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livetrax/libs/ardour/midi_buffer.cc
Robin Gareus c5511040ec
MidiBuffer: allow for partial processing with offset
AudioBuffer::read_from() only replaces data within the given
range (offset .. n_samples + offset) leaving the rest of the
buffer untouched.

With in-place processing, where the same MIDI buffer is used
for input and output, each sub-cycle must only clear the
processed range, while leaving the rest of the buffer
untouched.
2023-06-30 17:12:16 +02:00

607 lines
15 KiB
C++

/*
* Copyright (C) 2007-2016 David Robillard <d@drobilla.net>
* Copyright (C) 2007-2017 Paul Davis <paul@linuxaudiosystems.com>
* Copyright (C) 2008-2009 Hans Baier <hansfbaier@googlemail.com>
* Copyright (C) 2009-2012 Carl Hetherington <carl@carlh.net>
* Copyright (C) 2014-2016 Robin Gareus <robin@gareus.org>
*
* This program 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.
*
* This program 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 this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <iostream>
#include "pbd/malign.h"
#include "pbd/compose.h"
#include "pbd/debug.h"
#include "pbd/stacktrace.h"
#include "ardour/debug.h"
#include "ardour/midi_buffer.h"
#include "ardour/port.h"
using namespace std;
using namespace ARDOUR;
using namespace PBD;
// FIXME: mirroring for MIDI buffers?
MidiBuffer::MidiBuffer(size_t capacity)
: Buffer (DataType::MIDI)
, _data (0)
, _size (0)
{
if (capacity) {
resize (capacity);
silence (capacity);
}
}
MidiBuffer::~MidiBuffer()
{
cache_aligned_free(_data);
}
void
MidiBuffer::resize (size_t size)
{
if (_data && size < _capacity) {
if (_size < size) {
/* truncate */
_size = size;
}
return;
}
uint8_t* old_data = _data;
cache_aligned_malloc ((void**) &_data, size);
if (_size) {
assert (old_data);
memcpy (_data, old_data, _size);
}
cache_aligned_free (old_data);
_capacity = size;
assert(_data);
}
void
MidiBuffer::copy(const MidiBuffer& copy)
{
assert(_capacity >= copy._size);
_size = copy._size;
memcpy(_data, copy._data, copy._size);
}
void
MidiBuffer::copy(MidiBuffer const * const copy)
{
assert(_capacity >= copy->size ());
_size = copy->size ();
memcpy(_data, copy->_data, _size);
}
void
MidiBuffer::read_from (const Buffer& src, samplecnt_t nframes, sampleoffset_t dst_offset, sampleoffset_t src_offset)
{
assert (src.type() == DataType::MIDI);
assert (&src != this);
const MidiBuffer& msrc = (const MidiBuffer&) src;
assert (_capacity >= msrc.size());
MidiBuffer::silence (nframes, dst_offset);
for (MidiBuffer::const_iterator i = msrc.begin(); i != msrc.end(); ++i) {
const Evoral::Event<TimeType> ev(*i, false);
if (ev.time() >= src_offset && ev.time() < nframes + src_offset) {
push_back (ev.time() + dst_offset - src_offset, ev.event_type (), ev.size(), ev.buffer());
}
}
_silent = src.silent();
}
void
MidiBuffer::merge_from (const Buffer& src, samplecnt_t /*nframes*/, sampleoffset_t /*dst_offset*/, sampleoffset_t /*src_offset*/)
{
const MidiBuffer* mbuf = dynamic_cast<const MidiBuffer*>(&src);
assert (mbuf);
assert (mbuf != this);
/* XXX use nframes, and possible offsets */
if (!merge_in_place (*mbuf)) {
cerr << string_compose ("MidiBuffer::merge_in_place failed (buffer is full: size: %1 capacity %2 new bytes %3)", _size, _capacity, mbuf->size()) << endl;
PBD::stacktrace (cerr, 20);
}
}
/** Push an event into the buffer.
*
* Note that the raw MIDI pointed to by ev will be COPIED and unmodified.
* That is, the caller still owns it, if it needs freeing it's Not My Problem(TM).
* Realtime safe.
* @return false if operation failed (not enough room)
*/
bool
MidiBuffer::push_back(const Evoral::Event<TimeType>& ev)
{
return push_back (ev.time(), ev.event_type (), ev.size(), ev.buffer());
}
/** Push MIDI data into the buffer.
*
* Note that the raw MIDI pointed to by @p data will be COPIED and unmodified.
* That is, the caller still owns it, if it needs freeing it's Not My Problem(TM).
* Realtime safe.
* @return false if operation failed (not enough room)
*/
bool
MidiBuffer::push_back(TimeType time, Evoral::EventType event_type, size_t size, const uint8_t* data)
{
const size_t stamp_size = sizeof(TimeType);
const size_t etype_size = sizeof(Evoral::EventType);
#ifndef NDEBUG
if (DEBUG_ENABLED(DEBUG::MidiIO)) {
DEBUG_STR_DECL(a);
DEBUG_STR_APPEND(a, string_compose ("midibuffer %1 push event @ %2 sz %3 ", this, time, size));
for (size_t i=0; i < size; ++i) {
DEBUG_STR_APPEND(a,hex);
DEBUG_STR_APPEND(a,"0x");
DEBUG_STR_APPEND(a,(int)data[i]);
DEBUG_STR_APPEND(a,' ');
}
DEBUG_STR_APPEND(a,'\n');
DEBUG_TRACE (DEBUG::MidiIO, DEBUG_STR(a).str());
}
#endif
if (_size + stamp_size + etype_size + size >= _capacity) {
return false;
}
if (!Evoral::midi_event_is_valid(data, size)) {
return false;
}
uint8_t* const write_loc = _data + _size;
*(reinterpret_cast<TimeType*>((uintptr_t)write_loc)) = time;
*(reinterpret_cast<Evoral::EventType*>((uintptr_t)(write_loc + stamp_size))) = event_type;
memcpy(write_loc + stamp_size + etype_size, data, size);
_size += align32 (stamp_size + etype_size + size);
_silent = false;
return true;
}
extern PBD::Timing minsert;
bool
MidiBuffer::insert_event(const Evoral::Event<TimeType>& ev)
{
if (size() == 0) {
return push_back(ev);
}
const size_t stamp_size = sizeof(TimeType);
const size_t etype_size = sizeof(Evoral::EventType);
const size_t bytes_to_merge = align32 (stamp_size + etype_size + ev.size());
if (_size + bytes_to_merge >= _capacity) {
cerr << string_compose ("MidiBuffer::push_back failed (buffer is full: size: %1 capacity %2 new bytes %3)", _size, _capacity, bytes_to_merge) << endl;
PBD::stacktrace (cerr, 20);
return false;
}
TimeType t = ev.time();
ssize_t insert_offset = -1;
for (MidiBuffer::iterator m = begin(); m != end(); ++m) {
if ((*m).time() < t) {
continue;
}
if ((*m).time() == t) {
const uint8_t our_midi_status_byte = *(_data + m.offset + stamp_size + etype_size);
if (second_simultaneous_midi_byte_is_first (ev.type(), our_midi_status_byte)) {
continue;
}
}
insert_offset = m.offset;
break;
}
if (insert_offset == -1) {
bool r = push_back(ev);
return r;
}
// don't use memmove - it may use malloc(!)
// memmove (_data + insert_offset + bytes_to_merge, _data + insert_offset, _size - insert_offset);
for (ssize_t a = _size + bytes_to_merge - 1, b = _size - 1; b >= insert_offset; --b, --a) {
_data[a] = _data[b];
}
uint8_t* const write_loc = _data + insert_offset;
assert((insert_offset + stamp_size + etype_size + ev.size()) <= _capacity);
*(reinterpret_cast<TimeType*>((uintptr_t)write_loc)) = t;
*(reinterpret_cast<Evoral::EventType*>((uintptr_t)(write_loc + stamp_size))) = ev.event_type ();
memcpy(write_loc + stamp_size + etype_size, ev.buffer(), ev.size());
_size += bytes_to_merge;
return true;
}
uint32_t
MidiBuffer::write(TimeType time, Evoral::EventType type, uint32_t size, const uint8_t* buf)
{
insert_event(Evoral::Event<TimeType>(type, time, size, const_cast<uint8_t*>(buf)));
return size;
}
/** Reserve space for a new event in the buffer.
*
* This call is for copying MIDI directly into the buffer, the data location
* (of sufficient size to write \a size bytes) is returned, or 0 on failure.
* This call MUST be immediately followed by a write to the returned data
* location, or the buffer will be corrupted and very nasty things will happen.
*/
uint8_t*
MidiBuffer::reserve(TimeType time, Evoral::EventType event_type, size_t size)
{
const size_t stamp_size = sizeof(TimeType);
const size_t etype_size = sizeof(Evoral::EventType);
if (align32 (_size + stamp_size + etype_size + size) >= _capacity) {
return 0;
}
// write timestamp and event-type
uint8_t* write_loc = _data + _size;
*(reinterpret_cast<TimeType*>((uintptr_t)write_loc)) = time;
*(reinterpret_cast<Evoral::EventType*>((uintptr_t)(write_loc + stamp_size))) = event_type;
// move write_loc to begin of MIDI buffer data to write to
write_loc += stamp_size + etype_size;
_size += align32 (stamp_size + etype_size + size);
_silent = false;
return write_loc;
}
void
MidiBuffer::clear ()
{
_size = 0;
_silent = true;
}
void
MidiBuffer::silence (samplecnt_t nframes, samplecnt_t offset)
{
/* iterate over existing events, find all in range given by offset & nframes,
* and delete them.
*/
if (nframes == _capacity && offset == 0) {
MidiBuffer::clear ();
return;
}
for (MidiBuffer::iterator i = begin(); i != end();) {
const Evoral::Event<TimeType> ev(*i, false);
if (ev.time() >= offset && ev.time() < nframes + offset) {
i = erase (i);
} else {
++i;
}
}
}
bool
MidiBuffer::second_simultaneous_midi_byte_is_first (uint8_t a, uint8_t b)
{
bool b_first = false;
/* two events at identical times. we need to determine
the order in which they should occur.
the rule is:
Controller messages
Program Change
Note Off
Note On
Note Pressure
Channel Pressure
Pitch Bend
*/
if ((a) >= 0xf0 || (b) >= 0xf0 || ((a & 0xf) != (b & 0xf))) {
/* if either message is not a channel message, or if the channels are
* different, we don't care about the type.
*/
b_first = true;
} else {
switch (b & 0xf0) {
case MIDI_CMD_CONTROL:
b_first = true;
break;
case MIDI_CMD_PGM_CHANGE:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
break;
case MIDI_CMD_PGM_CHANGE:
case MIDI_CMD_NOTE_OFF:
case MIDI_CMD_NOTE_ON:
case MIDI_CMD_NOTE_PRESSURE:
case MIDI_CMD_CHANNEL_PRESSURE:
case MIDI_CMD_BENDER:
b_first = true;
}
break;
case MIDI_CMD_NOTE_OFF:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
case MIDI_CMD_PGM_CHANGE:
break;
case MIDI_CMD_NOTE_OFF:
case MIDI_CMD_NOTE_ON:
case MIDI_CMD_NOTE_PRESSURE:
case MIDI_CMD_CHANNEL_PRESSURE:
case MIDI_CMD_BENDER:
b_first = true;
}
break;
case MIDI_CMD_NOTE_ON:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
case MIDI_CMD_PGM_CHANGE:
case MIDI_CMD_NOTE_OFF:
break;
case MIDI_CMD_NOTE_ON:
case MIDI_CMD_NOTE_PRESSURE:
case MIDI_CMD_CHANNEL_PRESSURE:
case MIDI_CMD_BENDER:
b_first = true;
}
break;
case MIDI_CMD_NOTE_PRESSURE:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
case MIDI_CMD_PGM_CHANGE:
case MIDI_CMD_NOTE_OFF:
case MIDI_CMD_NOTE_ON:
break;
case MIDI_CMD_NOTE_PRESSURE:
case MIDI_CMD_CHANNEL_PRESSURE:
case MIDI_CMD_BENDER:
b_first = true;
}
break;
case MIDI_CMD_CHANNEL_PRESSURE:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
case MIDI_CMD_PGM_CHANGE:
case MIDI_CMD_NOTE_OFF:
case MIDI_CMD_NOTE_ON:
case MIDI_CMD_NOTE_PRESSURE:
break;
case MIDI_CMD_CHANNEL_PRESSURE:
case MIDI_CMD_BENDER:
b_first = true;
}
break;
case MIDI_CMD_BENDER:
switch (a & 0xf0) {
case MIDI_CMD_CONTROL:
case MIDI_CMD_PGM_CHANGE:
case MIDI_CMD_NOTE_OFF:
case MIDI_CMD_NOTE_ON:
case MIDI_CMD_NOTE_PRESSURE:
case MIDI_CMD_CHANNEL_PRESSURE:
break;
case MIDI_CMD_BENDER:
b_first = true;
}
break;
}
}
return b_first;
}
/** Merge \a other into this buffer. Realtime safe. */
bool
MidiBuffer::merge_in_place (const MidiBuffer &other)
{
const size_t header_size = sizeof(TimeType) + sizeof(Evoral::EventType);
if (other.size() && size()) {
DEBUG_TRACE (DEBUG::MidiIO, string_compose ("merge in place, sizes %1/%2\n", size(), other.size()));
}
if (other.size() == 0) {
return true;
}
if (size() + other.size() > _capacity) {
return false;
}
if (size() == 0) {
copy (other);
return true;
}
const_iterator them = other.begin();
iterator us = begin();
while (them != other.end()) {
size_t bytes_to_merge;
ssize_t merge_offset;
/* gather up total size of events that are earlier than
the event referenced by "us"
*/
merge_offset = -1;
bytes_to_merge = 0;
while (them != other.end() && (*them).time() < (*us).time()) {
if (merge_offset == -1) {
merge_offset = them.offset;
}
bytes_to_merge += align32 (header_size + (*them).size());
++them;
}
/* "them" now points to either:
*
* 1) an event that has the same or later timestamp than the
* event pointed to by "us"
*
* OR
*
* 2) the end of the "other" buffer
*
* if "sz" is non-zero, there is data to be merged from "other"
* into this buffer before we do anything else, corresponding
* to the events from "other" that we skipped while advancing
* "them".
*/
if (bytes_to_merge) {
assert(merge_offset >= 0);
/* move existing */
memmove (_data + us.offset + bytes_to_merge, _data + us.offset, _size - us.offset);
/* increase _size */
_size += bytes_to_merge;
assert (_size <= _capacity);
/* insert new stuff */
memcpy (_data + us.offset, other._data + merge_offset, bytes_to_merge);
/* update iterator to our own events. this is a miserable hack */
us.offset += bytes_to_merge;
}
/* if we're at the end of the other buffer, we're done */
if (them == other.end()) {
break;
}
/* if we have two messages messages with the same timestamp. we
* must order them correctly.
*/
if ((*us).time() == (*them).time()) {
DEBUG_TRACE (DEBUG::MidiIO,
string_compose ("simultaneous MIDI events discovered during merge, times %1/%2 status %3/%4\n",
(*us).time(), (*them).time(),
(int) *(_data + us.offset + header_size),
(int) *(other._data + them.offset + header_size)));
uint8_t our_midi_status_byte = *(_data + us.offset + header_size);
uint8_t their_midi_status_byte = *(other._data + them.offset + header_size);
bool them_first = second_simultaneous_midi_byte_is_first (our_midi_status_byte, their_midi_status_byte);
DEBUG_TRACE (DEBUG::MidiIO, string_compose ("other message came first ? %1\n", them_first));
if (!them_first) {
/* skip past our own event */
++us;
}
bytes_to_merge = align32 (header_size + (*them).size());
/* move our remaining events later in the buffer by
* enough to fit the one message we're going to merge
*/
memmove (_data + us.offset + bytes_to_merge, _data + us.offset, _size - us.offset);
/* increase _size */
_size += bytes_to_merge;
assert(_size <= _capacity);
/* insert new stuff */
memcpy (_data + us.offset, other._data + them.offset, bytes_to_merge);
/* update iterator to our own events. this is a miserable hack */
us.offset += bytes_to_merge;
/* 'us' is now an iterator to the event right after the
new ones that we merged
*/
if (them_first) {
/* need to skip the event pointed to by 'us'
since its at the same time as 'them'
(still), and we'll enter
*/
if (us != end()) {
++us;
}
}
/* we merged one event from the other buffer, so
* advance the iterator there.
*/
++them;
} else {
/* advance past our own events to get to the correct insertion
point for the next event(s) from "other"
*/
while (us != end() && (*us).time() <= (*them).time()) {
++us;
}
}
/* check to see if we reached the end of this buffer while
* looking for the insertion point.
*/
if (us == end()) {
/* just append the rest of other and we're done*/
memcpy (_data + us.offset, other._data + them.offset, other._size - them.offset);
_size += other._size - them.offset;
assert(_size <= _capacity);
break;
}
}
return true;
}