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livetrax/libs/surfaces/tranzport/tranzport_control_protocol.cc
Hans Fugal 79986643c0 r269@gandalf: fugalh | 2006-08-03 20:18:05 -0600
Trunk merge conflicts resolved


git-svn-id: svn://localhost/ardour2/branches/undo@756 d708f5d6-7413-0410-9779-e7cbd77b26cf
2006-08-04 02:18:45 +00:00

1589 lines
30 KiB
C++

/*
Copyright (C) 2006 Paul Davis
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., 675 Mass Ave, Cambridge, MA 02139, USA.
$Id$
*/
#include <iostream>
#include <algorithm>
#include <cmath>
#define __STDC_FORMAT_MACROS
#include <inttypes.h>
#include <float.h>
#include <sys/time.h>
#include <errno.h>
#include <pbd/pthread_utils.h>
#include <ardour/route.h>
#include <ardour/audio_track.h>
#include <ardour/session.h>
#include <ardour/location.h>
#include <ardour/dB.h>
#include "tranzport_control_protocol.h"
using namespace ARDOUR;
using namespace std;
using namespace sigc;
using namespace PBD;
#include "i18n.h"
#include <pbd/abstract_ui.cc>
BaseUI::RequestType LEDChange = BaseUI::new_request_type ();
BaseUI::RequestType Print = BaseUI::new_request_type ();
BaseUI::RequestType SetCurrentTrack = BaseUI::new_request_type ();
static inline double
gain_to_slider_position (ARDOUR::gain_t g)
{
if (g == 0) return 0;
return pow((6.0*log(g)/log(2.0)+192.0)/198.0, 8.0);
}
static inline ARDOUR::gain_t
slider_position_to_gain (double pos)
{
/* XXX Marcus writes: this doesn't seem right to me. but i don't have a better answer ... */
if (pos == 0.0) return 0;
return pow (2.0,(sqrt(sqrt(sqrt(pos)))*198.0-192.0)/6.0);
}
TranzportControlProtocol::TranzportControlProtocol (Session& s)
: ControlProtocol (s, X_("Tranzport"))
{
/* tranzport controls one track at a time */
set_route_table_size (1);
timeout = 60000;
buttonmask = 0;
_datawheel = 0;
_device_status = STATUS_OFFLINE;
udev = 0;
current_track_id = 0;
last_where = max_frames;
wheel_mode = WheelTimeline;
wheel_shift_mode = WheelShiftGain;
timerclear (&last_wheel_motion);
last_wheel_dir = 1;
last_track_gain = FLT_MAX;
display_mode = DisplayNormal;
gain_fraction = 0.0;
memset (current_screen, 0, sizeof (current_screen));
memset (pending_screen, 0, sizeof (pending_screen));
for (uint32_t i = 0; i < sizeof(lights)/sizeof(lights[0]); ++i) {
lights[i] = false;
}
for (uint32_t i = 0; i < sizeof(pending_lights)/sizeof(pending_lights[0]); ++i) {
pending_lights[i] = false;
}
}
TranzportControlProtocol::~TranzportControlProtocol ()
{
set_active (false);
}
bool
TranzportControlProtocol::probe ()
{
struct usb_bus *bus;
struct usb_device *dev;
usb_init();
usb_find_busses();
usb_find_devices();
for (bus = usb_busses; bus; bus = bus->next) {
for(dev = bus->devices; dev; dev = dev->next) {
if (dev->descriptor.idVendor == VENDORID && dev->descriptor.idProduct == PRODUCTID) {
return true;
}
}
}
return false;
}
int
TranzportControlProtocol::set_active (bool yn)
{
if (yn != _active) {
if (yn) {
if (open ()) {
return -1;
}
if (pthread_create_and_store (X_("tranzport monitor"), &thread, 0, _monitor_work, this) == 0) {
_active = true;
} else {
return -1;
}
} else {
cerr << "Begin tranzport shutdown\n";
pthread_cancel_one (thread);
cerr << "Thread dead\n";
// lcd_clear ();
// lights_off ();
// cerr << "dev reset\n";
close ();
_active = false;
cerr << "End tranzport shutdown\n";
}
}
return 0;
}
void
TranzportControlProtocol::show_track_gain ()
{
if (route_table[0]) {
gain_t g = route_get_gain (0);
if (g != last_track_gain) {
char buf[16];
snprintf (buf, sizeof (buf), "%6.1fdB", coefficient_to_dB (route_get_effective_gain (0)));
print (0, 9, buf);
last_track_gain = g;
}
} else {
print (0, 9, " ");
}
}
void
TranzportControlProtocol::normal_update ()
{
show_current_track ();
show_transport_time ();
show_track_gain ();
show_wheel_mode ();
}
void
TranzportControlProtocol::next_display_mode ()
{
switch (display_mode) {
case DisplayNormal:
display_mode = DisplayBigMeter;
break;
case DisplayBigMeter:
display_mode = DisplayNormal;
break;
}
}
void
TranzportControlProtocol::enter_big_meter_mode ()
{
lcd_clear ();
lights_off ();
last_meter_fill = 0;
display_mode = DisplayBigMeter;
}
void
TranzportControlProtocol::enter_normal_display_mode ()
{
last_where += 1; /* force time redisplay */
last_track_gain = FLT_MAX; /* force gain redisplay */
lcd_clear ();
lights_off ();
show_current_track ();
show_wheel_mode ();
show_wheel_mode ();
show_transport_time ();
display_mode = DisplayNormal;
}
float
log_meter (float db)
{
float def = 0.0f; /* Meter deflection %age */
if (db < -70.0f) {
def = 0.0f;
} else if (db < -60.0f) {
def = (db + 70.0f) * 0.25f;
} else if (db < -50.0f) {
def = (db + 60.0f) * 0.5f + 2.5f;
} else if (db < -40.0f) {
def = (db + 50.0f) * 0.75f + 7.5f;
} else if (db < -30.0f) {
def = (db + 40.0f) * 1.5f + 15.0f;
} else if (db < -20.0f) {
def = (db + 30.0f) * 2.0f + 30.0f;
} else if (db < 6.0f) {
def = (db + 20.0f) * 2.5f + 50.0f;
} else {
def = 115.0f;
}
/* 115 is the deflection %age that would be
when db=6.0. this is an arbitrary
endpoint for our scaling.
*/
return def/115.0f;
}
void
TranzportControlProtocol::show_meter ()
{
if (route_table[0] == 0) {
return;
}
float level = route_get_peak_input_power (0, 0);
float fraction = log_meter (level);
/* we draw using a choice of a sort of double colon-like character ("::") or a single, left-aligned ":".
the screen is 20 chars wide, so we can display 40 different levels. compute the level,
then figure out how many "::" to fill. if the answer is odd, make the last one a ":"
*/
uint32_t fill = (uint32_t) floor (fraction * 40);
char buf[21];
uint32_t i;
if (fill == last_meter_fill) {
/* nothing to do */
return;
}
last_meter_fill = fill;
bool add_single_level = (fill % 2 != 0);
fill /= 2;
if (fraction > 0.98) {
light_on (LightAnysolo);
}
/* add all full steps */
for (i = 0; i < fill; ++i) {
buf[i] = 0x07; /* tranzport special code for 4 quadrant LCD block */
}
/* add a possible half-step */
if (i < 20 && add_single_level) {
buf[i] = 0x03; /* tranzport special code for 2 left quadrant LCD block */
++i;
}
/* fill rest with space */
for (; i < 20; ++i) {
buf[i] = ' ';
}
/* print() requires this */
buf[21] = '\0';
print (0, 0, buf);
print (1, 0, buf);
}
void
TranzportControlProtocol::show_transport_time ()
{
jack_nframes_t where = session->transport_frame();
if (where != last_where) {
char buf[5];
SMPTE::Time smpte;
session->smpte_time (where, smpte);
if (smpte.negative) {
sprintf (buf, "-%02" PRIu32 ":", smpte.hours);
} else {
sprintf (buf, " %02" PRIu32 ":", smpte.hours);
}
print (1, 8, buf);
sprintf (buf, "%02" PRIu32 ":", smpte.minutes);
print (1, 12, buf);
sprintf (buf, "%02" PRIu32 ":", smpte.seconds);
print (1, 15, buf);
sprintf (buf, "%02" PRIu32, smpte.frames);
print (1, 18, buf);
last_where = where;
}
}
void*
TranzportControlProtocol::_monitor_work (void* arg)
{
return static_cast<TranzportControlProtocol*>(arg)->monitor_work ();
}
int
TranzportControlProtocol::open ()
{
struct usb_bus *bus;
struct usb_device *dev;
usb_init();
usb_find_busses();
usb_find_devices();
for (bus = usb_busses; bus; bus = bus->next) {
for(dev = bus->devices; dev; dev = dev->next) {
if (dev->descriptor.idVendor != VENDORID)
continue;
if (dev->descriptor.idProduct != PRODUCTID)
continue;
return open_core (dev);
}
}
error << _("Tranzport: no device detected") << endmsg;
return -1;
}
int
TranzportControlProtocol::open_core (struct usb_device* dev)
{
if (!(udev = usb_open (dev))) {
error << _("Tranzport: cannot open USB transport") << endmsg;
return -1;
}
if (usb_claim_interface (udev, 0) < 0) {
error << _("Tranzport: cannot claim USB interface") << endmsg;
usb_close (udev);
udev = 0;
return -1;
}
if (usb_set_configuration (udev, 1) < 0) {
cerr << _("Tranzport: cannot configure USB interface") << endmsg;
}
return 0;
}
int
TranzportControlProtocol::close ()
{
int ret = 0;
if (udev == 0) {
return 0;
}
if (usb_release_interface (udev, 0) < 0) {
error << _("Tranzport: cannot release interface") << endmsg;
ret = -1;
}
if (usb_close (udev)) {
error << _("Tranzport: cannot close device") << endmsg;
udev = 0;
ret = 0;
}
return ret;
}
int
TranzportControlProtocol::write (uint8_t* cmd, uint32_t timeout_override)
{
int val;
val = usb_interrupt_write (udev, WRITE_ENDPOINT, (char*) cmd, 8, timeout_override ? timeout_override : timeout);
if (val < 0)
return val;
if (val != 8)
return -1;
return 0;
}
void
TranzportControlProtocol::lcd_clear ()
{
/* special case this for speed and atomicity */
uint8_t cmd[8];
cmd[0] = 0x00;
cmd[1] = 0x01;
cmd[3] = ' ';
cmd[4] = ' ';
cmd[5] = ' ';
cmd[6] = ' ';
cmd[7] = 0x00;
for (uint8_t i = 0; i < 10; ++i) {
cmd[2] = i;
usb_interrupt_write (udev, WRITE_ENDPOINT, (char*) cmd, 8, 1000);
}
memset (current_screen, ' ', sizeof (current_screen));
memset (pending_screen, ' ', sizeof (pending_screen));
}
void
TranzportControlProtocol::lights_off ()
{
uint8_t cmd[8];
cmd[0] = 0x00;
cmd[1] = 0x00;
cmd[3] = 0x00;
cmd[4] = 0x00;
cmd[5] = 0x00;
cmd[6] = 0x00;
cmd[7] = 0x00;
cmd[2] = LightRecord;
if (write (cmd, 1000) == 0) {
lights[LightRecord] = false;
}
cmd[2] = LightTrackrec;
if (write (cmd, 1000) == 0) {
lights[LightTrackrec] = false;
}
cmd[2] = LightTrackmute;
if (write (cmd, 1000) == 0) {
lights[LightTrackmute] = false;
}
cmd[2] = LightTracksolo;
if (write (cmd, 1000) == 0) {
lights[LightTracksolo] = false;
}
cmd[2] = LightAnysolo;
if (write (cmd, 1000) == 0) {
lights[LightAnysolo] = false;
}
cmd[2] = LightLoop;
if (write (cmd, 1000) == 0) {
lights[LightLoop] = false;
}
cmd[2] = LightPunch;
if (write (cmd, 1000) == 0) {
lights[LightPunch] = false;
}
}
int
TranzportControlProtocol::light_on (LightID light)
{
uint8_t cmd[8];
if (!lights[light]) {
cmd[0] = 0x00;
cmd[1] = 0x00;
cmd[2] = light;
cmd[3] = 0x01;
cmd[4] = 0x00;
cmd[5] = 0x00;
cmd[6] = 0x00;
cmd[7] = 0x00;
if (write (cmd, 1000) == 0) {
lights[light] = true;
return 0;
} else {
return -1;
}
} else {
return 0;
}
}
int
TranzportControlProtocol::light_off (LightID light)
{
uint8_t cmd[8];
if (lights[light]) {
cmd[0] = 0x00;
cmd[1] = 0x00;
cmd[2] = light;
cmd[3] = 0x00;
cmd[4] = 0x00;
cmd[5] = 0x00;
cmd[6] = 0x00;
cmd[7] = 0x00;
if (write (cmd, 1000) == 0) {
lights[light] = false;
return 0;
} else {
return -1;
}
} else {
return 0;
}
}
void*
TranzportControlProtocol::monitor_work ()
{
struct sched_param rtparam;
int err;
uint8_t buf[8];
int val;
bool first_time = true;
PBD::ThreadCreated (pthread_self(), X_("Tranzport"));
memset (&rtparam, 0, sizeof (rtparam));
rtparam.sched_priority = 3; /* XXX should be relative to audio (JACK) thread */
if ((err = pthread_setschedparam (pthread_self(), SCHED_FIFO, &rtparam)) != 0) {
// do we care? not particularly.
PBD::info << string_compose (_("%1: thread not running with realtime scheduling (%2)"), name(), strerror (errno)) << endmsg;
}
pthread_setcancelstate (PTHREAD_CANCEL_ENABLE, 0);
pthread_setcanceltype (PTHREAD_CANCEL_ASYNCHRONOUS, 0);
next_track ();
while (true) {
/* bInterval for this beastie is 10ms */
/* anything to read ? */
if (_device_status == STATUS_OFFLINE) {
light_off (LightRecord);
first_time = true;
}
pthread_testcancel();
val = usb_interrupt_read (udev, READ_ENDPOINT, (char*) buf, 8, 10);
pthread_testcancel();
if (val == 8) {
process (buf);
}
if (_device_status != STATUS_OFFLINE) {
if (first_time) {
lcd_clear ();
lights_off ();
first_time = false;
}
/* update whatever needs updating */
update_state ();
}
}
return (void*) 0;
}
int
TranzportControlProtocol::update_state ()
{
int row;
int col_base;
int col;
int cell;
/* do the text updates */
switch (display_mode) {
case DisplayBigMeter:
show_meter ();
break;
case DisplayNormal:
normal_update ();
break;
}
/* next: flush LCD */
cell = 0;
for (row = 0; row < 2; ++row) {
for (col_base = 0, col = 0; col < 20; ) {
if (pending_screen[row][col] != current_screen[row][col]) {
/* something in this cell is different, so dump the cell
to the device.
*/
uint8_t cmd[8];
cmd[0] = 0x00;
cmd[1] = 0x01;
cmd[2] = cell;
cmd[3] = pending_screen[row][col_base];
cmd[4] = pending_screen[row][col_base+1];
cmd[5] = pending_screen[row][col_base+2];
cmd[6] = pending_screen[row][col_base+3];
cmd[7] = 0x00;
if (usb_interrupt_write (udev, WRITE_ENDPOINT, (char *) cmd, 8, 1000) == 8) {
/* successful write: copy to current */
memcpy (&current_screen[row][col_base], &pending_screen[row][col_base], 4);
}
/* skip the rest of the 4 character cell since we wrote+copied it already */
col_base += 4;
col = col_base;
cell++;
} else {
col++;
if (col && col % 4 == 0) {
cell++;
col_base += 4;
}
}
}
}
/* now update LED's */
/* per track */
if (route_table[0]) {
boost::shared_ptr<AudioTrack> at = boost::dynamic_pointer_cast<AudioTrack> (route_table[0]);
if (at && at->record_enabled()) {
pending_lights[LightTrackrec] = true;
} else {
pending_lights[LightTrackrec] = false;
}
if (route_get_muted (0)) {
pending_lights[LightTrackmute] = true;
} else {
pending_lights[LightTrackmute] = false;
}
if (route_get_soloed (0)) {
pending_lights[LightTracksolo] = true;
} else {
pending_lights[LightTracksolo] = false;
}
} else {
pending_lights[LightTrackrec] = false;
pending_lights[LightTracksolo] = false;
pending_lights[LightTrackmute] = false;
}
/* global */
if (session->get_auto_loop()) {
pending_lights[LightLoop] = true;
} else {
pending_lights[LightLoop] = false;
}
if (session->get_punch_in() || session->get_punch_out()) {
pending_lights[LightPunch] = true;
} else {
pending_lights[LightPunch] = false;
}
if (session->get_record_enabled()) {
pending_lights[LightRecord] = true;
} else {
pending_lights[LightRecord] = false;
}
if (session->soloing ()) {
pending_lights[LightAnysolo] = true;
} else {
pending_lights[LightAnysolo] = false;
}
/* flush changed light change */
if (pending_lights[LightRecord] != lights[LightRecord]) {
if (pending_lights[LightRecord]) {
light_on (LightRecord);
} else {
light_off (LightRecord);
}
}
if (pending_lights[LightTracksolo] != lights[LightTracksolo]) {
if (pending_lights[LightTracksolo]) {
light_on (LightTracksolo);
} else {
light_off (LightTracksolo);
}
}
if (pending_lights[LightTrackmute] != lights[LightTrackmute]) {
if (pending_lights[LightTrackmute]) {
light_on (LightTrackmute);
} else {
light_off (LightTrackmute);
}
}
if (pending_lights[LightTracksolo] != lights[LightTracksolo]) {
if (pending_lights[LightTracksolo]) {
light_on (LightTracksolo);
} else {
light_off (LightTracksolo);
}
}
if (pending_lights[LightAnysolo] != lights[LightAnysolo]) {
if (pending_lights[LightAnysolo]) {
light_on (LightAnysolo);
} else {
light_off (LightAnysolo);
}
}
if (pending_lights[LightLoop] != lights[LightLoop]) {
if (pending_lights[LightLoop]) {
light_on (LightLoop);
} else {
light_off (LightLoop);
}
}
if (pending_lights[LightPunch] != lights[LightPunch]) {
if (pending_lights[LightPunch]) {
light_on (LightPunch);
} else {
light_off (LightPunch);
}
}
return 0;
}
int
TranzportControlProtocol::process (uint8_t* buf)
{
// printf("read: %02x %02x %02x %02x %02x %02x %02x %02x\n", buf[0], buf[1], buf[2], buf[3], buf[4], buf[5], buf[6], buf[7]);
uint32_t this_button_mask;
uint32_t button_changes;
_device_status = buf[1];
this_button_mask = 0;
this_button_mask |= buf[2] << 24;
this_button_mask |= buf[3] << 16;
this_button_mask |= buf[4] << 8;
this_button_mask |= buf[5];
_datawheel = buf[6];
button_changes = (this_button_mask ^ buttonmask);
buttonmask = this_button_mask;
if (_datawheel) {
datawheel ();
}
if (button_changes & ButtonBattery) {
if (buttonmask & ButtonBattery) {
button_event_battery_press (buttonmask&ButtonShift);
} else {
button_event_battery_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonBacklight) {
if (buttonmask & ButtonBacklight) {
button_event_backlight_press (buttonmask&ButtonShift);
} else {
button_event_backlight_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonTrackLeft) {
if (buttonmask & ButtonTrackLeft) {
button_event_trackleft_press (buttonmask&ButtonShift);
} else {
button_event_trackleft_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonTrackRight) {
if (buttonmask & ButtonTrackRight) {
button_event_trackright_press (buttonmask&ButtonShift);
} else {
button_event_trackright_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonTrackRec) {
if (buttonmask & ButtonTrackRec) {
button_event_trackrec_press (buttonmask&ButtonShift);
} else {
button_event_trackrec_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonTrackMute) {
if (buttonmask & ButtonTrackMute) {
button_event_trackmute_press (buttonmask&ButtonShift);
} else {
button_event_trackmute_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonTrackSolo) {
if (buttonmask & ButtonTrackSolo) {
button_event_tracksolo_press (buttonmask&ButtonShift);
} else {
button_event_tracksolo_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonUndo) {
if (buttonmask & ButtonUndo) {
button_event_undo_press (buttonmask&ButtonShift);
} else {
button_event_undo_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonIn) {
if (buttonmask & ButtonIn) {
button_event_in_press (buttonmask&ButtonShift);
} else {
button_event_in_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonOut) {
if (buttonmask & ButtonOut) {
button_event_out_press (buttonmask&ButtonShift);
} else {
button_event_out_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonPunch) {
if (buttonmask & ButtonPunch) {
button_event_punch_press (buttonmask&ButtonShift);
} else {
button_event_punch_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonLoop) {
if (buttonmask & ButtonLoop) {
button_event_loop_press (buttonmask&ButtonShift);
} else {
button_event_loop_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonPrev) {
if (buttonmask & ButtonPrev) {
button_event_prev_press (buttonmask&ButtonShift);
} else {
button_event_prev_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonAdd) {
if (buttonmask & ButtonAdd) {
button_event_add_press (buttonmask&ButtonShift);
} else {
button_event_add_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonNext) {
if (buttonmask & ButtonNext) {
button_event_next_press (buttonmask&ButtonShift);
} else {
button_event_next_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonRewind) {
if (buttonmask & ButtonRewind) {
button_event_rewind_press (buttonmask&ButtonShift);
} else {
button_event_rewind_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonFastForward) {
if (buttonmask & ButtonFastForward) {
button_event_fastforward_press (buttonmask&ButtonShift);
} else {
button_event_fastforward_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonStop) {
if (buttonmask & ButtonStop) {
button_event_stop_press (buttonmask&ButtonShift);
} else {
button_event_stop_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonPlay) {
if (buttonmask & ButtonPlay) {
button_event_play_press (buttonmask&ButtonShift);
} else {
button_event_play_release (buttonmask&ButtonShift);
}
}
if (button_changes & ButtonRecord) {
if (buttonmask & ButtonRecord) {
button_event_record_press (buttonmask&ButtonShift);
} else {
button_event_record_release (buttonmask&ButtonShift);
}
}
return 0;
}
void
TranzportControlProtocol::show_current_track ()
{
if (route_table[0] == 0) {
print (0, 0, "--------");
} else {
print (0, 0, route_get_name (0).substr (0, 8).c_str());
}
}
void
TranzportControlProtocol::button_event_battery_press (bool shifted)
{
}
void
TranzportControlProtocol::button_event_battery_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_backlight_press (bool shifted)
{
}
void
TranzportControlProtocol::button_event_backlight_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_trackleft_press (bool shifted)
{
prev_track ();
}
void
TranzportControlProtocol::button_event_trackleft_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_trackright_press (bool shifted)
{
next_track ();
}
void
TranzportControlProtocol::button_event_trackright_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_trackrec_press (bool shifted)
{
if (shifted) {
toggle_all_rec_enables ();
} else {
route_set_rec_enable (0, !route_get_rec_enable (0));
}
}
void
TranzportControlProtocol::button_event_trackrec_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_trackmute_press (bool shifted)
{
route_set_muted (0, !route_get_muted (0));
}
void
TranzportControlProtocol::button_event_trackmute_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_tracksolo_press (bool shifted)
{
if (display_mode == DisplayBigMeter) {
light_off (LightAnysolo);
return;
}
if (shifted) {
session->set_all_solo (!session->soloing());
} else {
route_set_soloed (0, !route_get_soloed (0));
}
}
void
TranzportControlProtocol::button_event_tracksolo_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_undo_press (bool shifted)
{
if (shifted) {
redo ();
} else {
undo ();
}
}
void
TranzportControlProtocol::button_event_undo_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_in_press (bool shifted)
{
if (shifted) {
toggle_punch_in ();
} else {
ControlProtocol::ZoomIn (); /* EMIT SIGNAL */
}
}
void
TranzportControlProtocol::button_event_in_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_out_press (bool shifted)
{
if (shifted) {
toggle_punch_out ();
} else {
ControlProtocol::ZoomOut (); /* EMIT SIGNAL */
}
}
void
TranzportControlProtocol::button_event_out_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_punch_press (bool shifted)
{
}
void
TranzportControlProtocol::button_event_punch_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_loop_press (bool shifted)
{
if (shifted) {
next_wheel_shift_mode ();
} else {
loop_toggle ();
}
}
void
TranzportControlProtocol::button_event_loop_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_prev_press (bool shifted)
{
if (shifted) {
ControlProtocol::ZoomToSession (); /* EMIT SIGNAL */
} else {
prev_marker ();
}
}
void
TranzportControlProtocol::button_event_prev_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_add_press (bool shifted)
{
add_marker ();
}
void
TranzportControlProtocol::button_event_add_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_next_press (bool shifted)
{
if (shifted) {
next_wheel_mode ();
} else {
next_marker ();
}
}
void
TranzportControlProtocol::button_event_next_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_rewind_press (bool shifted)
{
if (shifted) {
goto_start ();
} else {
rewind ();
}
}
void
TranzportControlProtocol::button_event_rewind_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_fastforward_press (bool shifted)
{
if (shifted) {
goto_end ();
} else {
ffwd ();
}
}
void
TranzportControlProtocol::button_event_fastforward_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_stop_press (bool shifted)
{
if (shifted) {
next_display_mode ();
} else {
transport_stop ();
}
}
void
TranzportControlProtocol::button_event_stop_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_play_press (bool shifted)
{
transport_play ();
}
void
TranzportControlProtocol::button_event_play_release (bool shifted)
{
}
void
TranzportControlProtocol::button_event_record_press (bool shifted)
{
if (shifted) {
save_state ();
} else {
rec_enable_toggle ();
}
}
void
TranzportControlProtocol::button_event_record_release (bool shifted)
{
}
void
TranzportControlProtocol::datawheel ()
{
if ((buttonmask & ButtonTrackRight) || (buttonmask & ButtonTrackLeft)) {
/* track scrolling */
if (_datawheel < WheelDirectionThreshold) {
next_track ();
} else {
prev_track ();
}
timerclear (&last_wheel_motion);
} else if ((buttonmask & ButtonPrev) || (buttonmask & ButtonNext)) {
if (_datawheel < WheelDirectionThreshold) {
next_marker ();
} else {
prev_marker ();
}
timerclear (&last_wheel_motion);
} else if (buttonmask & ButtonShift) {
/* parameter control */
if (route_table[0]) {
switch (wheel_shift_mode) {
case WheelShiftGain:
if (_datawheel < WheelDirectionThreshold) {
step_gain_up ();
} else {
step_gain_down ();
}
break;
case WheelShiftPan:
if (_datawheel < WheelDirectionThreshold) {
step_pan_right ();
} else {
step_pan_left ();
}
break;
case WheelShiftMaster:
break;
}
}
timerclear (&last_wheel_motion);
} else {
switch (wheel_mode) {
case WheelTimeline:
scroll ();
break;
case WheelScrub:
scrub ();
break;
case WheelShuttle:
shuttle ();
break;
}
}
}
void
TranzportControlProtocol::scroll ()
{
if (_datawheel < WheelDirectionThreshold) {
ScrollTimeline (0.2);
} else {
ScrollTimeline (-0.2);
}
}
void
TranzportControlProtocol::scrub ()
{
float speed;
struct timeval now;
struct timeval delta;
int dir;
gettimeofday (&now, 0);
if (_datawheel < WheelDirectionThreshold) {
dir = 1;
} else {
dir = -1;
}
if (dir != last_wheel_dir) {
/* changed direction, start over */
speed = 0.1f;
} else {
if (timerisset (&last_wheel_motion)) {
timersub (&now, &last_wheel_motion, &delta);
/* 10 clicks per second => speed == 1.0 */
speed = 100000.0f / (delta.tv_sec * 1000000 + delta.tv_usec);
} else {
/* start at half-speed and see where we go from there */
speed = 0.5f;
}
}
last_wheel_motion = now;
last_wheel_dir = dir;
set_transport_speed (speed * dir);
}
void
TranzportControlProtocol::shuttle ()
{
if (_datawheel < WheelDirectionThreshold) {
if (session->transport_speed() < 0) {
session->request_transport_speed (1.0);
} else {
session->request_transport_speed (session->transport_speed() + 0.1);
}
} else {
if (session->transport_speed() > 0) {
session->request_transport_speed (-1.0);
} else {
session->request_transport_speed (session->transport_speed() - 0.1);
}
}
}
void
TranzportControlProtocol::step_gain_up ()
{
if (buttonmask & ButtonStop) {
gain_fraction += 0.001;
} else {
gain_fraction += 0.01;
}
if (gain_fraction > 2.0) {
gain_fraction = 2.0;
}
route_set_gain (0, slider_position_to_gain (gain_fraction));
}
void
TranzportControlProtocol::step_gain_down ()
{
if (buttonmask & ButtonStop) {
gain_fraction -= 0.001;
} else {
gain_fraction -= 0.01;
}
if (gain_fraction < 0.0) {
gain_fraction = 0.0;
}
route_set_gain (0, slider_position_to_gain (gain_fraction));
}
void
TranzportControlProtocol::step_pan_right ()
{
}
void
TranzportControlProtocol::step_pan_left ()
{
}
void
TranzportControlProtocol::next_wheel_shift_mode ()
{
switch (wheel_shift_mode) {
case WheelShiftGain:
wheel_shift_mode = WheelShiftPan;
break;
case WheelShiftPan:
wheel_shift_mode = WheelShiftMaster;
break;
case WheelShiftMaster:
wheel_shift_mode = WheelShiftGain;
}
show_wheel_mode ();
}
void
TranzportControlProtocol::next_wheel_mode ()
{
switch (wheel_mode) {
case WheelTimeline:
wheel_mode = WheelScrub;
break;
case WheelScrub:
wheel_mode = WheelShuttle;
break;
case WheelShuttle:
wheel_mode = WheelTimeline;
}
show_wheel_mode ();
}
void
TranzportControlProtocol::next_track ()
{
ControlProtocol::next_track (current_track_id);
gain_fraction = gain_to_slider_position (route_get_effective_gain (0));
}
void
TranzportControlProtocol::prev_track ()
{
ControlProtocol::prev_track (current_track_id);
gain_fraction = gain_to_slider_position (route_get_effective_gain (0));
}
void
TranzportControlProtocol::show_wheel_mode ()
{
string text;
switch (wheel_mode) {
case WheelTimeline:
text = "Time";
break;
case WheelScrub:
text = "Scrb";
break;
case WheelShuttle:
text = "Shtl";
break;
}
switch (wheel_shift_mode) {
case WheelShiftGain:
text += ":Gain";
break;
case WheelShiftPan:
text += ":Pan";
break;
case WheelShiftMaster:
text += ":Mstr";
break;
}
print (1, 0, text.c_str());
}
void
TranzportControlProtocol::print (int row, int col, const char *text)
{
int cell;
uint32_t left = strlen (text);
char tmp[5];
int base_col;
if (row < 0 || row > 1) {
return;
}
if (col < 0 || col > 19) {
return;
}
while (left) {
if (col >= 0 && col < 4) {
cell = 0;
base_col = 0;
} else if (col >= 4 && col < 8) {
cell = 1;
base_col = 4;
} else if (col >= 8 && col < 12) {
cell = 2;
base_col = 8;
} else if (col >= 12 && col < 16) {
cell = 3;
base_col = 12;
} else if (col >= 16 && col < 20) {
cell = 4;
base_col = 16;
} else {
return;
}
int offset = col % 4;
/* copy current cell contents into tmp */
memcpy (tmp, &pending_screen[row][base_col], 4);
/* overwrite with new text */
uint32_t tocopy = min ((4U - offset), left);
memcpy (tmp+offset, text, tocopy);
/* copy it back to pending */
memcpy (&pending_screen[row][base_col], tmp, 4);
text += tocopy;
left -= tocopy;
col += tocopy;
}
}
XMLNode&
TranzportControlProtocol::get_state ()
{
XMLNode* node = new XMLNode (_name); /* node name must match protocol name */
return *node;
}
int
TranzportControlProtocol::set_state (const XMLNode& node)
{
return 0;
}