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/*******************************************************************************/
/* Copyright (C) 2007-2008 Jonathan Moore Liles */
/* */
/* 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; see the file COPYING. If not,write to the Free Software */
/* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
/*******************************************************************************/
/* This is a generic double-buffering, optimizing canvas interface to
grids (patterns and phrases). It draws only what is necessary to keep
the display up-to-date. Actual drawing functions are in draw.C */
#include "canvas.H"
#include "pattern.H"
#include "gui/draw.H"
#include "common.h"
#include "non.H"
cell_t **
Canvas::_alloc_array ( void )
{
cell_t **a;
int one = sizeof( typeof( a ) ) * m.vp->w;
int two = sizeof( typeof( a[0] ) ) * (m.vp->h * m.vp->w);
a = (cell_t **) malloc( one + two );
m.size = one + two;
cell_t *c = (cell_t *) (((unsigned char *)a) + one);
for ( uint x = m.vp->w; x-- ; )
{
a[x] = c;
c += m.vp->h;
for ( uint y = m.vp->h; y-- ; )
{
a[ x ][ y ].flags = 0;
a[ x ][ y ].state = -1;
a[ x ][ y ].shape = SQUARE;
a[ x ][ y ].color = 0;
}
}
m.w = m.vp->w;
m.h = m.vp->h;
return a;
}
Canvas::Canvas ( )
{
m.origin_x = m.origin_y = m.height = m.width = m.div_w = m.div_h = m.playhead = m.margin_top = m.margin_left = m.playhead = m.w = m.h = m.p1 = m.p2 = m.p3 = m.p4 = 0;
m.margin_top = ruler_height;
m.draw = false;
m.ruler_drawn = false;
m.mapping_drawn = false;
m.grid_drawn = false;
m.current = m.previous = NULL;
m.row_compact = true;
m.maxh = 128;
m.vp = NULL;
}
void
Canvas::handle_event_change ( void )
{
/* mark the song as dirty and pass the signal on */
song.set_dirty();
signal_draw();
}
/** change grid to /g/, returns TRUE if new grid size differs from old */
void
Canvas::grid ( Grid *g )
{
m.grid = g;
if ( ! g )
return;
m.vp = &g->viewport;
char *s = m.vp->dump();
DMESSAGE( "viewport: %s", s );
free( s );
m.ruler_drawn = false;
resize_grid();
update_mapping();
m.shape = m.grid->draw_shape();
/* connect signals */
/* FIXME: what happens when we do this twice? */
g->signal_events_change.connect( mem_fun( this, &Canvas::handle_event_change ) );
g->signal_settings_change.connect( signal_settings_change.make_slot() );
signal_draw();
signal_settings_change();
}
/** keep row compaction tables up-to-date */
void
Canvas::_update_row_mapping ( void )
{
/* reset */
for ( int i = 128; i-- ; )
m.rtn[i] = m.ntr[i] = -1;
DMESSAGE( "updating row mapping" );
/* rebuild */
int r = 0;
for ( int n = 0; n < 128; ++n )
{
if ( m.grid->row_name( n ) )
{
m.rtn[r] = n;
m.ntr[n] = r;
++r;
}
}
if ( m.row_compact && r )
m.maxh = r;
else
m.maxh = 128;
m.vp->h = min( m.vp->h, m.maxh );
}
/** update everything about mapping, leaving the viewport alone */
void
Canvas::update_mapping ( void )
{
_update_row_mapping();
m.mapping_drawn = false;
resize();
int old_margin = m.margin_left;
m.margin_left = 0;
m.draw = false;
m.grid->draw_row_names( this );
if ( m.margin_left != old_margin )
{
signal_resize();
signal_draw();
}
else
signal_draw();
}
/** change grid mapping */
void
Canvas::changed_mapping ( void )
{
update_mapping();
m.vp->h = min( m.vp->h, m.maxh );
if ( m.vp->y + m.vp->h > m.maxh )
m.vp->y = (m.maxh / 2) - (m.vp->h / 2);
}
Grid *
Canvas::grid ( void )
{
return m.grid;
}
/** recalculate node sizes based on physical dimensions */
void
Canvas::resize ( void )
{
if ( ! m.vp )
return;
m.div_w = (m.width - m.margin_left) / m.vp->w;
m.div_h = (m.height - m.margin_top) / m.vp->h;
m.border_w = min( m.div_w, m.div_h ) / 8;
m.mapping_drawn = m.ruler_drawn = false;
}
/** reallocate buffers to match grid dimensions */
void
Canvas::resize_grid ( void )
{
// _update_row_mapping();
resize();
if ( m.vp )
{
if ( m.vp->w != m.w || m.vp->h != m.h ||
m.div_w != m.old_div_w || m.div_h != m.old_div_h )
{
if ( m.grid_drawn )
signal_resize();
m.old_div_w = m.div_w;
m.old_div_h = m.div_h;
}
else
return;
}
DMESSAGE( "resizing grid %dx%d", m.vp->w, m.vp->h );
if ( m.previous )
{
free( m.previous );
free( m.current );
}
m.current = _alloc_array();
m.previous = _alloc_array();
m.grid_drawn = false;
}
/** inform the canvas with new phsyical dimensions */
void
Canvas::resize ( int x, int y, int w, int h )
{
m.origin_x = x;
m.origin_y = y;
m.width = w;
m.height = h;
resize();
}
/***********/
/* Drawing */
/***********/
/** copy last buffer into current */
void
Canvas::copy ( void )
{
for ( uint y = m.vp->h; y-- ; )
for ( uint x = m.vp->w; x-- ; )
m.current[ x ][ y ] = m.previous[ x ][ y ];
}
/** reset last buffer */
void
Canvas::_reset ( void )
{
cell_t empty = {0,0,0,0};
for ( uint y = m.vp->h; y-- ; )
for ( uint x = m.vp->w; x-- ; )
m.current[ x ][ y ] = empty;
}
/** prepare current buffer for drawing (draw "background") */
void
Canvas::clear ( void )
{
uint rule = m.grid->ppqn();
uint lx = m.grid->ts_to_x( m.grid->length() );
for ( uint y = m.vp->h; y--; )
for ( uint x = m.vp->w; x--; )
{
m.current[ x ][ y ].color = 0;
m.current[ x ][ y ].shape = m.shape;
m.current[ x ][ y ].state = EMPTY;
m.current[ x ][ y ].flags = 0;
}
for ( int x = m.vp->w - rule; x >= 0; x -= rule )
for ( uint y = m.vp->h; y-- ; )
m.current[ x ][ y ].state = LINE;
int sx = (int)(lx - m.vp->x) >= 0 ? lx - m.vp->x : 0;
for ( int x = sx; x < m.vp->w; ++x )
for ( int y = m.vp->h; y-- ; )
m.current[ x ][ y ].state = PARTIAL;
}
/** is /x/ within the viewport? */
bool
Canvas::viewable_x ( int x )
{
return x >= m.vp->x && x < m.vp->x + m.vp->w;
}
/** flush delta of last and current buffers to screen, then flip them */
void
Canvas::flip ( void )
{
/* FIXME: should this not go in clear()? */
if ( m.p1 != m.p2 )
{
if ( viewable_x( m.p1 ) ) draw_line( m.p1 - m.vp->x, F_P1 );
if ( viewable_x( m.p2 ) ) draw_line( m.p2 - m.vp->x, F_P2 );
}
if ( viewable_x( m.playhead ) ) draw_line( m.playhead - m.vp->x, F_PLAYHEAD );
for ( uint y = m.vp->h; y--; )
for ( uint x = m.vp->w; x--; )
{
cell_t *c = &m.current[ x ][ y ];
cell_t *p = &m.previous[ x ][ y ];
/* draw selection rect */
if ( m.p3 != m.p4 )
if ( y + m.vp->y >= m.p3 && x + m.vp->x >= m.p1 &&
y + m.vp->y <= m.p4 && x + m.vp->x < m.p2 )
c->flags |= F_SELECTION;
if ( *c != *p )
gui_draw_shape( m.origin_x + m.margin_left + x * m.div_w, m.origin_y + m.margin_top + y * m.div_h, m.div_w, m.div_h, m.border_w,
c->shape, c->state, c->flags, c->color );
}
cell_t **tmp = m.previous;
m.previous = m.current;
m.current = tmp;
}
/** redraw the ruler at the top of the canvas */
void
Canvas::redraw_ruler ( void )
{
m.margin_top = gui_draw_ruler( m.origin_x + m.margin_left, m.origin_y, m.vp->w, m.div_w, m.grid->division(), m.vp->x,
m.p1 - m.vp->x, m.p2 - m.vp->x );
m.ruler_drawn = true;
}
/** callback called by Grid::draw_row_names() to draw an individual row name */
void
Canvas::draw_row_name ( int y, const char *name, int color )
{
bool draw = m.draw;
bool clear = false;
y = ntr( y );
if ( ! m.row_compact && ! name )
clear = true;
y -= m.vp->y;
int bx = m.origin_x;
int by = m.origin_y + m.margin_top + y * m.div_h;
int bw = min( m.margin_left, m.width / 8 );
int bh = m.div_h;
if ( y < 0 || y >= m.vp->h )
draw = false;
if ( clear && draw )
gui_clear_area( bx, by, bw, bh );
else
m.margin_left = max( m.margin_left, gui_draw_string( bx, by,
bw, bh,
color,
name,
draw ) );
}
/** redraw row names */
void
Canvas::redraw_mapping ( void )
{
m.margin_left = 0;
m.draw = false;
m.grid->draw_row_names( this );
resize();
m.draw = true;
m.grid->draw_row_names( this );
m.mapping_drawn = true;
}
void
Canvas::draw_mapping ( void )
{
if ( ! m.mapping_drawn ) redraw_mapping();
}
void
Canvas::draw_ruler ( void )
{
if ( ! m.ruler_drawn ) redraw_ruler();
}
/** "draw" a shape in the backbuffer */
void
Canvas::draw_shape ( int x, int y, int shape, int state, int color, bool selected )
{
y = ntr( y );
if ( y < 0 )
return;
// adjust for viewport.
x -= m.vp->x;
y -= m.vp->y;
if ( x < 0 || y < 0 || x >= m.vp->w || y >= m.vp->h )
return;
m.current[ x ][ y ].shape = shape;
m.current[ x ][ y ].color = color;
m.current[ x ][ y ].state = (uint)m.vp->x + x > m.grid->ts_to_x( m.grid->length() ) ? PARTIAL : state;
if ( selected )
m.current[ x ][ y ].state = SELECTED;
m.current[ x ][ y ].flags = 0;
}
/** callback used by Grid::draw() */
void
Canvas::draw_dash ( int x, int y, int l, int shape, int color, bool selected )
{
draw_shape( x, y, shape, FULL, color, selected );
for ( int i = x + l - 1; i > x; i-- )
{
draw_shape( i, y, shape, CONTINUED, 0, selected );
}
}
/** draw a vertical line with flags */
void
Canvas::draw_line ( int x, int flags )
{
for ( uint y = m.vp->h; y-- ; )
m.current[ x ][ y ].flags |= flags;
}
/** draw only the playhead--without reexamining the grid */
int
Canvas::draw_playhead ( void )
{
int x = m.grid->ts_to_x( m.grid->index() );
if ( m.playhead == x )
return 0;
m.playhead = x;
if ( m.playhead < m.vp->x || m.playhead >= m.vp->x + m.vp->w )
{
if ( config.follow_playhead )
{
m.vp->x = m.playhead / m.vp->w * m.vp->w;
m.ruler_drawn = false;
signal_draw();
return 0;
}
}
copy();
for ( uint x = m.vp->w; x-- ; )
for ( uint y = m.vp->h; y-- ; )
m.current[ x ][ y ].flags &= ~ (F_PLAYHEAD | F_P1 | F_P2 );
flip();
return 1;
}
/** draw ONLY those nodes necessary to bring the canvas up-to-date with the grid */
void
Canvas::draw ( void )
{
DMESSAGE( "drawing canvas" );
draw_mapping();
draw_ruler();
m.grid_drawn = true;
m.grid->draw( this, m.vp->x, m.vp->y, m.vp->w, m.vp->h );
}
/** redraw every node on the canvas from the buffer (without
* necessarily reexamining the grid) */
void
Canvas::redraw ( void )
{
DMESSAGE( "redrawing canvas" );
if ( ! m.grid_drawn )
draw();
m.ruler_drawn = false;
m.mapping_drawn = false;
draw_mapping();
draw_ruler();
for ( int y = m.vp->h; y--; )
for ( int x = m.vp->w; x--; )
{
cell_t c = m.previous[ x ][ y ];
if ( c.shape > HEXAGON ) return;
if ( m.vp->x + x == m.playhead )
c.flags |= F_PLAYHEAD;
gui_draw_shape( m.origin_x + m.margin_left + x * m.div_w, m.origin_y + m.margin_top + y * m.div_h, m.div_w, m.div_h, m.border_w,
c.shape, c.state, c.flags, c.color );
}
}
/** convert pixel coords into grid coords. returns true if valid */
bool
Canvas::grid_pos ( int *x, int *y ) const
{
*y = (*y - m.margin_top - m.origin_y) / m.div_h;
*x = (*x - m.margin_left - m.origin_x) / m.div_w;
if ( *x < 0 || *y < 0 || *x >= m.vp->w || *y >= m.vp->h )
return false;
/* adjust for viewport */
*x += m.vp->x;
*y += m.vp->y;
/* adjust for row-compaction */
*y = rtn( *y );
return true;
}
/******************/
/* Input handlers */
/******************/
/* These methods translate viewport pixel coords to absolute grid
coords and pass on to the grid. */
/** if coords correspond to a row name entry, return the (absolute) note number, otherwise return -1 */
int
Canvas::is_row_name ( int x, int y )
{
if ( x - m.origin_x >= m.margin_left )
return -1;
x = m.margin_left;
grid_pos( &x, &y );
return m.grid->y_to_note( y );
}
void
Canvas::start_cursor ( int x, int y )
{
if ( ! grid_pos( &x, &y ) )
return;
m.ruler_drawn = false;
m.p1 = x;
m.p3 = ntr( y );
_lr();
signal_draw();
}
void
Canvas::end_cursor ( int x, int y )
{
if ( ! grid_pos( &x, &y ) )
return;
m.ruler_drawn = false;
m.p2 = x;
m.p4 = ntr( y );
_lr();
signal_draw();
}
void
Canvas::set ( int x, int y )
{
if ( y - m.origin_y < m.margin_top )
/* looks like a click on the ruler */
{
if ( x - m.margin_left - m.origin_x >= 0 )
{
m.p1 = m.vp->x + ((x - m.margin_left - m.origin_x) / m.div_w);
m.ruler_drawn = false;
m.p3 = m.p4 = 0;
}
_lr();
signal_draw();
return;
}
if ( ! grid_pos( &x, &y ) )
return;
m.grid->put( x, y, 0 );
}
void
Canvas::unset ( int x, int y )
{
if ( y - m.origin_y < m.margin_top )
/* looks like a click on the ruler */
{
if ( x - m.margin_left - m.origin_x >= 0 )
{
m.p2 = m.vp->x + ((x - m.margin_left - m.origin_x) / m.div_w);
m.ruler_drawn = false;
m.p3 = m.p4 = 0;
}
_lr();
signal_draw();
return;
}
if ( ! grid_pos( &x, &y ) )
return;
m.grid->del( x, y );
}
void
Canvas::adj_color ( int x, int y, int n )
{
if ( ! grid_pos( &x, &y ) )
return;
m.grid->adj_velocity( x, y, n );
}
void
Canvas::adj_length ( int x, int y, int n )
{
if ( ! grid_pos( &x, &y ) )
return;
m.grid->adj_duration( x, y, n );
}
void
Canvas::select ( int x, int y )
{
if ( ! grid_pos( &x, &y ) )
return;
m.grid->toggle_select( x, y );
}
void
Canvas::move_selected ( int dir, int n )
{
switch ( dir )
{
case RIGHT:
m.grid->move_selected( n );
break;
case LEFT:
m.grid->move_selected( 0 - n );
break;
case UP:
case DOWN:
{
/* row-compaction makes this a little complicated */
event_list *el = m.grid->events();
/* FIXME: don't allow movement beyond the edges! */
/* int hi, lo; */
/* m.grid->selected_hi_lo_note( &hi, &lo ); */
/* hi = ntr( hi ) > 0 ? ntr( hi ) : */
/* if ( m.grid->y_to_note( ntr( hi ) ) ) */
if ( dir == UP )
for ( int y = 0; y <= m.maxh; ++y )
el->rewrite_selected( m.grid->y_to_note( rtn( y ) ), m.grid->y_to_note( rtn( y - n ) ) );
else
for ( int y = m.maxh; y >= 0; --y )
el->rewrite_selected( m.grid->y_to_note( rtn( y ) ), m.grid->y_to_note( rtn( y + n ) ) );
m.grid->events( el );
delete el;
break;
}
}
}
void
Canvas::randomize_row ( int y )
{
int x = m.margin_left;
if ( ! grid_pos( &x, &y ) )
return;
((pattern*)m.grid)->randomize_row( y, song.random.feel, song.random.probability );
}
void
Canvas::_lr ( void )
{
int l, r;
if ( m.p2 > m.p1 )
{
l = m.p1;
r = m.p2;
}
else
{
l = m.p2;
r = m.p1;
}
m.p1 = l;
m.p2 = r;
}
void
Canvas::select_range ( void )
{
if ( m.p3 == m.p4 )
m.grid->select( m.p1, m.p2 );
else
m.grid->select( m.p1, m.p2, rtn( m.p3 ), rtn( m.p4 ) );
}
void
Canvas::invert_selection ( void )
{
m.grid->invert_selection();
}
void
Canvas::crop ( void )
{
if ( m.p3 == m.p4 )
m.grid->crop( m.p1, m.p2 );
else
m.grid->crop( m.p1, m.p2, rtn( m.p3 ), rtn( m.p4 ) );
m.vp->x = 0;
m.p2 = m.p2 - m.p1;
m.p1 = 0;
m.ruler_drawn = false;
}
void
Canvas::delete_time ( void )
{
m.grid->delete_time( m.p1, m.p2 );
}
void
Canvas::insert_time ( void )
{
m.grid->insert_time( m.p1, m.p2 );
}
/** paste range as new grid */
void
Canvas::duplicate_range ( void )
{
Grid *g = m.grid->clone();
g->crop( m.p1, m.p2 );
g->viewport.x = 0;
}
void
Canvas::row_compact ( int n )
{
switch ( n )
{
case OFF:
m.row_compact = false;
m.maxh = 128;
break;
case ON:
m.row_compact = true;
m.vp->y = 0;
_update_row_mapping();
break;
case TOGGLE:
row_compact( m.row_compact ? OFF : ON );
break;
}
_reset();
m.mapping_drawn = false;
}
void
Canvas::pan ( int dir, int n )
{
switch ( dir )
{
case LEFT: case RIGHT: case TO_PLAYHEAD: case TO_NEXT_NOTE: case TO_PREV_NOTE:
/* handle horizontal movement specially */
n *= m.grid->division();
m.ruler_drawn = false;
break;
default:
n *= 5;
m.mapping_drawn = false;
break;
}
switch ( dir )
{
case LEFT:
m.vp->x = max( m.vp->x - n, 0 );
break;
case RIGHT:
m.vp->x += n;
break;
case TO_PLAYHEAD:
m.vp->x = m.playhead - (m.playhead % m.grid->division());
break;
case UP:
m.vp->y = max( m.vp->y - n, 0 );
break;
case DOWN:
m.vp->y = min( m.vp->y + n, m.maxh - m.vp->h );
break;
case TO_NEXT_NOTE:
{
int x = m.grid->next_note_x( m.vp->x );
m.vp->x = x - (x % m.grid->division() );
break;
}
case TO_PREV_NOTE:
{
int x = m.grid->prev_note_x( m.vp->x );
m.vp->x = x - (x % m.grid->division() );
break;
}
}
signal_draw();
}
/** adjust horizontal zoom (* n) */
void
Canvas::h_zoom ( float n )
{
m.vp->w = max( 32, min( (int)(m.vp->w * n), 256 ) );
resize_grid();
song.set_dirty();
}
void
Canvas::v_zoom_fit ( void )
{
if ( ! m.grid )
return;
changed_mapping();
m.vp->h = m.maxh;
m.vp->y = 0;
resize_grid();
song.set_dirty();
}
/** adjust vertical zoom (* n) */
void
Canvas::v_zoom ( float n )
{
m.vp->h = max( 1, min( (int)(m.vp->h * n), m.maxh ) );
resize_grid();
song.set_dirty();
}
void
Canvas::notes ( char *s )
{
m.grid->notes( s );
}
char *
Canvas::notes ( void )
{
return m.grid->notes();
}