*/
#include "pbd/compose.h"
+#include "pbd/enumwriter.h"
#include "pbd/error.h"
#include "ardour/debug.h"
#include "ardour/event_type_map.h"
using namespace std;
-using namespace ARDOUR;
using namespace PBD;
+namespace ARDOUR {
+
/** Read a block of MIDI events from this buffer into a MidiBuffer.
*
* Timestamps of events returned are relative to start (i.e. event with stamp 0
}
T ev_time;
- Evoral::EventType ev_type;
uint32_t ev_size;
-
- /* If we see the end of a loop during this read, we must write the events after it
- to the MidiBuffer with adjusted times. The situation is as follows:
-
- session frames----------------------------->
-
- | | |
- start_of_loop start end_of_loop
-
- The MidiDiskstream::read method which will have happened before this checks for
- loops ending, and helpfully inserts a magic LoopEvent into the ringbuffer. After this,
- the MidiDiskstream continues to write events with their proper session frame times,
- so after the LoopEvent event times will go backwards (ie non-monotonically).
-
- Once we hit end_of_loop, we need to fake it to make it look as though the loop has been
- immediately repeated. Say that an event E after the end_of_loop in the ringbuffer
- has time E_t, which is a time in session frames. Its offset from the start
- of the loop will be E_t - start_of_loop. Its `faked' time will therefore be
- end_of_loop + E_t - start_of_loop. And so its port-buffer-relative time (for
- writing to the MidiBuffer) will be end_of_loop + E_t - start_of_loop - start.
-
- The subtraction of start is already taken care of, so if we see a LoopEvent, we'll
- set up loop_offset to equal end_of_loop - start_of_loop, so that given an event
- time E_t in the ringbuffer we can get the port-buffer-relative time as
- E_t + offset - start.
- */
-
- frameoffset_t loop_offset = 0;
-
- size_t count = 0;
-
- const size_t prefix_size = sizeof(T) + sizeof(Evoral::EventType) + sizeof(uint32_t);
+ size_t count = 0;
+ const size_t prefix_size = sizeof(T) + sizeof(Evoral::EventType) + sizeof(uint32_t);
while (this->read_space() >= prefix_size) {
uint8_t peekbuf[prefix_size];
- bool success;
- success = this->peek (peekbuf, prefix_size);
/* this cannot fail, because we've already verified that there
is prefix_space to read
*/
- assert (success);
+ this->peek (peekbuf, prefix_size);
ev_time = *((T*) peekbuf);
- ev_type = *((Evoral::EventType*)(peekbuf + sizeof (T)));
ev_size = *((uint32_t*)(peekbuf + sizeof(T) + sizeof (Evoral::EventType)));
- if (ev_time + loop_offset >= end) {
+ if (ev_time >= end) {
DEBUG_TRACE (DEBUG::MidiDiskstreamIO, string_compose ("MRB event @ %1 past end @ %2\n", ev_time, end));
break;
- } else if (ev_time + loop_offset < start) {
+ } else if (ev_time < start) {
DEBUG_TRACE (DEBUG::MidiDiskstreamIO, string_compose ("MRB event @ %1 before start @ %2\n", ev_time, start));
break;
} else {
DEBUG_TRACE (DEBUG::MidiDiskstreamIO, string_compose ("MRB event @ %1 in range %2 .. %3\n", ev_time, start, end));
}
- assert(ev_time >= start);
-
ev_time -= start;
ev_time += offset;
- // This event marks a loop end (i.e. the next event's timestamp
- // will be non-monotonic). Don't write it into the buffer - the
- // significance of this event ends here.
-
- if (ev_type == LoopEventType) {
- assert (ev_size == sizeof (framepos_t));
- framepos_t loop_start;
- read_contents (ev_size, (uint8_t *) &loop_start);
- loop_offset = ev_time - loop_start;
- _tracker.resolve_notes (dst, ev_time);
- continue;
- }
-
/* we're good to go ahead and read the data now but since we
* have the prefix data already, just skip over that
*/
this->increment_read_ptr (prefix_size);
- ev_time += loop_offset;
uint8_t status;
- success = this->peek (&status, sizeof(uint8_t));
- assert(success); // If this failed, buffer is corrupt, all hope is lost
-
- // Ignore event if it doesn't match channel filter
- if (is_channel_event(status) && get_channel_mode() == FilterChannels) {
- const uint8_t channel = status & 0x0F;
- if (!(get_channel_mask() & (1L << channel))) {
- DEBUG_TRACE (DEBUG::MidiDiskstreamIO, string_compose ("MRB skipping event (%3 bytes) due to channel mask (mask = %1 chn = %2)\n",
- get_channel_mask(), (int) channel, ev_size));
- this->increment_read_ptr (ev_size); // Advance read pointer to next event
- continue;
- }
- }
+ bool r = this->peek (&status, sizeof(uint8_t));
+ assert (r); // If this failed, buffer is corrupt, all hope is lost
/* lets see if we are going to be able to write this event into dst.
*/
}
// write MIDI buffer contents
- success = read_contents (ev_size, write_loc);
+ bool success = read_contents (ev_size, write_loc);
#ifndef NDEBUG
if (DEBUG::MidiDiskstreamIO && PBD::debug_bits) {
} else if (is_note_off(write_loc[0])) {
_tracker.remove (write_loc[1], write_loc[0] & 0xf);
}
-
- if (is_channel_event(status) && get_channel_mode() == ForceChannel) {
- write_loc[0] = (write_loc[0] & 0xF0) | (get_channel_mask() & 0x0F);
- }
+
++count;
} else {
cerr << "WARNING: error reading event contents from MIDI ring" << endl;
return count;
}
+template<typename T>
+void
+MidiRingBuffer<T>::flush (framepos_t /*start*/, framepos_t end)
+{
+ const size_t prefix_size = sizeof(T) + sizeof(Evoral::EventType) + sizeof(uint32_t);
+
+ while (this->read_space() >= prefix_size) {
+ uint8_t peekbuf[prefix_size];
+ bool success;
+ uint32_t ev_size;
+ T ev_time;
+
+ success = this->peek (peekbuf, prefix_size);
+ /* this cannot fail, because we've already verified that there
+ is prefix_space to read
+ */
+ assert (success);
+
+ ev_time = *((T*) peekbuf);
+
+ if (ev_time >= end) {
+ break;
+ }
+
+ ev_size = *((uint32_t*)(peekbuf + sizeof(T) + sizeof (Evoral::EventType)));
+ this->increment_read_ptr (prefix_size);
+ this->increment_read_ptr (ev_size);
+ }
+}
+
template<typename T>
void
MidiRingBuffer<T>::dump(ostream& str)
_tracker.reset ();
}
+template<typename T>
+void
+MidiRingBuffer<T>::loop_resolve (MidiBuffer& dst, framepos_t t)
+{
+ _tracker.resolve_notes (dst, t);
+}
+
template class MidiRingBuffer<framepos_t>;
+} // namespace ARDOUR