = m_CbnSampleFormat.GetItemData(m_CbnSampleFormat.GetCurSel());
Encoder::Mode mode = (Encoder::Mode)((dwFormat >> 24) & 0xff);
CheckDlgButton(IDC_CHECK3, encTraits->canCues?encSettings.Cues?TRUE:FALSE:FALSE);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_CHECK3), encTraits->canCues?TRUE:FALSE);
const BOOL canTags = encTraits->canTags ? TRUE : FALSE;
CheckDlgButton(IDC_CHECK7, encSettings.Tags ? canTags : FALSE);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_CHECK7), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_COMBO3), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_EDIT11), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_EDIT6), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_EDIT7), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_EDIT8), canTags);
::EnableWindow(::GetDlgItem(m_hWnd, IDC_EDIT9), canTags);
m_CbnGenre.EnableWindow(canTags?TRUE:FALSE);
m_EditGenre.EnableWindow(canTags?TRUE:FALSE);
if((encTraits->modesWithFixedGenres & mode) && !encTraits->genres.empty())
{
m_EditGenre.ShowWindow(SW_HIDE);
m_CbnGenre.ShowWindow(SW_SHOW);
m_EditGenre.Clear();
m_CbnGenre.ResetContent();
m_CbnGenre.AddString(_T(""));
for(const auto &genre : encTraits->genres)
{
m_CbnGenre.AddString(mpt::ToCString(genre));
}
} else
{
m_CbnGenre.ShowWindow(SW_HIDE);
m_EditGenre.ShowWindow(SW_SHOW);
m_CbnGenre.ResetContent();
m_EditGenre.Clear();
}
}
void CWaveConvert::FillFileTypes()
{
m_CbnFileType.ResetContent();
int sel = 0;
for(std::size_t i = 0; i < m_Settings.EncoderFactories.size(); ++i)
{
int ndx = m_CbnFileType.AddString(MPT_CFORMAT("{} ({})")(mpt::ToCString(m_Settings.EncoderFactories[i]->GetTraits().fileShortDescription), mpt::ToCString(m_Settings.EncoderFactories[i]->GetTraits().fileDescription)));
m_CbnFileType.SetItemData(ndx, i);
if(m_Settings.EncoderIndex == i)
{
sel = ndx;
}
}
m_CbnFileType.SetCurSel(sel);
}
void CWaveConvert::FillSamplerates()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
m_CbnSampleRate.CComboBox::ResetContent();
int sel = -1;
if(TrackerSettings::Instance().ExportDefaultToSoundcardSamplerate)
{
for(auto samplerate : encTraits->samplerates)
{
if(samplerate == TrackerSettings::Instance().MixerSamplerate)
{
encSettings.Samplerate = samplerate;
}
}
}
for(auto samplerate : encTraits->samplerates)
{
int ndx = m_CbnSampleRate.AddString(MPT_CFORMAT("{} Hz")(samplerate));
m_CbnSampleRate.SetItemData(ndx, samplerate);
if(samplerate == encSettings.Samplerate)
{
sel = ndx;
}
}
if(sel == -1)
{
sel = 0;
}
m_CbnSampleRate.SetCurSel(sel);
}
void CWaveConvert::FillChannels()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
m_CbnChannels.CComboBox::ResetContent();
int sel = 0;
for(int channels = 4; channels >= 1; channels /= 2)
{
if(channels > encTraits->maxChannels)
{
continue;
}
if(IsDlgButtonChecked(IDC_RADIO5) != BST_UNCHECKED)
{
if(channels > 2)
{
// sample export only supports 2 channels max
continue;
}
}
int ndx = m_CbnChannels.AddString(gszChnCfgNames[(channels+2)/2-1]);
m_CbnChannels.SetItemData(ndx, channels);
if(channels == encSettings.Channels)
{
sel = ndx;
}
}
m_CbnChannels.SetCurSel(sel);
}
void CWaveConvert::FillFormats()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
m_CbnSampleFormat.CComboBox::ResetContent();
int sel = -1;
int samplerate = static_cast<int>(m_CbnSampleRate.GetItemData(m_CbnSampleRate.GetCurSel()));
int channels = static_cast<int>(m_CbnChannels.GetItemData(m_CbnChannels.GetCurSel()));
if(encTraits->modes & Encoder::ModeQuality)
{
for(int quality = 100; quality >= 0; quality -= 10)
{
int ndx = m_CbnSampleFormat.AddString(mpt::ToCString(m_Settings.GetEncoderFactory()->DescribeQuality(quality * 0.01f)));
m_CbnSampleFormat.SetItemData(ndx, (Encoder::ModeQuality<<24) | (quality<<0));
if(encSettings.Mode == Encoder::ModeQuality && mpt::saturate_round<int>(encSettings.Quality*100.0f) == quality)
{
sel = ndx;
}
}
}
if(encTraits->modes & Encoder::ModeVBR)
{
for(int bitrate = static_cast<int>(encTraits->bitrates.size()-1); bitrate >= 0; --bitrate)
{
if(!m_Settings.GetEncoderFactory()->IsBitrateSupported(samplerate, channels, encTraits->bitrates[bitrate]))
{
continue;
}
int ndx = m_CbnSampleFormat.AddString(mpt::ToCString(m_Settings.GetEncoderFactory()->DescribeBitrateVBR(encTraits->bitrates[bitrate])));
m_CbnSampleFormat.SetItemData(ndx, (Encoder::ModeVBR<<24) | (encTraits->bitrates[bitrate]<<0));
if(encSettings.Mode == Encoder::ModeVBR && static_cast<int>(encSettings.Bitrate) == encTraits->bitrates[bitrate])
{
sel = ndx;
}
}
}
if(encTraits->modes & Encoder::ModeABR)
{
for(int bitrate = static_cast<int>(encTraits->bitrates.size()-1); bitrate >= 0; --bitrate)
{
if(!m_Settings.GetEncoderFactory()->IsBitrateSupported(samplerate, channels, encTraits->bitrates[bitrate]))
{
continue;
}
int ndx = m_CbnSampleFormat.AddString(mpt::ToCString(m_Settings.GetEncoderFactory()->DescribeBitrateABR(encTraits->bitrates[bitrate])));
m_CbnSampleFormat.SetItemData(ndx, (Encoder::ModeABR<<24) | (encTraits->bitrates[bitrate]<<0));
if(encSettings.Mode == Encoder::ModeABR && static_cast<int>(encSettings.Bitrate) == encTraits->bitrates[bitrate])
{
sel = ndx;
}
}
}
if(encTraits->modes & Encoder::ModeCBR)
{
for(int bitrate = static_cast<int>(encTraits->bitrates.size()-1); bitrate >= 0; --bitrate)
{
if(!m_Settings.GetEncoderFactory()->IsBitrateSupported(samplerate, channels, encTraits->bitrates[bitrate]))
{
continue;
}
int ndx = m_CbnSampleFormat.AddString(mpt::ToCString(m_Settings.GetEncoderFactory()->DescribeBitrateCBR(encTraits->bitrates[bitrate])));
m_CbnSampleFormat.SetItemData(ndx, (Encoder::ModeCBR<<24) | (encTraits->bitrates[bitrate]<<0));
if(encSettings.Mode == Encoder::ModeCBR && static_cast<int>(encSettings.Bitrate) == encTraits->bitrates[bitrate])
{
sel = ndx;
}
}
}
if(encTraits->modes & Encoder::ModeLossless)
{
bool allBig = true;
bool allLittle = true;
for(const auto &format : encTraits->formats)
{
if(format.endian != mpt::endian::little)
{
allLittle = false;
}
if(format.endian != mpt::endian::big)
{
allBig = false;
}
}
bool showEndian = !(allBig || allLittle);
for(std::size_t i = 0; i < encTraits->formats.size(); ++i)
{
const Encoder::Format &format = encTraits->formats[i];
mpt::ustring description;
switch(format.encoding)
{
case Encoder::Format::Encoding::Float:
description = MPT_UFORMAT("{} Bit Floating Point")(format.bits);
break;
case Encoder::Format::Encoding::Integer:
description = MPT_UFORMAT("{} Bit")(format.bits);
break;
case Encoder::Format::Encoding::Alaw:
description = U_("A-law");
break;
case Encoder::Format::Encoding::ulaw:
description = MPT_UTF8("\xce\xbc-law");
break;
case Encoder::Format::Encoding::Unsigned:
description = MPT_UFORMAT("{} Bit (unsigned)")(format.bits);
break;
}
if(showEndian && format.bits != 8 && format.encoding != Encoder::Format::Encoding::Alaw && format.encoding != Encoder::Format::Encoding::ulaw)
{
switch(format.endian)
{
case mpt::endian::big:
description += U_(" Big-Endian");
break;
case mpt::endian::little:
description += U_(" Little-Endian");
break;
}
}
int ndx = m_CbnSampleFormat.AddString(mpt::ToCString(description));
m_CbnSampleFormat.SetItemData(ndx, format.AsInt());
if(encSettings.Mode & Encoder::ModeLossless && format == encSettings.Format2)
{
sel = ndx;
}
}
}
if(sel == -1)
{
sel = 0;
}
m_CbnSampleFormat.SetCurSel(sel);
}
void CWaveConvert::FillDither()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
m_CbnDither.CComboBox::ResetContent();
int format = m_CbnSampleFormat.GetItemData(m_CbnSampleFormat.GetCurSel()) & 0xffffff;
if((encTraits->modes & Encoder::ModeLossless) && Encoder::Format::FromInt(format).GetSampleFormat() != SampleFormat::Invalid && !Encoder::Format::FromInt(format).GetSampleFormat().IsFloat())
{
m_CbnDither.EnableWindow(TRUE);
for(std::size_t dither = 0; dither < DithersOpenMPT::GetNumDithers(); ++dither)
{
int ndx = m_CbnDither.AddString(mpt::ToCString(DithersOpenMPT::GetModeName(dither) + U_(" dither")));
m_CbnDither.SetItemData(ndx, dither);
}
} else
{
m_CbnDither.EnableWindow(FALSE);
for(std::size_t dither = 0; dither < DithersOpenMPT::GetNumDithers(); ++dither)
{
int ndx = m_CbnDither.AddString(mpt::ToCString(DithersOpenMPT::GetModeName(DithersOpenMPT::GetNoDither()) + U_(" dither")));
m_CbnDither.SetItemData(ndx, dither);
}
}
m_CbnDither.SetCurSel(encSettings.Dither);
}
void CWaveConvert::OnFileTypeChanged()
{
SaveEncoderSettings();
DWORD_PTR dwFileType = m_CbnFileType.GetItemData(m_CbnFileType.GetCurSel());
m_Settings.SelectEncoder(dwFileType);
encTraits = m_Settings.GetTraits();
FillSamplerates();
FillChannels();
FillFormats();
FillDither();
FillTags();
}
void CWaveConvert::OnSamplerateChanged()
{
SaveEncoderSettings();
FillFormats();
FillDither();
}
void CWaveConvert::OnChannelsChanged()
{
SaveEncoderSettings();
FillFormats();
FillDither();
}
void CWaveConvert::OnDitherChanged()
{
SaveEncoderSettings();
}
void CWaveConvert::OnFormatChanged()
{
SaveEncoderSettings();
FillDither();
FillTags();
}
void CWaveConvert::UpdateDialog()
{
CheckDlgButton(IDC_CHECK2, (m_dwSongLimit) ? BST_CHECKED : 0);
GetDlgItem(IDC_EDIT2)->EnableWindow(m_dwSongLimit ? TRUE : FALSE);
// Repeat / selection play
int sel = GetCheckedRadioButton(IDC_RADIO1, IDC_RADIO3);
GetDlgItem(IDC_EDIT3)->EnableWindow(sel == IDC_RADIO2);
GetDlgItem(IDC_EDIT4)->EnableWindow(sel == IDC_RADIO2);
m_SpinMinOrder.EnableWindow(sel == IDC_RADIO2);
m_SpinMaxOrder.EnableWindow(sel == IDC_RADIO2);
GetDlgItem(IDC_EDIT5)->EnableWindow(sel == IDC_RADIO1);
m_SpinLoopCount.EnableWindow(sel == IDC_RADIO1);
const SEQUENCEINDEX numSequences = m_SndFile.Order.GetNumSequences();
const BOOL enableSeq = (numSequences > 1 && sel == IDC_RADIO3) ? TRUE : FALSE;
GetDlgItem(IDC_EDIT12)->EnableWindow(enableSeq);
GetDlgItem(IDC_EDIT13)->EnableWindow(enableSeq);
m_SpinMinSequence.EnableWindow(enableSeq);
m_SpinMaxSequence.EnableWindow(enableSeq);
// No free slots => Cannot do instrument- or channel-based export to sample
BOOL canDoMultiExport = (IsDlgButtonChecked(IDC_RADIO4) != BST_UNCHECKED /* normal export */ || m_CbnSampleSlot.GetItemData(0) == 0 /* "free slot" is in list */) ? TRUE : FALSE;
GetDlgItem(IDC_CHECK4)->EnableWindow(canDoMultiExport);
GetDlgItem(IDC_CHECK6)->EnableWindow(canDoMultiExport);
}
void CWaveConvert::OnExportModeChanged()
{
SaveEncoderSettings();
bool sampleExport = (IsDlgButtonChecked(IDC_RADIO5) != BST_UNCHECKED);
m_CbnFileType.EnableWindow(sampleExport ? FALSE : TRUE);
m_CbnSampleSlot.EnableWindow(sampleExport && !IsDlgButtonChecked(IDC_CHECK4) && !IsDlgButtonChecked(IDC_CHECK6));
if(sampleExport)
{
// Render to sample: Always use WAV
if(m_CbnFileType.GetCurSel() != 0)
{
m_CbnFileType.SetCurSel(0);
OnFileTypeChanged();
}
}
FillChannels();
FillFormats();
FillDither();
FillTags();
}
void CWaveConvert::OnSampleSlotChanged()
{
CheckRadioButton(IDC_RADIO4, IDC_RADIO5, IDC_RADIO5);
// When choosing a specific sample slot, we cannot use per-channel or per-instrument export
int sel = m_CbnSampleSlot.GetCurSel();
if(sel >= 0 && m_CbnSampleSlot.GetItemData(sel) > 0)
{
CheckDlgButton(IDC_CHECK4, BST_UNCHECKED);
CheckDlgButton(IDC_CHECK6, BST_UNCHECKED);
}
UpdateDialog();
}
void CWaveConvert::OnPlayerOptions()
{
CPropertySheet dlg(_T("Mixer Settings"), this);
COptionsMixer mixerpage;
dlg.AddPage(&mixerpage);
#if !defined(NO_REVERB) || !defined(NO_DSP) || !defined(NO_EQ) || !defined(NO_AGC)
COptionsPlayer dsppage;
dlg.AddPage(&dsppage);
#endif
dlg.DoModal();
}
void CWaveConvert::OnCheckTimeLimit()
{
if (IsDlgButtonChecked(IDC_CHECK2))
{
m_dwSongLimit = GetDlgItemInt(IDC_EDIT2, NULL, FALSE);
if (!m_dwSongLimit)
{
m_dwSongLimit = 600;
SetDlgItemText(IDC_EDIT2, _T("600"));
}
} else m_dwSongLimit = 0;
UpdateDialog();
}
// Channel render is mutually exclusive with instrument render
void CWaveConvert::OnCheckChannelMode()
{
if(IsDlgButtonChecked(IDC_CHECK4) != BST_UNCHECKED)
{
CheckDlgButton(IDC_CHECK6, BST_UNCHECKED);
m_CbnSampleSlot.SetCurSel(0);
}
UpdateDialog();
}
// Channel render is mutually exclusive with instrument render
void CWaveConvert::OnCheckInstrMode()
{
if(IsDlgButtonChecked(IDC_CHECK6) != BST_UNCHECKED)
{
CheckDlgButton(IDC_CHECK4, BST_UNCHECKED);
m_CbnSampleSlot.SetCurSel(0);
}
UpdateDialog();
}
void CWaveConvert::OnOK()
{
if (m_dwSongLimit) m_dwSongLimit = GetDlgItemInt(IDC_EDIT2, NULL, FALSE);
const bool selection = IsDlgButtonChecked(IDC_RADIO2) != BST_UNCHECKED;
if(selection)
{
// Play selection
m_Settings.minOrder = static_cast<ORDERINDEX>(GetDlgItemInt(IDC_EDIT3, NULL, FALSE));
m_Settings.maxOrder = static_cast<ORDERINDEX>(GetDlgItemInt(IDC_EDIT4, NULL, FALSE));
if(m_Settings.minOrder > m_Settings.maxOrder)
std::swap(m_Settings.minOrder, m_Settings.maxOrder);
} else
{
m_Settings.minOrder = m_Settings.maxOrder = ORDERINDEX_INVALID;
}
if(IsDlgButtonChecked(IDC_RADIO3))
{
const UINT maxSequence = m_SndFile.Order.GetNumSequences();
m_Settings.minSequence = static_cast<SEQUENCEINDEX>(std::clamp(GetDlgItemInt(IDC_EDIT12, NULL, FALSE), 1u, maxSequence) - 1u);
m_Settings.maxSequence = static_cast<SEQUENCEINDEX>(std::clamp(GetDlgItemInt(IDC_EDIT13, NULL, FALSE), 1u, maxSequence) - 1u);
if(m_Settings.minSequence > m_Settings.maxSequence)
std::swap(m_Settings.minSequence, m_Settings.maxSequence);
} else
{
m_Settings.minSequence = m_Settings.maxSequence = m_SndFile.Order.GetCurrentSequenceIndex();
}
m_Settings.repeatCount = static_cast<uint16>(GetDlgItemInt(IDC_EDIT5, NULL, FALSE));
m_Settings.normalize = IsDlgButtonChecked(IDC_CHECK5) != BST_UNCHECKED;
m_Settings.silencePlugBuffers = IsDlgButtonChecked(IDC_RENDERSILENCE) != BST_UNCHECKED;
m_Settings.outputToSample = IsDlgButtonChecked(IDC_RADIO5) != BST_UNCHECKED;
m_bGivePlugsIdleTime = IsDlgButtonChecked(IDC_GIVEPLUGSIDLETIME) != BST_UNCHECKED;
if (m_bGivePlugsIdleTime)
{
static bool showWarning = true;
if(showWarning && Reporting::Confirm("You only need slow render if you are experiencing dropped notes with a Kontakt based sampler with Direct-From-Disk enabled, or buggy plugins that use the system time for parameter automation.\nIt will make rendering *very* slow.\n\nAre you sure you want to enable slow render?",
"Really enable slow render?") == cnfNo)
{
m_bGivePlugsIdleTime = false;
} else
{
showWarning = false;
}
}
m_bChannelMode = IsDlgButtonChecked(IDC_CHECK4) != BST_UNCHECKED;
m_bInstrumentMode= IsDlgButtonChecked(IDC_CHECK6) != BST_UNCHECKED;
m_Settings.sampleSlot = static_cast<SAMPLEINDEX>(m_CbnSampleSlot.GetItemData(m_CbnSampleSlot.GetCurSel()));
SaveEncoderSettings();
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
m_Settings.Tags = FileTags();
m_Settings.Tags.SetEncoder();
if(encSettings.Tags)
{
CString tmp;
m_EditTitle.GetWindowText(tmp);
m_Settings.Tags.title = mpt::ToUnicode(tmp);
m_EditAuthor.GetWindowText(tmp);
m_Settings.Tags.artist = mpt::ToUnicode(tmp);
m_EditAlbum.GetWindowText(tmp);
m_Settings.Tags.album = mpt::ToUnicode(tmp);
m_EditURL.GetWindowText(tmp);
m_Settings.Tags.url = mpt::ToUnicode(tmp);
if((encTraits->modesWithFixedGenres & encSettings.Mode) && !encTraits->genres.empty())
{
m_CbnGenre.GetWindowText(tmp);
m_Settings.Tags.genre = mpt::ToUnicode(tmp);
} else
{
m_EditGenre.GetWindowText(tmp);
m_Settings.Tags.genre = mpt::ToUnicode(tmp);
}
m_EditYear.GetWindowText(tmp);
m_Settings.Tags.year = mpt::ToUnicode(tmp);
if(m_Settings.Tags.year == U_("0"))
{
m_Settings.Tags.year = mpt::ustring();
}
if(!m_SndFile.m_songMessage.empty())
{
m_Settings.Tags.comments = mpt::ToUnicode(mpt::Charset::Locale, m_SndFile.m_songMessage.GetFormatted(SongMessage::leLF));
}
m_Settings.Tags.bpm = mpt::ufmt::val(m_SndFile.GetCurrentBPM());
SaveTags();
}
CDialog::OnOK();
}
void CWaveConvert::SaveEncoderSettings()
{
EncoderSettingsConf &encSettings = m_Settings.GetEncoderSettings();
encSettings.Samplerate = static_cast<uint32>(m_CbnSampleRate.GetItemData(m_CbnSampleRate.GetCurSel()));
encSettings.Channels = static_cast<uint16>(m_CbnChannels.GetItemData(m_CbnChannels.GetCurSel()));
DWORD_PTR dwFormat = m_CbnSampleFormat.GetItemData(m_CbnSampleFormat.GetCurSel());
if(encTraits->modes & Encoder::ModeLossless)
{
int format = (int)((dwFormat >> 0) & 0xffffff);
encSettings.Dither = static_cast<int>(m_CbnDither.GetItemData(m_CbnDither.GetCurSel()));
encSettings.Format2 = Encoder::Format::FromInt(format);
encSettings.Mode = Encoder::ModeLossless;
encSettings.Bitrate = 0;
encSettings.Quality = encTraits->defaultQuality;
} else
{
encSettings.Dither = static_cast<int>(m_CbnDither.GetItemData(m_CbnDither.GetCurSel()));
Encoder::Mode mode = (Encoder::Mode)((dwFormat >> 24) & 0xff);
int quality = (int)((dwFormat >> 0) & 0xff);
int bitrate = (int)((dwFormat >> 0) & 0xffff);
encSettings.Mode = mode;
encSettings.Bitrate = bitrate;
encSettings.Quality = static_cast<float>(quality) * 0.01f;
encSettings.Format2 = { Encoder::Format::Encoding::Float, 32, mpt::get_endian() };
}
encSettings.Cues = IsDlgButtonChecked(IDC_CHECK3) ? true : false;
encSettings.Tags = IsDlgButtonChecked(IDC_CHECK7) ? true : false;
}
std::size_t CWaveConvertSettings::FindEncoder(const mpt::ustring &name) const
{
for(std::size_t i = 0; i < EncoderFactories.size(); ++i)
{
if(EncoderFactories[i]->GetTraits().encoderSettingsName == name)
{
return i;
}
}
return 0;
}
void CWaveConvertSettings::SelectEncoder(std::size_t index)
{
MPT_ASSERT(!EncoderFactories.empty());
MPT_ASSERT(index < EncoderFactories.size());
EncoderIndex = index;
EncoderName = EncoderFactories[EncoderIndex]->GetTraits().encoderSettingsName;
}
EncoderFactoryBase *CWaveConvertSettings::GetEncoderFactory() const
{
MPT_ASSERT(!EncoderFactories.empty());
return EncoderFactories[EncoderIndex];
}
const Encoder::Traits *CWaveConvertSettings::GetTraits() const
{
MPT_ASSERT(!EncoderFactories.empty());
return &EncoderFactories[EncoderIndex]->GetTraits();
}
EncoderSettingsConf &CWaveConvertSettings::GetEncoderSettings() const
{
MPT_ASSERT(!EncoderSettings.empty());
return *(EncoderSettings[EncoderIndex]);
}
Encoder::Settings CWaveConvertSettings::GetEncoderSettingsWithDetails() const
{
MPT_ASSERT(!EncoderSettings.empty());
Encoder::Settings settings = static_cast<Encoder::Settings>(*(EncoderSettings[EncoderIndex]));
settings.Details = static_cast<Encoder::StreamSettings>(TrackerSettings::Instance().ExportStreamEncoderSettings);
return settings;
}
CWaveConvertSettings::CWaveConvertSettings(SettingsContainer &conf, const std::vector<EncoderFactoryBase*> &encFactories)
: EncoderFactories(encFactories)
, EncoderName(conf, U_("Export"), U_("Encoder"), U_(""))
, EncoderIndex(FindEncoder(EncoderName))
, storedTags(conf)
, repeatCount(0)
, minOrder(ORDERINDEX_INVALID), maxOrder(ORDERINDEX_INVALID)
, sampleSlot(0)
, normalize(false)
, silencePlugBuffers(false)
, outputToSample(false)
{
Tags.SetEncoder();
for(const auto & factory : EncoderFactories)
{
const Encoder::Traits &encTraits = factory->GetTraits();
EncoderSettings.push_back(
std::make_unique<EncoderSettingsConf>(
conf,
encTraits.encoderSettingsName,
encTraits.canCues,
encTraits.canTags,
encTraits.defaultSamplerate,
encTraits.defaultChannels,
encTraits.defaultMode,
encTraits.defaultBitrate,
encTraits.defaultQuality,
encTraits.defaultFormat,
encTraits.defaultDitherType
)
);
}
SelectEncoder(EncoderIndex);
}
/////////////////////////////////////////////////////////////////////////////////////////
// CDoWaveConvert: save a mod as a wave file
void CDoWaveConvert::Run()
{
UINT ok = IDOK;
uint64 ullSamples = 0;
std::vector<float> normalizeBufferData;
float *normalizeBuffer = nullptr;
float normalizePeak = 0.0f;
const mpt::PathString normalizeFileName = mpt::CreateTempFileName(P_("OpenMPT"));
std::optional<mpt::fstream> normalizeFile;
if(m_Settings.normalize)
{
normalizeBufferData.resize(MIXBUFFERSIZE * 4);
normalizeBuffer = normalizeBufferData.data();
// Ensure this temporary file is marked as temporary in the file system, to increase the chance it will never be written to disk
if(HANDLE hFile = ::CreateFile(normalizeFileName.AsNative().c_str(), GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, CREATE_ALWAYS, FILE_ATTRIBUTE_TEMPORARY, NULL); hFile != INVALID_HANDLE_VALUE)
{
::CloseHandle(hFile);
}
normalizeFile.emplace(normalizeFileName, std::ios::binary | std::ios::in | std::ios::out | std::ios::trunc);
}
const Encoder::Settings encSettings = m_Settings.GetEncoderSettingsWithDetails();
const uint32 samplerate = encSettings.Samplerate;
const uint16 channels = encSettings.Channels;
ASSERT(m_Settings.GetEncoderFactory() && m_Settings.GetEncoderFactory()->IsAvailable());
// Silence mix buffer of plugins, for plugins that don't clear their reverb buffers and similar stuff when they are reset
#ifndef NO_PLUGINS
if(m_Settings.silencePlugBuffers)
{
SetText(_T("Clearing plugin buffers"));
for(auto &plug : m_SndFile.m_MixPlugins)
{
if(plug.pMixPlugin != nullptr)
{
// Render up to 20 seconds per plugin
for(int j = 0; j < 20; j++)
{
const float maxVal = plug.pMixPlugin->RenderSilence(samplerate);
if(maxVal <= FLT_EPSILON)
{
break;
}
}
ProcessMessages();
if(m_abort)
{
m_abort = false;
break;
}
}
}
}
#endif // NO_PLUGINS
MixerSettings oldmixersettings = m_SndFile.m_MixerSettings;
MixerSettings mixersettings = TrackerSettings::Instance().GetMixerSettings();
mixersettings.m_nMaxMixChannels = MAX_CHANNELS; // always use max mixing channels when rendering
mixersettings.gdwMixingFreq = samplerate;
mixersettings.gnChannels = channels;
m_SndFile.m_SongFlags.reset(SONG_PAUSED | SONG_STEP);
if(m_Settings.normalize)
{
#ifndef NO_AGC
mixersettings.DSPMask &= ~SNDDSP_AGC;
#endif
}
DithersOpenMPT dithers(theApp.PRNG(), encSettings.Dither, encSettings.Channels);
m_SndFile.ResetChannels();
m_SndFile.SetMixerSettings(mixersettings);
m_SndFile.SetResamplerSettings(TrackerSettings::Instance().GetResamplerSettings());
m_SndFile.InitPlayer(true);
// Tags must be known at the stream start,
// so that the encoder class could write them before audio data if mandated by the format,
// otherwise they should just be cached by the encoder.
std::unique_ptr<IAudioStreamEncoder> fileEnc = m_Settings.GetEncoderFactory()->ConstructStreamEncoder(fileStream, encSettings, m_Settings.Tags);
std::variant<
std::unique_ptr<std::array<double, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<float, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<int32, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<int24, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<int16, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<int8, MIXBUFFERSIZE * 4>>,
std::unique_ptr<std::array<uint8, MIXBUFFERSIZE * 4>>> bufferData;
union AnyBufferSamplePointer
{
double *float64;
float *float32;
int32 *int32;
int24 *int24;
int16 *int16;
int8 *int8;
uint8 *uint8;
void *any;
};
AnyBufferSamplePointer buffer;
buffer.any = nullptr;
switch(fileEnc->GetSampleFormat())
{
case SampleFormat::Float64:
bufferData = std::make_unique<std::array<double, MIXBUFFERSIZE * 4>>();
buffer.float64 = std::get<0>(bufferData)->data();
break;
case SampleFormat::Float32:
bufferData = std::make_unique<std::array<float, MIXBUFFERSIZE * 4>>();
buffer.float32 = std::get<1>(bufferData)->data();
break;
case SampleFormat::Int32:
bufferData = std::make_unique<std::array<int32, MIXBUFFERSIZE * 4>>();
buffer.int32 = std::get<2>(bufferData)->data();
break;
case SampleFormat::Int24:
bufferData = std::make_unique<std::array<int24, MIXBUFFERSIZE * 4>>();
buffer.int24 = std::get<3>(bufferData)->data();
break;
case SampleFormat::Int16:
bufferData = std::make_unique<std::array<int16, MIXBUFFERSIZE * 4>>();
buffer.int16 = std::get<4>(bufferData)->data();
break;
case SampleFormat::Int8:
bufferData = std::make_unique<std::array<int8, MIXBUFFERSIZE * 4>>();
buffer.int8 = std::get<5>(bufferData)->data();
break;
case SampleFormat::Unsigned8:
bufferData = std::make_unique<std::array<uint8, MIXBUFFERSIZE * 4>>();
buffer.uint8 = std::get<6>(bufferData)->data();
break;
}
uint64 ullMaxSamples = uint64_max / (channels * ((fileEnc->GetSampleFormat().GetBitsPerSample()+7) / 8));
if (m_dwSongLimit)
{
LimitMax(ullMaxSamples, m_dwSongLimit * samplerate);
}
// Calculate maximum samples
uint64 max = m_dwSongLimit ? ullMaxSamples : uint64_max;
// Reset song position tracking
m_SndFile.ResetPlayPos();
m_SndFile.m_SongFlags.reset(SONG_PATTERNLOOP);
ORDERINDEX startOrder = 0;
GetLengthTarget target;
if(m_Settings.minOrder != ORDERINDEX_INVALID && m_Settings.maxOrder != ORDERINDEX_INVALID)
{
m_SndFile.SetRepeatCount(0);
startOrder = m_Settings.minOrder;
ORDERINDEX endOrder = m_Settings.maxOrder;
while(!m_SndFile.Order().IsValidPat(endOrder) && endOrder > startOrder)
{
endOrder--;
}
if(m_SndFile.Order().IsValidPat(endOrder))
{
target = GetLengthTarget(endOrder, m_SndFile.Patterns[m_SndFile.Order()[endOrder]].GetNumRows() - 1);
}
target.StartPos(m_SndFile.Order.GetCurrentSequenceIndex(), startOrder, 0);
m_SndFile.m_nMaxOrderPosition = endOrder + 1;
} else
{
m_SndFile.SetRepeatCount(std::max(0, m_Settings.repeatCount - 1));
}
uint64 l = mpt::saturate_round<uint64>(m_SndFile.GetLength(eNoAdjust, target).front().duration * samplerate * (1 + m_SndFile.GetRepeatCount()));
m_SndFile.SetCurrentOrder(startOrder);
m_SndFile.GetLength(eAdjust, GetLengthTarget(startOrder, 0)); // adjust playback variables / visited rows vector
m_SndFile.m_PlayState.m_nCurrentOrder = startOrder;
if (l < max) max = l;
SetRange(0, max);
EnableTaskbarProgress();
// No pattern cue points yet
std::vector<PatternCuePoint> patternCuePoints;
patternCuePoints.reserve(m_SndFile.Order().size());
m_SndFile.m_PatternCuePoints = &patternCuePoints;
// Process the conversion
// For calculating the remaining time
auto dwStartTime = timeGetTime(), prevTime = dwStartTime;
uint32 timeRemaining = 0;
uint64 bytesWritten = 0;
auto mainFrame = CMainFrame::GetMainFrame();
mainFrame->PauseMod();
m_SndFile.m_SongFlags.reset(SONG_STEP | SONG_PATTERNLOOP);
mainFrame->InitRenderer(&m_SndFile);
for (UINT n = 0; ; n++)
{
UINT lRead = 0;
if(m_Settings.normalize)
{
lRead = ReadInterleaved(m_SndFile, normalizeBuffer, channels, MIXBUFFERSIZE, dithers);
} else
{
switch(fileEnc->GetSampleFormat())
{
case SampleFormat::Float64:
lRead = ReadInterleaved(m_SndFile, buffer.float64, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Float32:
lRead = ReadInterleaved(m_SndFile, buffer.float32, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Int32:
lRead = ReadInterleaved(m_SndFile, buffer.int32, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Int24:
lRead = ReadInterleaved(m_SndFile, buffer.int24, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Int16:
lRead = ReadInterleaved(m_SndFile, buffer.int16, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Int8:
lRead = ReadInterleaved(m_SndFile, buffer.int8, channels, MIXBUFFERSIZE, dithers);
break;
case SampleFormat::Unsigned8:
lRead = ReadInterleaved(m_SndFile, buffer.uint8, channels, MIXBUFFERSIZE, dithers);
break;
}
}
// Process cue points (add base offset), if there are any to process.
for(auto iter = patternCuePoints.rbegin(); iter != patternCuePoints.rend(); ++iter)
{
if(iter->processed)
{
// From this point, all cues have already been processed.
break;
}
iter->offset += ullSamples;
iter->processed = true;
}
if (m_bGivePlugsIdleTime)
{
Sleep(20);
}
if (!lRead)
break;
ullSamples += lRead;
if(m_Settings.normalize)
{
std::size_t countSamples = lRead * m_SndFile.m_MixerSettings.gnChannels;
const float *src = normalizeBuffer;
while(countSamples--)
{
const float val = *src;
if(val > normalizePeak) normalizePeak = val;
else if(0.0f - val >= normalizePeak) normalizePeak = 0.0f - val;
src++;
}
if(!mpt::IO::WriteRaw(*normalizeFile, mpt::as_span(reinterpret_cast<const std::byte*>(normalizeBuffer), lRead * m_SndFile.m_MixerSettings.gnChannels * sizeof(float))))
{
break;
}
} else
{
const std::streampos oldPos = fileStream.tellp();
switch(fileEnc->GetSampleFormat())
{
case SampleFormat::Float64:
fileEnc->WriteInterleaved(lRead, buffer.float64);
break;
case SampleFormat::Float32:
fileEnc->WriteInterleaved(lRead, buffer.float32);
break;
case SampleFormat::Int32:
fileEnc->WriteInterleaved(lRead, buffer.int32);
break;
case SampleFormat::Int24:
fileEnc->WriteInterleaved(lRead, buffer.int24);
break;
case SampleFormat::Int16:
fileEnc->WriteInterleaved(lRead, buffer.int16);
break;
case SampleFormat::Int8:
fileEnc->WriteInterleaved(lRead, buffer.int8);
break;
case SampleFormat::Unsigned8:
fileEnc->WriteInterleaved(lRead, buffer.uint8);
break;
}
const std::streampos newPos = fileStream.tellp();
bytesWritten += static_cast<uint64>(newPos - oldPos);
if(!fileStream)
{
break;
}
}
if(m_dwSongLimit && (ullSamples >= ullMaxSamples))
{
break;
}
auto currentTime = timeGetTime();
if((currentTime - prevTime) >= 16)
{
prevTime = currentTime;
DWORD seconds = (DWORD)(ullSamples / m_SndFile.m_MixerSettings.gdwMixingFreq);
if((ullSamples > 0) && (ullSamples < max))
{
timeRemaining = static_cast<uint32>((timeRemaining + ((currentTime - dwStartTime) * (max - ullSamples) / ullSamples) / 1000) / 2);
}
if(m_Settings.normalize)
{
SetText(MPT_CFORMAT("Rendering {}... ({}mn{}s, {}mn{}s remaining)")(caption, seconds / 60, mpt::ufmt::dec0<2>(seconds % 60u), timeRemaining / 60, mpt::ufmt::dec0<2>(timeRemaining % 60u)));
} else
{
SetText(MPT_CFORMAT("Writing {}... ({}kB, {}mn{}s, {}mn{}s remaining)")(caption, bytesWritten >> 10, seconds / 60, mpt::ufmt::dec0<2>(seconds % 60u), timeRemaining / 60, mpt::ufmt::dec0<2>(timeRemaining % 60u)));
}
SetProgress(ullSamples);
}
ProcessMessages();
if (m_abort)
{
ok = IDCANCEL;
break;
}
}
m_SndFile.m_nMaxOrderPosition = 0;
mainFrame->StopRenderer(&m_SndFile);
if(m_Settings.normalize)
{
const float normalizeFactor = (normalizePeak != 0.0f) ? (1.0f / normalizePeak) : 1.0f;
const uint64 framesTotal = ullSamples;
int lastPercent = -1;
mpt::IO::SeekAbsolute(*normalizeFile, 0);
uint64 framesProcessed = 0;
uint64 framesToProcess = framesTotal;
SetRange(0, framesTotal);
while(framesToProcess)
{
const std::size_t framesChunk = std::min(mpt::saturate_cast<std::size_t>(framesToProcess), std::size_t(MIXBUFFERSIZE));
const uint32 samplesChunk = static_cast<uint32>(framesChunk * channels);
const std::size_t bytes = samplesChunk * sizeof(float);
if(mpt::IO::ReadRaw(*normalizeFile, mpt::as_span(reinterpret_cast<std::byte*>(normalizeBuffer), bytes)).size() != bytes)
{
break;
}
for(std::size_t i = 0; i < samplesChunk; ++i)
{
normalizeBuffer[i] *= normalizeFactor;
}
const std::streampos oldPos = fileStream.tellp();
std::visit(
[&](auto& ditherInstance)
{
switch(fileEnc->GetSampleFormat())
{
case SampleFormat::Unsigned8:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<uint8>(buffer.uint8, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Int8:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<int8>(buffer.int8, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Int16:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<int16>(buffer.int16, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Int24:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<int24>(buffer.int24, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Int32:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<int32>(buffer.int32, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Float32:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<float>(buffer.float32, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
case SampleFormat::Float64:
ConvertBufferMixInternalToBuffer<false>(mpt::audio_span_interleaved<double>(buffer.float64, channels, framesChunk), mpt::audio_span_interleaved<const MixSampleFloat>(normalizeBuffer, channels, framesChunk), ditherInstance, channels, framesChunk);
break;
default: MPT_ASSERT_NOTREACHED(); break;
}
},
dithers.Variant()
);
switch(fileEnc->GetSampleFormat())
{
case SampleFormat::Float64:
fileEnc->WriteInterleaved(framesChunk, buffer.float64);
break;
case SampleFormat::Float32:
fileEnc->WriteInterleaved(framesChunk, buffer.float32);
break;
case SampleFormat::Int32:
fileEnc->WriteInterleaved(framesChunk, buffer.int32);
break;
case SampleFormat::Int24:
fileEnc->WriteInterleaved(framesChunk, buffer.int24);
break;
case SampleFormat::Int16:
fileEnc->WriteInterleaved(framesChunk, buffer.int16);
break;
case SampleFormat::Int8:
fileEnc->WriteInterleaved(framesChunk, buffer.int8);
break;
case SampleFormat::Unsigned8:
fileEnc->WriteInterleaved(framesChunk, buffer.uint8);
break;
}
const std::streampos newPos = fileStream.tellp();
bytesWritten += static_cast<std::size_t>(newPos - oldPos);
auto currentTime = timeGetTime();
if((currentTime - prevTime) >= 16)
{
prevTime = currentTime;
int percent = static_cast<int>(100 * framesProcessed / framesTotal);
if(percent != lastPercent)
{
SetText(MPT_CFORMAT("Normalizing... ({}%)")(percent));
SetProgress(framesProcessed);
lastPercent = percent;
}
ProcessMessages();
}
framesProcessed += framesChunk;
framesToProcess -= framesChunk;
}
mpt::IO::Flush(*normalizeFile);
normalizeFile.reset();
for(int retry=0; retry<10; retry++)
{
// stupid virus scanners
if(DeleteFile(normalizeFileName.AsNative().c_str()) != EACCES)
{
break;
}
Sleep(10);
}
}
if(!patternCuePoints.empty())
{
if(encSettings.Cues)
{
std::vector<uint64> cues;
cues.reserve(patternCuePoints.size());
for(const auto &cue : patternCuePoints)
{
cues.push_back(static_cast<uint32>(cue.offset));
}
fileEnc->WriteCues(cues);
}
}
m_SndFile.m_PatternCuePoints = nullptr;
fileEnc->WriteFinalize();
fileEnc = nullptr;
CMainFrame::UpdateAudioParameters(m_SndFile, TRUE);
EndDialog(ok);
}
OPENMPT_NAMESPACE_END