mkxp/src/midisource.cpp

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/*
** midisource.cpp
**
** This file is part of mkxp.
**
** Copyright (C) 2014 Jonas Kulla <Nyocurio@gmail.com>
**
** mkxp is free software: you can redistribute it and/or modify
** it under the terms of the GNU General Public License as published by
** the Free Software Foundation, either version 2 of the License, or
** (at your option) any later version.
**
** mkxp is distributed in the hope that it will be useful,
** but WITHOUT ANY WARRANTY; without even the implied warranty of
** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
** GNU General Public License for more details.
**
** You should have received a copy of the GNU General Public License
** along with mkxp. If not, see <http://www.gnu.org/licenses/>.
*/
#include "aldatasource.h"
#include "al-util.h"
#include "exception.h"
#include "sharedstate.h"
#include "sharedmidistate.h"
#include "util.h"
#include "debugwriter.h"
#include "fluid-fun.h"
#include <SDL_rwops.h>
#include <assert.h>
#include <math.h>
#include <vector>
#include <algorithm>
#include <string>
/* Vocabulary:
*
* Tick:
* Ticks are the smallest batch of samples that fluidsynth
* allows midi state changes to take effect in, ie. if two midi
* events are fired within less than a tick, it will look as
* if they fired at the same time. Midisource therefore always
* synthesizes sample blocks which are multiples of ticks.
* One tick is 64 samples, or 32 frames with two channels.
*
* Delta:
* Deltas are the abstract time unit in which the relative
* offsets between midi events are encoded.
*/
#define TICK_FRAMES 32
#define BUF_TICKS (STREAM_BUF_SIZE / TICK_FRAMES)
#define DEFAULT_BPM 120
#define MAX_CHANNELS 16
#define CC_CTRL_VOLUME 7
#define CC_CTRL_EXPRESSION 11
#define CC_CTRL_LOOP 111
#define CC_VAL_DEFAULT 127
enum MidiEventType
{
NoteOff,
NoteOn,
ChanTouch,
PitchBend,
CC,
PC,
Tempo,
Last
};
struct ChannelEvent
{
uint8_t chan;
};
struct NoteEvent : ChannelEvent
{
uint8_t key;
uint8_t vel;
};
struct NoteTouchEvent : ChannelEvent
{
uint8_t val;
};
struct PitchBendEvent : ChannelEvent
{
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uint16_t val;
};
struct CCEvent : ChannelEvent
{
uint8_t ctrl;
uint8_t val;
};
struct PCEvent : ChannelEvent
{
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uint8_t prog;
};
struct TempoEvent
{
uint32_t bpm;
};
struct MidiEvent
{
MidiEventType type;
uint32_t delta;
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union
{
ChannelEvent chan;
NoteEvent note;
NoteTouchEvent chanTouch;
PitchBendEvent pitchBend;
CCEvent cc;
PCEvent pc;
TempoEvent tempo;
} e;
};
struct MidiReadHandler
{
virtual void onMidiHeader(uint16_t midiType, uint16_t trackCount, uint16_t division) = 0;
virtual void onMidiTrackBegin() = 0;
virtual void onMidiEvent(const MidiEvent &e, uint32_t absDelta) = 0;
};
static void
badMidiFormat()
{
throw Exception(Exception::MKXPError, "Midi: Bad format");
}
/* File-like interface to a read-only memory buffer */
struct MemChunk
{
const std::vector<uint8_t> &data;
size_t i;
MemChunk(const std::vector<uint8_t> &data)
: data(data),
i(0)
{}
uint8_t readByte()
{
if (i >= data.size())
endOfFile();
return data[i++];
}
void readData(void *buf, size_t n)
{
if (i + n > data.size())
endOfFile();
memcpy(buf, &data[i], n);
i += n;
}
void skipData(size_t n)
{
if ((i += n) > data.size())
endOfFile();
}
void endOfFile()
{
throw Exception(Exception::MKXPError, "Midi: EOF");
}
};
static uint32_t
readVarNum(MemChunk &chunk)
{
uint32_t result = 0;
uint8_t byte;
uint8_t len = 0;
do
{
/* A variable length number can at most be made of 4 bytes */
if (++len > 4)
badMidiFormat();
byte = chunk.readByte();
result = (result << 0x7) | (byte & 0x7F);
}
while (byte & 0x80);
return result;
}
template<typename T>
static T readBigEndian(MemChunk &chunk)
{
T result = 0;
for (size_t i = 0; i < sizeof(T); ++i)
result = (result << 0x8) | chunk.readByte();
return result;
}
static void
readVoiceEvent(MidiEvent &e, MemChunk &chunk,
uint8_t type, uint8_t data1, bool &handled)
{
e.e.chan.chan = (type & 0x0F);
uint8_t tmp;
switch (type >> 4)
{
case 0x8 :
e.type = NoteOff;
e.e.note.key = data1;
chunk.readByte(); /* We don't care about velocity */
break;
case 0x9 :
e.type = NoteOn;
e.e.note.key = data1;
e.e.note.vel = chunk.readByte();
break;
case 0xA :
/* Note aftertouch unhandled */
handled = false;
break;
case 0xB :
e.type = CC;
e.e.cc.ctrl = data1;
e.e.cc.val = chunk.readByte();
break;
case 0xC :
e.type = PC;
e.e.pc.prog = data1;
break;
case 0xD :
e.type = ChanTouch;
e.e.chanTouch.val = data1;
break;
case 0xE :
e.type = PitchBend;
tmp = chunk.readByte();
e.e.pitchBend.val = ((tmp & 0x7F) << 7) | (data1 & 0x7F);
break;
default :
assert(!"unreachable");
break;
}
}
static void
readEvent(MidiReadHandler *handler, MemChunk &chunk,
uint8_t &prevType, uint32_t &deltaBase, uint32_t &deltaCarry,
bool &endOfTrack)
{
MidiEvent e;
bool handled = true;
e.delta = readVarNum(chunk);
uint8_t type = chunk.readByte();
/* Check for running status */
if (!(type & 0x80))
{
/* Running status for meta/system events is not allowed */
if (prevType == 0)
badMidiFormat();
/* Running status voice event: 'type' becomes
* first data byte instead */
readVoiceEvent(e, chunk, prevType, type, handled);
goto event_read;
}
if ((type >> 4) != 0xF)
{
/* Normal voice event */
readVoiceEvent(e, chunk, type, chunk.readByte(), handled);
prevType = type;
}
else if (type == 0xFF)
{
/* Meta event */
uint8_t metaType = chunk.readByte();
uint32_t len = readVarNum(chunk);
if (metaType == 0x51)
{
/* Tempo event */
if (len != 3)
badMidiFormat();
uint8_t data[3];
chunk.readData(data, 3);
uint32_t mpqn = (data[0] << 0x10)
| (data[1] << 0x08)
| (data[2] << 0x00);
e.type = Tempo;
e.e.tempo.bpm = 60000000.0 / mpqn;
}
else if (metaType == 0x2F)
{
/* End-of-track event */
if (len != 0)
badMidiFormat();
endOfTrack = true;
handled = false;
}
else
{
handled = false;
}
if (!handled)
chunk.skipData(len);
prevType = 0;
}
else if (type == 0xF0 || type == 0xF7)
{
/* SysEx event */
uint32_t len = readVarNum(chunk);
handled = false;
chunk.skipData(len);
prevType = 0;
}
else
{
badMidiFormat();
}
event_read:
if (handled)
{
e.delta += deltaCarry;
deltaCarry = 0;
deltaBase += e.delta;
handler->onMidiEvent(e, deltaBase);
}
else
{
deltaCarry += e.delta;
}
}
void readMidiTrack(MidiReadHandler *handler, MemChunk &chunk)
{
/* Track signature */
char sig[5] = { 0 };
chunk.readData(sig, 4);
if (strcmp(sig, "MTrk"))
badMidiFormat();
handler->onMidiTrackBegin();
uint32_t trackLen = readBigEndian<uint32_t>(chunk);
/* The combined delta of all events on this track so far */
uint32_t deltaBase = 0;
/* If we don't care about an event, instead of inserting a
* useless event, we carry over its delta into the next one */
uint32_t deltaCarry = 0;
/* Holds the previous status byte for voice event, in case
* we encounter a running status */
uint8_t prevType = 0;
/* The 'EndOfTrack' meta event will toggle this flag on */
bool endOfTrack = false;
size_t savedPos = chunk.i;
/* Read all events */
while (!endOfTrack)
readEvent(handler, chunk, prevType, deltaBase, deltaCarry, endOfTrack);
/* Check that the track byte length from the header
* matches the amount we actually ended up reading */
if ((chunk.i - savedPos) != trackLen)
badMidiFormat();
}
void readMidi(MidiReadHandler *handler, const std::vector<uint8_t> &data)
{
MemChunk chunk(data);
/* Midi signature */
char sig[5] = { 0 };
chunk.readData(sig, 4);
if (strcmp(sig, "MThd"))
badMidiFormat();
/* Header length must always be 6 */
uint32_t hdrLen = readBigEndian<uint32_t>(chunk);
if (hdrLen != 6)
badMidiFormat();
/* Only types 0, 1, 2 exist */
uint16_t type = readBigEndian<uint16_t>(chunk);
if (type > 2)
badMidiFormat();
/* Type 0 only contains one track */
uint16_t trackCount = readBigEndian<uint16_t>(chunk);
if (trackCount == 0)
badMidiFormat();
if (type == 0 && trackCount > 1)
badMidiFormat();
uint16_t timeDiv = readBigEndian<uint16_t>(chunk);
handler->onMidiHeader(type, trackCount, timeDiv);
/* Read tracks */
for (uint16_t i = 0; i < trackCount; ++i)
readMidiTrack(handler, chunk);
}
struct Track
{
std::vector<MidiEvent> events;
/* Combined deltas of all events */
uint64_t length;
/* Event index that is resumed from after loop wraparound */
int32_t loopI;
/* Difference between last event's position and length of
* the longest overall track / song length */
uint32_t loopOffsetEnd;
/* Delta offset from the loop beginning to event[loopI] */
uint32_t loopOffsetStart;
bool valid;
MidiEvent event;
int32_t remDeltas;
uint32_t index;
bool wrapAroundFlag;
bool atEnd;
Track()
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: length(0),
loopI(-1),
loopOffsetEnd(0),
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loopOffsetStart(0),
valid(false),
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index(0),
wrapAroundFlag(false),
atEnd(false)
{}
void appendEvent(const MidiEvent &e)
{
length += e.delta;
events.push_back(e);
}
void scheduleEvent(bool looped)
{
if (valid)
return;
/* At end and not looped? */
if (index == events.size() && ((!looped || loopI < 0) || length == 0))
{
valid = false;
atEnd = true;
return;
}
MidiEvent &e = events[index++];
event = e;
remDeltas = e.delta;
valid = true;
if (wrapAroundFlag)
{
remDeltas = loopOffsetEnd + loopOffsetStart;
wrapAroundFlag = false;
}
if (looped && (index == events.size()) && loopI >= 0)
{
index = loopI;
wrapAroundFlag = true;
}
}
void reset()
{
valid = false;
index = 0;
wrapAroundFlag = false;
atEnd = false;
}
};
/* Some songs use CC events for effects like fade-out,
* slowly decreasing a channel's volume to 0. The problem is that
* for looped songs, events are continuously fed into the synth
* without restoring those controls back to their default value.
* We can't reset them at the very beginning of tracks because it
* might cause audible interactions with notes which are still decaying
* past the end of the song. Therefore, we insert a fake CC event right
* after the first NoteOn event for each channel which resets the
* control to its default state while avoiding audible glitches.
* If there is already a CC event for this control before the first
* NoteOn event, we don't clobber it by not inserting our fake event. */
template<uint8_t ctrl>
struct CCResetter
{
bool chanHandled[MAX_CHANNELS];
CCResetter()
{
memset(&chanHandled, 0, sizeof(chanHandled));
}
void handleEvent(const MidiEvent &e, Track &track)
{
if (e.type != NoteOn && e.type != CC)
return;
uint8_t chan = e.e.chan.chan;
if (chanHandled[chan])
return;
if (e.type == CC && e.e.cc.ctrl == ctrl)
{
/* Don't clobber the existing CC value */
chanHandled[chan] = true;
return;
}
else if (e.type == NoteOn)
{
chanHandled[chan] = true;
MidiEvent re;
re.delta = 0;
re.type = CC;
re.e.cc.chan = chan;
re.e.cc.ctrl = ctrl;
re.e.cc.val = CC_VAL_DEFAULT;
track.appendEvent(re);
}
}
};
struct MidiSource : ALDataSource, MidiReadHandler
{
const uint16_t freq;
fluid_synth_t *synth;
int16_t synthBuf[BUF_TICKS*TICK_FRAMES*2];
std::vector<Track> tracks;
CCResetter<CC_CTRL_VOLUME> volReset;
CCResetter<CC_CTRL_EXPRESSION> expReset;
/* Index of longest track */
uint8_t longestI;
bool looped;
/* Absolute delta at which we received the LOOP_MARKER CC event */
uint32_t loopDelta;
/* Deltas per beat */
uint16_t dpb;
int8_t pitchShift;
/* Deltas per tick */
float playbackSpeed;
float genDeltasCarry;
/* MidiReadHandler (track that's currently being read) */
int16_t curTrack;
MidiSource(SDL_RWops &ops,
bool looped)
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: freq(SYNTH_SAMPLERATE),
looped(looped),
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dpb(480),
pitchShift(0),
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genDeltasCarry(0),
curTrack(-1)
{
size_t dataLen = SDL_RWsize(&ops);
std::vector<uint8_t> data(dataLen);
if (SDL_RWread(&ops, &data[0], 1, dataLen) < dataLen)
throw Exception(Exception::MKXPError, "Reading midi data failed");
readMidi(this, data);
synth = shState->midiState().allocateSynth();
uint64_t longest = 0;
for (size_t i = 0; i < tracks.size(); ++i)
if (tracks[i].length > longest)
{
longest = tracks[i].length;
longestI = i;
}
for (size_t i = 0; i < tracks.size(); ++i)
tracks[i].loopOffsetEnd = longest - tracks[i].length;
/* Enterbrain likes to be funny and put loop markers at
* the very end of ME tracks */
if (loopDelta >= longest)
loopDelta = 0;
for (size_t i = 0; i < tracks.size(); ++i)
{
Track &track = tracks[i];
int64_t base = 0;
for (size_t j = 0; j < track.events.size(); ++j)
{
MidiEvent &e = track.events[j];
base += e.delta;
if (base < loopDelta)
continue;
/* Don't make the last event loop eternally */
if (j < track.events.size())
{
track.loopI = j;
track.loopOffsetStart = base - loopDelta;
}
break;
}
}
updatePlaybackSpeed(DEFAULT_BPM);
// FIXME: It would make the code in 'fillBuffer' a lot nicer if
// we could combine all tracks into one giant one on construction,
// instead of having to constantly iterate through all of them
}
~MidiSource()
{
shState->midiState().releaseSynth(synth);
}
void updatePlaybackSpeed(uint32_t bpm)
{
float deltaLength = 60.0 / (dpb * bpm);
playbackSpeed = TICK_FRAMES / (deltaLength * freq);
}
void activateEvent(const MidiEvent &e)
{
int16_t key = e.e.note.key;
/* Apply pitch shift if necessary */
if ((e.type == NoteOn || e.type == NoteOff) && e.e.chan.chan != 9)
{
key += pitchShift;
/* Drop events whose keys are out of bounds */
if (key < 0 || key > 127)
return;
}
switch (e.type)
{
case NoteOn:
fluid.synth_noteon(synth, e.e.note.chan, key, e.e.note.vel);
break;
case NoteOff:
fluid.synth_noteoff(synth, e.e.note.chan, key);
break;
case ChanTouch:
fluid.synth_channel_pressure(synth, e.e.chanTouch.chan, e.e.chanTouch.val);
break;
case PitchBend:
fluid.synth_pitch_bend(synth, e.e.pitchBend.chan, e.e.pitchBend.val);
break;
case CC:
fluid.synth_cc(synth, e.e.cc.chan, e.e.cc.ctrl, e.e.cc.val);
break;
case PC:
fluid.synth_program_change(synth, e.e.pc.chan, e.e.pc.prog);
break;
case Tempo:
updatePlaybackSpeed(e.e.tempo.bpm);
break;
default:
break;
}
}
void renderTicks(size_t count, size_t offset)
{
size_t bufOffset = offset * TICK_FRAMES * 2;
int len = count * TICK_FRAMES;
void *buffer = &synthBuf[bufOffset];
fluid.synth_write_s16(synth, len, buffer, 0, 2, buffer, 1, 2);
}
/* MidiReadHandler */
void onMidiHeader(uint16_t midiType, uint16_t trackCount, uint16_t division)
{
if (midiType != 0 && midiType != 1)
throw Exception(Exception::MKXPError, "Midi: Type 2 not supported");
tracks.resize(trackCount);
// SMTP unhandled
if (division & 0x8000)
throw Exception(Exception::MKXPError, "Midi: SMTP parameters not supported");
else
dpb = division;
}
void onMidiTrackBegin()
{
++curTrack;
}
void onMidiEvent(const MidiEvent &e, uint32_t absDelta)
{
assert(curTrack >= 0 && curTrack < (int16_t) tracks.size());
Track &track = tracks[curTrack];
track.appendEvent(e);
volReset.handleEvent(e, track);
expReset.handleEvent(e, track);
if (e.type == CC && e.e.cc.ctrl == CC_CTRL_LOOP)
loopDelta = absDelta;
}
/* ALDataSource */
Status fillBuffer(AL::Buffer::ID buf)
{
/* In case there is no currently scheduled one */
for (size_t i = 0; i < tracks.size(); ++i)
tracks[i].scheduleEvent(looped);
size_t remTicks = BUF_TICKS;
/* Iterate until all ticks that fit into the buffer
* have been rendered */
while (remTicks > 0)
{
/* Check for events that have to be activated now, activate them,
* and schedule new ones if the queue isn't empty */
for (size_t i = 0; i < tracks.size(); ++i)
{
Track &track = tracks[i];
/* We have to loop and ensure that the final scheduled
* event lies in the future, as multiple events might
* have to be activated at once */
while (true)
{
if (!track.valid || track.remDeltas > 0)
break;
int32_t prevOffset = track.remDeltas;
activateEvent(track.event);
track.valid = false;
track.scheduleEvent(looped);
/* Negative deltas from the previous event have to
* be carried over into the next to stay in sync */
if (prevOffset < 0)
track.remDeltas += prevOffset;
/* Ensure it lies in the future */
if (track.remDeltas > 0)
break;
}
}
size_t nextEvent = (size_t) -1;
bool allInvalid = true;
/* Search all tracks for the temporally nearest event */
for (size_t i = 0; i < tracks.size(); ++i)
{
Track &track = tracks[i];
if (!track.valid)
continue;
allInvalid = false;
uint32_t remDelta = track.remDeltas / playbackSpeed;
/* We need to render at least one tick regardless to
* avoid an endless loop of waiting for the next event
* to become current */
if (remDelta < nextEvent)
nextEvent = std::max<uint32_t>(remDelta, 1);
}
/* Calculate amount of ticks we'll render next */
size_t genTicks = allInvalid ? remTicks : std::min(remTicks, nextEvent);
if (genTicks == 0)
continue;
renderTicks(genTicks, BUF_TICKS - remTicks);
remTicks -= genTicks;
float genDeltas = (genTicks * playbackSpeed) + genDeltasCarry;
float intDeltas;
genDeltasCarry = modff(genDeltas, &intDeltas);
/* Substract integer part of consumed deltas while carrying
* over the fractional amount into the next iteration */
for (size_t i = 0; i < tracks.size(); ++i)
if (tracks[i].valid)
tracks[i].remDeltas -= intDeltas;
}
/* Fill AL buffer */
AL::Buffer::uploadData(buf, AL_FORMAT_STEREO16, synthBuf, sizeof(synthBuf), freq);
if (tracks[longestI].atEnd)
return EndOfStream;
return NoError;
}
int sampleRate()
{
return freq;
}
/* Midi sources cannot seek, and so always reset to beginning */
void seekToOffset(float)
{
/* Reset synth */
fluid.synth_system_reset(synth);
/* Reset runtime variables */
genDeltasCarry = 0;
updatePlaybackSpeed(DEFAULT_BPM);
/* Reset tracks */
for (size_t i = 0; i < tracks.size(); ++i)
tracks[i].reset();
}
uint32_t loopStartFrames() { return 0; }
bool setPitch(float value)
{
// not completely correct, but close
pitchShift = round((value > 1.0 ? 14 : 24) * (value - 1.0));
return true;
}
};
ALDataSource *createMidiSource(SDL_RWops &ops,
bool looped)
{
return new MidiSource(ops, looped);
}