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livetrax/libs/surfaces/mackie/mackie_midi_builder.cc

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/*
Copyright (C) 2006,2007 John Anderson
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.
*/
#include "mackie_midi_builder.h"
#include <typeinfo>
#include <sstream>
#include <iomanip>
#include <algorithm>
#include "controls.h"
#include "midi_byte_array.h"
#include "mackie_port.h"
using namespace Mackie;
using namespace std;
MIDI::byte MackieMidiBuilder::calculate_pot_value( midi_pot_mode mode, const ControlState & state )
{
// TODO do an exact calc for 0.50? To allow manually re-centering the port.
// center on or off
MIDI::byte retval = ( state.pos > 0.45 && state.pos < 0.55 ? 1 : 0 ) << 6;
// mode
retval |= ( mode << 4 );
// value, but only if off hasn't explicitly been set
if ( state.led_state != off )
retval += ( int(state.pos * 10.0) + 1 ) & 0x0f; // 0b00001111
return retval;
}
MidiByteArray MackieMidiBuilder::build_led_ring( const Pot & pot, const ControlState & state, midi_pot_mode mode )
{
return build_led_ring( pot.led_ring(), state, mode );
}
MidiByteArray MackieMidiBuilder::build_led_ring( const LedRing & led_ring, const ControlState & state, midi_pot_mode mode )
{
// The other way of doing this:
// 0x30 + pot/ring number (0-7)
//, 0x30 + led_ring.ordinal() - 1
return MidiByteArray ( 3
// the control type
, midi_pot_id
// the id
, 0x20 + led_ring.raw_id()
// the value
, calculate_pot_value( mode, state )
);
}
MidiByteArray MackieMidiBuilder::build_led( const Button & button, LedState ls )
{
return build_led( button.led(), ls );
}
MidiByteArray MackieMidiBuilder::build_led( const Led & led, LedState ls )
{
MIDI::byte state = 0;
switch ( ls.state() )
{
case LedState::on: state = 0x7f; break;
case LedState::off: state = 0x00; break;
case LedState::none: state = 0x00; break; // actually, this should never happen.
case LedState::flashing: state = 0x01; break;
}
return MidiByteArray ( 3
, midi_button_id
, led.raw_id()
, state
);
}
MidiByteArray MackieMidiBuilder::build_fader( const Fader & fader, float pos )
{
int posi = int( 0x3fff * pos );
return MidiByteArray ( 3
, midi_fader_id | fader.raw_id()
// lower-order bits
, posi & 0x7f
// higher-order bits
, ( posi >> 7 )
);
}
MidiByteArray MackieMidiBuilder::zero_strip( SurfacePort & port, const Strip & strip )
{
Group::Controls::const_iterator it = strip.controls().begin();
MidiByteArray retval;
for (; it != strip.controls().end(); ++it )
{
Control & control = **it;
if ( control.accepts_feedback() )
retval << zero_control( control );
}
// These must have sysex headers
retval << strip_display_blank( port, strip, 0 );
retval << strip_display_blank( port, strip, 1 );
return retval;
}
MidiByteArray MackieMidiBuilder::zero_control( const Control & control )
{
switch( control.type() )
{
case Control::type_button:
return build_led( (Button&)control, off );
case Control::type_led:
return build_led( (Led&)control, off );
case Control::type_fader:
return build_fader( (Fader&)control, 0.0 );
case Control::type_pot:
return build_led_ring( dynamic_cast<const Pot&>( control ), off );
case Control::type_led_ring:
return build_led_ring( dynamic_cast<const LedRing&>( control ), off );
default:
ostringstream os;
os << "Unknown control type " << control << " in Strip::zero_control";
throw MackieControlException( os.str() );
}
}
char translate_seven_segment( char achar )
{
achar = toupper( achar );
if ( achar >= 0x40 && achar <= 0x60 )
return achar - 0x40;
else if ( achar >= 0x21 && achar <= 0x3f )
return achar;
else
return 0x00;
}
MidiByteArray MackieMidiBuilder::two_char_display( const std::string & msg, const std::string & dots )
{
if ( msg.length() != 2 ) throw MackieControlException( "MackieMidiBuilder::two_char_display: msg must be exactly 2 characters" );
if ( dots.length() != 2 ) throw MackieControlException( "MackieMidiBuilder::two_char_display: dots must be exactly 2 characters" );
MidiByteArray bytes( 5, 0xb0, 0x4a, 0x00, 0x4b, 0x00 );
// chars are understood by the surface in right-to-left order
// could also exchange the 0x4a and 0x4b, above
bytes[4] = translate_seven_segment( msg[0] ) + ( dots[0] == '.' ? 0x40 : 0x00 );
bytes[2] = translate_seven_segment( msg[1] ) + ( dots[1] == '.' ? 0x40 : 0x00 );
return bytes;
}
MidiByteArray MackieMidiBuilder::two_char_display (unsigned int value, const std::string & /*dots*/)
{
ostringstream os;
os << setfill('0') << setw(2) << value % 100;
return two_char_display( os.str() );
}
MidiByteArray MackieMidiBuilder::strip_display_blank( SurfacePort & port, const Strip & strip, unsigned int line_number )
{
// 6 spaces, not 7 because strip_display adds a space where appropriate
return strip_display( port, strip, line_number, " " );
}
MidiByteArray MackieMidiBuilder::strip_display( SurfacePort & port, const Strip & strip, unsigned int line_number, const std::string & line )
{
if ( line_number > 1 )
{
throw runtime_error( "line_number must be 0 or 1" );
}
if ( strip.index() > 7 )
{
throw runtime_error( "strip.index() must be between 0 and 7" );
}
#ifdef DEBUG
cout << "MackieMidiBuilder::strip_display index: " << strip.index() << ", line " << line_number << ": " << line << endl;
#endif
MidiByteArray retval;
// sysex header
retval << port.sysex_hdr();
// code for display
retval << 0x12;
// offset (0 to 0x37 first line, 0x38 to 0x6f for second line )
retval << ( strip.index() * 7 + ( line_number * 0x38 ) );
// ascii data to display
retval << line;
// pad with " " out to 6 chars
for ( int i = line.length(); i < 6; ++i ) retval << ' ';
// column spacer, unless it's the right-hand column
if ( strip.index() < 7 ) retval << ' ';
// sysex trailer
retval << MIDI::eox;
#ifdef DEBUG
cout << "MackieMidiBuilder::strip_display midi: " << retval << endl;
#endif
return retval;
}
MidiByteArray MackieMidiBuilder::all_strips_display (SurfacePort & /*port*/, std::vector<std::string> & /*lines1*/, std::vector<std::string> & /*lines2*/)
{
MidiByteArray retval;
retval << 0x12 << 0;
// NOTE remember max 112 bytes per message, including sysex headers
retval << "Not working yet";
return retval;
}
MidiByteArray MackieMidiBuilder::timecode_display( SurfacePort & port, const std::string & timecode, const std::string & last_timecode )
{
// if there's no change, send nothing, not even sysex header
if ( timecode == last_timecode ) return MidiByteArray();
// length sanity checking
string local_timecode = timecode;
// truncate to 10 characters
if ( local_timecode.length() > 10 ) local_timecode = local_timecode.substr( 0, 10 );
// pad to 10 characters
while ( local_timecode.length() < 10 ) local_timecode += " ";
// find the suffix of local_timecode that differs from last_timecode
std::pair<string::const_iterator,string::iterator> pp = mismatch( last_timecode.begin(), last_timecode.end(), local_timecode.begin() );
MidiByteArray retval;
// sysex header
retval << port.sysex_hdr();
// code for timecode display
retval << 0x10;
// translate characters. These are sent in reverse order of display
// hence the reverse iterators
string::reverse_iterator rend = reverse_iterator<string::iterator>( pp.second );
for ( string::reverse_iterator it = local_timecode.rbegin(); it != rend; ++it )
{
retval << translate_seven_segment( *it );
}
// sysex trailer
retval << MIDI::eox;
return retval;
}