//------------------------------------------------------------------------
void create_star(agg::path_storage& ps)
{
double r = initial_width();
if(initial_height() < r) r = initial_height();
double r1 = r / 3 - 8.0;
double r2 = r1 / 1.45;
unsigned nr = 14;
unsigned i;
for(i = 0; i < nr; i++)
{
double a = agg::pi * 2.0 * i / nr - agg::pi / 2.0;
double dx = cos(a);
double dy = sin(a);
if(i & 1)
{
ps.line_to(m_polygon_cx + dx * r1, m_polygon_cy + dy * r1);
}
else
{
if(i) ps.line_to(m_polygon_cx + dx * r2, m_polygon_cy + dy * r2);
else ps.move_to(m_polygon_cx + dx * r2, m_polygon_cy + dy * r2);
}
}
}
//------------------------------------------------------------------------
virtual void on_init()
{
m_image_center_x = initial_width() / 2.0;
m_image_center_y = initial_height() / 2.0;
m_polygon_cx = m_image_cx = initial_width() / 2.0;
m_polygon_cy = m_image_cy = initial_height() / 2.0;
}
virtual void on_draw() {
agg::rasterizer_scanline_aa<> pf;
agg::scanline_p8 sl;
typedef agg::renderer_base<pixfmt> renderer_base;
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
rb.clear(agg::rgba(1, 1, 1));
agg::ellipse e1;
agg::conv_transform<agg::ellipse> t1(e1, trans_affine_resizing());
unsigned i;
unsigned n_drawn = 0;
for (i = 0; i < m_num_points; i++) {
double z = m_points[i].z;
double alpha = 1.0;
if (z < m_scale_ctrl_z.value1()) {
alpha = 1.0 - (m_scale_ctrl_z.value1() - z) *
m_slider_ctrl_sel.value() * 100.0;
}
if (z > m_scale_ctrl_z.value2()) {
alpha = 1.0 - (z - m_scale_ctrl_z.value2()) *
m_slider_ctrl_sel.value() * 100.0;
}
if (alpha > 1.0) alpha = 1.0;
if (alpha < 0.0) alpha = 0.0;
if (alpha > 0.0) {
e1.init(m_points[i].x, m_points[i].y, m_slider_ctrl_size.value() * 5.0,
m_slider_ctrl_size.value() * 5.0, 8);
pf.add_path(t1);
agg::render_scanlines_aa_solid(
pf, sl, rb, agg::rgba(m_points[i].color.r, m_points[i].color.g,
m_points[i].color.b, alpha));
n_drawn++;
}
}
agg::render_ctrl(pf, sl, rb, m_scale_ctrl_z);
agg::render_ctrl(pf, sl, rb, m_slider_ctrl_sel);
agg::render_ctrl(pf, sl, rb, m_slider_ctrl_size);
char buf[10];
sprintf(buf, "%08u", n_drawn);
agg::gsv_text txt;
txt.size(15.0);
txt.text(buf);
txt.start_point(10.0, initial_height() - 20.0);
agg::gsv_text_outline<> txt_o(txt, trans_affine_resizing());
pf.add_path(txt_o);
agg::render_scanlines_aa_solid(pf, sl, rb, agg::rgba(0, 0, 0));
}
void generate() {
unsigned i;
double rx = initial_width() / 3.5;
double ry = initial_height() / 3.5;
for (i = 0; i < m_num_points; i++) {
double z = m_points[i].z = random_dbl(0.0, 1.0);
double x = cos(z * 2.0 * agg::pi) * rx;
double y = sin(z * 2.0 * agg::pi) * ry;
double dist = random_dbl(0.0, rx / 2.0);
double angle = random_dbl(0.0, agg::pi * 2.0);
m_points[i].x = initial_width() / 2.0 + x + cos(angle) * dist;
m_points[i].y = initial_height() / 2.0 + y + sin(angle) * dist;
m_points[i].color =
agg::rgba(m_spline_r.get(z) * 0.8, m_spline_g.get(z) * 0.8,
m_spline_b.get(z) * 0.8, 1.0);
}
}
bool MonitorWindow::open_and_resize(Monitor* m) {
_m = m;
pw = 0;
# ifdef QUARTZ_LIB
if (!SpyDisplay[0]) {
pw = (AbstractPlatformWindow*) new QuartzWindow;
}
# endif
# ifdef XLIB
if (!pw) {
pw = (AbstractPlatformWindow*) new XPlatformWindow;
}
# endif
if (!pw) {
warning("no window system for spy");
return false;
}
// open the window, and resize for the spy
// set size hints to don't care cause we will resize window below
if (! pw->open( compute_display_name(),
100, 100, 500, 500,
-1, -1, -1, -1,
compute_window_name(),
"Spy",
SpyFont[0] ? SpyFont : pw->default_fixed_font_name(),
pw->default_fixed_font_size()))
return false;
// Spy uses fixed-width font and sizes window accordingly.
// On some platforms, cannot get font till window is open.
// So, now that window is opened, can ask spy for height, and
// can set window place/size and size limits.
if (!pw->change_extent( initial_left(), initial_top(), initial_width(), initial_height())) { close(); return false; }
if (!pw->change_size_hints( -1, initial_width(), initial_height(), initial_height())) { close(); return false; }
return true;
}
unsigned render_sbool(Rasterizer& ras1, Rasterizer& ras2)
{
pixfmt pf(rbuf_window());
agg::renderer_base<pixfmt> rb(pf);
agg::renderer_scanline_aa_solid<agg::renderer_base<pixfmt> > ren(rb);
agg::scanline_p8 sl;
ras1.filling_rule(m_fill_rule.cur_item() ? agg::fill_non_zero : agg::fill_even_odd);
ras2.filling_rule(m_fill_rule.cur_item() ? agg::fill_non_zero : agg::fill_even_odd);
switch(m_polygons.cur_item())
{
case 0:
{
//------------------------------------
// Two simple paths
//
agg::path_storage ps1;
agg::path_storage ps2;
double x = m_x - initial_width()/2 + 100;
double y = m_y - initial_height()/2 + 100;
ps1.move_to(x+140, y+145);
ps1.line_to(x+225, y+44);
ps1.line_to(x+296, y+219);
ps1.close_polygon();
ps1.line_to(x+226, y+289);
ps1.line_to(x+82, y+292);
ps1.move_to(x+220, y+222);
ps1.line_to(x+363, y+249);
ps1.line_to(x+265, y+331);
ps1.move_to(x+242, y+243);
ps1.line_to(x+325, y+261);
ps1.line_to(x+268, y+309);
ps1.move_to(x+259, y+259);
ps1.line_to(x+273, y+288);
ps1.line_to(x+298, y+266);
ps2.move_to(100+32, 100+77);
ps2.line_to(100+473, 100+263);
ps2.line_to(100+351, 100+290);
ps2.line_to(100+354, 100+374);
ras1.reset();
ras1.add_path(ps1);
ren.color(agg::rgba(0, 0, 0, 0.1));
agg::render_scanlines(ras1, sl, ren);
ras2.reset();
ras2.add_path(ps2);
ren.color(agg::rgba(0, 0.6, 0, 0.1));
agg::render_scanlines(ras2, sl, ren);
render_scanline_boolean(ras1, ras2);
}
break;
case 1:
{
//------------------------------------
// Closed stroke
//
agg::path_storage ps1;
agg::path_storage ps2;
agg::conv_stroke<agg::path_storage> stroke(ps2);
stroke.width(15.0);
double x = m_x - initial_width()/2 + 100;
double y = m_y - initial_height()/2 + 100;
ps1.move_to(x+140, y+145);
ps1.line_to(x+225, y+44);
ps1.line_to(x+296, y+219);
ps1.close_polygon();
ps1.line_to(x+226, y+289);
ps1.line_to(x+82, y+292);
ps1.move_to(x+220-50, y+222);
ps1.line_to(x+363-50, y+249);
ps1.line_to(x+265-50, y+331);
ps1.close_polygon();
ps2.move_to(100+32, 100+77);
ps2.line_to(100+473, 100+263);
ps2.line_to(100+351, 100+290);
ps2.line_to(100+354, 100+374);
ps2.close_polygon();
ras1.reset();
ras1.add_path(ps1);
ren.color(agg::rgba(0, 0, 0, 0.1));
agg::render_scanlines(ras1, sl, ren);
ras2.reset();
ras2.add_path(stroke);
ren.color(agg::rgba(0, 0.6, 0, 0.1));
agg::render_scanlines(ras2, sl, ren);
render_scanline_boolean(ras1, ras2);
}
break;
case 2:
{
//------------------------------------
// Great Britain and Arrows
//
agg::path_storage gb_poly;
agg::path_storage arrows;
make_gb_poly(gb_poly);
make_arrows(arrows);
agg::trans_affine mtx1;
agg::trans_affine mtx2;
mtx1 *= agg::trans_affine_translation(-1150, -1150);
mtx1 *= agg::trans_affine_scaling(2.0);
mtx2 = mtx1;
mtx2 *= agg::trans_affine_translation(m_x - initial_width()/2,
m_y - initial_height()/2);
agg::conv_transform<agg::path_storage> trans_gb_poly(gb_poly, mtx1);
agg::conv_transform<agg::path_storage> trans_arrows(arrows, mtx2);
ras2.add_path(trans_gb_poly);
ren.color(agg::rgba(0.5, 0.5, 0, 0.1));
agg::render_scanlines(ras2, sl, ren);
agg::conv_stroke<agg::conv_transform<agg::path_storage> > stroke_gb_poly(trans_gb_poly);
stroke_gb_poly.width(0.1);
ras1.add_path(stroke_gb_poly);
ren.color(agg::rgba(0, 0, 0));
agg::render_scanlines(ras1, sl, ren);
ras2.add_path(trans_arrows);
ren.color(agg::rgba(0.0, 0.5, 0.5, 0.1));
agg::render_scanlines(ras2, sl, ren);
ras1.reset();
ras1.add_path(trans_gb_poly);
render_scanline_boolean(ras1, ras2);
}
break;
case 3:
{
//------------------------------------
// Great Britain and a Spiral
//
spiral sp(m_x, m_y, 10, 150, 30, 0.0);
agg::conv_stroke<spiral> stroke(sp);
stroke.width(15.0);
agg::path_storage gb_poly;
make_gb_poly(gb_poly);
agg::trans_affine mtx;
mtx *= agg::trans_affine_translation(-1150, -1150);
mtx *= agg::trans_affine_scaling(2.0);
mtx *= trans_affine_resizing();
agg::conv_transform<agg::path_storage> trans_gb_poly(gb_poly, mtx);
ras1.add_path(trans_gb_poly);
ren.color(agg::rgba(0.5, 0.5, 0, 0.1));
agg::render_scanlines(ras1, sl, ren);
agg::conv_stroke<agg::conv_transform<agg::path_storage> > stroke_gb_poly(trans_gb_poly);
stroke_gb_poly.width(0.1);
ras1.reset();
ras1.add_path(stroke_gb_poly);
ren.color(agg::rgba(0, 0, 0));
agg::render_scanlines(ras1, sl, ren);
ras2.reset();
ras2.add_path(stroke);
ren.color(agg::rgba(0.0, 0.5, 0.5, 0.1));
agg::render_scanlines(ras2, sl, ren);
ras1.reset();
ras1.add_path(trans_gb_poly);
render_scanline_boolean(ras1, ras2);
}
break;
case 4:
{
//------------------------------------
// Spiral and glyph
//
spiral sp(m_x, m_y, 10, 150, 30, 0.0);
agg::conv_stroke<spiral> stroke(sp);
stroke.width(15.0);
agg::path_storage glyph;
glyph.move_to(28.47, 6.45);
glyph.curve3(21.58, 1.12, 19.82, 0.29);
glyph.curve3(17.19, -0.93, 14.21, -0.93);
glyph.curve3(9.57, -0.93, 6.57, 2.25);
glyph.curve3(3.56, 5.42, 3.56, 10.60);
glyph.curve3(3.56, 13.87, 5.03, 16.26);
glyph.curve3(7.03, 19.58, 11.99, 22.51);
glyph.curve3(16.94, 25.44, 28.47, 29.64);
glyph.line_to(28.47, 31.40);
glyph.curve3(28.47, 38.09, 26.34, 40.58);
glyph.curve3(24.22, 43.07, 20.17, 43.07);
glyph.curve3(17.09, 43.07, 15.28, 41.41);
glyph.curve3(13.43, 39.75, 13.43, 37.60);
glyph.line_to(13.53, 34.77);
glyph.curve3(13.53, 32.52, 12.38, 31.30);
glyph.curve3(11.23, 30.08, 9.38, 30.08);
glyph.curve3(7.57, 30.08, 6.42, 31.35);
glyph.curve3(5.27, 32.62, 5.27, 34.81);
glyph.curve3(5.27, 39.01, 9.57, 42.53);
glyph.curve3(13.87, 46.04, 21.63, 46.04);
glyph.curve3(27.59, 46.04, 31.40, 44.04);
glyph.curve3(34.28, 42.53, 35.64, 39.31);
glyph.curve3(36.52, 37.21, 36.52, 30.71);
glyph.line_to(36.52, 15.53);
glyph.curve3(36.52, 9.13, 36.77, 7.69);
glyph.curve3(37.01, 6.25, 37.57, 5.76);
glyph.curve3(38.13, 5.27, 38.87, 5.27);
glyph.curve3(39.65, 5.27, 40.23, 5.62);
glyph.curve3(41.26, 6.25, 44.19, 9.18);
glyph.line_to(44.19, 6.45);
glyph.curve3(38.72, -0.88, 33.74, -0.88);
glyph.curve3(31.35, -0.88, 29.93, 0.78);
glyph.curve3(28.52, 2.44, 28.47, 6.45);
glyph.close_polygon();
glyph.move_to(28.47, 9.62);
glyph.line_to(28.47, 26.66);
glyph.curve3(21.09, 23.73, 18.95, 22.51);
glyph.curve3(15.09, 20.36, 13.43, 18.02);
glyph.curve3(11.77, 15.67, 11.77, 12.89);
glyph.curve3(11.77, 9.38, 13.87, 7.06);
glyph.curve3(15.97, 4.74, 18.70, 4.74);
glyph.curve3(22.41, 4.74, 28.47, 9.62);
glyph.close_polygon();
agg::trans_affine mtx;
mtx *= agg::trans_affine_scaling(4.0);
mtx *= agg::trans_affine_translation(220, 200);
agg::conv_transform<agg::path_storage> trans(glyph, mtx);
agg::conv_curve<agg::conv_transform<agg::path_storage> > curve(trans);
ras1.reset();
ras1.add_path(stroke);
ren.color(agg::rgba(0, 0, 0, 0.1));
agg::render_scanlines(ras1, sl, ren);
ras2.reset();
ras2.add_path(curve);
ren.color(agg::rgba(0, 0.6, 0, 0.1));
agg::render_scanlines(ras2, sl, ren);
render_scanline_boolean(ras1, ras2);
}
break;
}
return 0;
}
void
CSS_Viewport::Constrain(const CSS_DeviceProperties& device_props)
{
/* Sanity check for input values. */
OP_ASSERT(device_props.device_width > 0 &&
device_props.device_height > 0 &&
device_props.viewport_width > 0 &&
device_props.viewport_height > 0 &&
device_props.font_size > 0);
m_actual_zoom = m_zoom;
m_actual_min_zoom = m_min_zoom;
m_actual_max_zoom = m_max_zoom;
m_actual_zoomable = m_zoomable;
m_actual_orientation = m_orientation;
/* 1. Resolve relative and absolute lengths, percentages, and keywords ('device-width',
'device-height') to pixel values for the 'min-width', 'max-width',
'min-height' and 'max-height' properties. */
CSS_ViewportLength min_width = m_min_width.ToPixels(device_props, TRUE);
CSS_ViewportLength max_width = m_max_width.ToPixels(device_props, TRUE);
CSS_ViewportLength min_height = m_min_height.ToPixels(device_props, FALSE);
CSS_ViewportLength max_height = m_max_height.ToPixels(device_props, FALSE);
/* 2. If min-width or max-width is not 'auto', set width = MAX(min-width, MIN(max-width, initial-width)) */
CSS_ViewportLength width;
if (!min_width.IsAuto() || !max_width.IsAuto())
{
CSS_ViewportLength initial_width(device_props.viewport_width, CSS_ViewportLength::PX);
width = Max(min_width, Min(max_width, initial_width));
}
/* 3. If min-height or max-height is not 'auto', set height = MAX(min-height, MIN(max-height, initial-height)) */
CSS_ViewportLength height;
if (!min_height.IsAuto() || !max_height.IsAuto())
{
CSS_ViewportLength initial_height(device_props.viewport_height, CSS_ViewportLength::PX);
height = Max(min_height, Min(max_height, initial_height));
}
/* 4. If min-zoom is not 'auto' and max-zoom is not 'auto', set max-zoom = MAX(min-zoom, max-zoom) */
if (m_actual_max_zoom != CSS_VIEWPORT_ZOOM_AUTO &&
m_actual_min_zoom != CSS_VIEWPORT_ZOOM_AUTO &&
m_actual_max_zoom < m_actual_min_zoom)
m_actual_max_zoom = m_actual_min_zoom;
/* 5. If zoom is not 'auto', set zoom = MIN(max-zoom, MAX(min-zoom, zoom)) */
if (m_actual_zoom != CSS_VIEWPORT_ZOOM_AUTO)
{
if (m_actual_min_zoom != CSS_VIEWPORT_ZOOM_AUTO && m_actual_zoom < m_actual_min_zoom)
m_actual_zoom = m_actual_min_zoom;
else if (m_actual_max_zoom != CSS_VIEWPORT_ZOOM_AUTO && m_actual_zoom > m_actual_max_zoom)
m_actual_zoom = m_actual_max_zoom;
}
if (width.IsAuto())
{
if (m_actual_zoom == CSS_VIEWPORT_ZOOM_AUTO)
/* 6. If width and zoom are both 'auto', set width = initial-width */
width = device_props.viewport_width;
else if (height.IsAuto())
/* 7. If width is 'auto', and height is 'auto', set width = (initial-width / zoom) */
width = device_props.viewport_width / m_actual_zoom;
else
/* 8. If width is 'auto', set width = height * (initial-width / initial-height) */
width = double(height) * device_props.viewport_width / double(device_props.viewport_height);
}
/* Check that width has been resolved. */
OP_ASSERT(!width.IsAuto());
/* 9. If height is 'auto', set height = width * (initial-height / initial-width) */
if (height.IsAuto())
height = double(width) * device_props.viewport_height / double(device_props.viewport_width);
/* Check that height has been resolved. */
OP_ASSERT(!height.IsAuto());
if (m_actual_zoom != CSS_VIEWPORT_ZOOM_AUTO || m_actual_max_zoom != CSS_VIEWPORT_ZOOM_AUTO)
{
double max_initial_zoom = m_actual_zoom == CSS_VIEWPORT_ZOOM_AUTO ? m_actual_max_zoom : m_actual_zoom;
/* 10. If zoom or max-zoom is not 'auto', set width = MAX(width, (initial-width / MIN(zoom, max-zoom))) */
double extended_width(device_props.viewport_width / max_initial_zoom);
if (double(width) < extended_width)
width = extended_width;
/* 11. If zoom or max-zoom is not 'auto', set height = MAX(height, (initial-height / MIN(zoom, max-zoom))) */
double extended_height(device_props.viewport_height / max_initial_zoom);
if (double(height) < extended_height)
height = extended_height;
}
m_actual_width = width;
m_actual_height = height;
}
virtual void on_draw()
{
typedef agg::pixfmt_bgr24 pixfmt;
typedef agg::renderer_base<pixfmt> renderer_base;
typedef agg::renderer_scanline_aa_solid<renderer_base> renderer_solid;
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
renderer_solid rs(rb);
rb.clear(agg::rgba(1, 1, 1));
agg::trans_affine mtx;
agg::conv_transform<agg::path_storage, agg::trans_affine> trans(g_path, mtx);
mtx *= agg::trans_affine_translation(-g_base_dx, -g_base_dy);
mtx *= agg::trans_affine_scaling(g_scale, g_scale);
mtx *= agg::trans_affine_rotation(g_angle + agg::pi);
mtx *= agg::trans_affine_skewing(g_skew_x/1000.0, g_skew_y/1000.0);
mtx *= agg::trans_affine_translation(initial_width()/4, initial_height()/2);
mtx *= trans_affine_resizing();
agg::rasterizer_scanline_aa<> ras2;
agg::scanline_p8 sl;
agg::scanline_u8 sl2;
agg::render_all_paths(ras2, sl, rs, trans, g_colors, g_path_idx, g_npaths);
mtx *= ~trans_affine_resizing();
mtx *= agg::trans_affine_translation(initial_width()/2, 0);
mtx *= trans_affine_resizing();
agg::line_profile_aa profile;
profile.width(1.0);
agg::renderer_outline_aa<renderer_base> rp(rb, profile);
agg::rasterizer_outline_aa<agg::renderer_outline_aa<renderer_base> > ras(rp);
ras.round_cap(true);
ras.render_all_paths(trans, g_colors, g_path_idx, g_npaths);
agg::ellipse ell(m_cx, m_cy, 100.0, 100.0, 100);
agg::conv_stroke<agg::ellipse> ell_stroke1(ell);
ell_stroke1.width(6.0);
agg::conv_stroke<agg::conv_stroke<agg::ellipse> > ell_stroke2(ell_stroke1);
ell_stroke2.width(2.0);
rs.color(agg::rgba(0,0.2,0));
ras2.add_path(ell_stroke2);
agg::render_scanlines(ras2, sl, rs);
typedef agg::span_simple_blur_rgb24<agg::order_bgr> span_blur_gen;
typedef agg::span_allocator<span_blur_gen::color_type> span_blur_alloc;
span_blur_alloc sa;
span_blur_gen sg;
sg.source_image(rbuf_img(0));
ras2.add_path(ell);
copy_window_to_img(0);
agg::render_scanlines_aa(ras2, sl2, rb, sa, sg);
// More blur if desired :-)
//copy_window_to_img(0);
//agg::render_scanlines(ras2, sl2, rblur);
//copy_window_to_img(0);
//agg::render_scanlines(ras2, sl2, rblur);
//copy_window_to_img(0);
//agg::render_scanlines(ras2, sl2, rblur);
}
virtual void on_init()
{
m_mouse_y = initial_height() / 2;
m_mouse_x = initial_width() / 2;
}
virtual void on_draw()
{
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
renderer_solid rs(rb);
rb.clear(agg::rgba(1, 1, 1));
// When Gamma changes rebuild the gamma and gradient LUTs
//------------------
if(m_old_gamma != m_gamma.value())
{
m_gamma_lut.gamma(m_gamma.value());
build_gradient_lut();
m_old_gamma = m_gamma.value();
}
// Gradient center. All gradient functions assume the
// center being in the origin (0,0) and you can't
// change it. But you can apply arbitrary transformations
// to the gradient (see below).
//------------------
double cx = initial_width() / 2;
double cy = initial_height() / 2;
double r = 100;
// Focal center. Defined in the gradient coordinates,
// that is, with respect to the origin (0,0)
//------------------
double fx = m_mouse_x - cx;
double fy = m_mouse_y - cy;
gradient_func_type gradient_func(r, fx, fy);
gradient_adaptor_type gradient_adaptor(gradient_func);
agg::trans_affine gradient_mtx;
// Making the affine matrix. Move to (cx,cy),
// apply the resizing transformations and invert
// the matrix. Gradients and images always assume the
// inverse transformations.
//------------------
gradient_mtx.translate(cx, cy);
gradient_mtx *= trans_affine_resizing();
gradient_mtx.invert();
interpolator_type span_interpolator(gradient_mtx);
span_gradient_type span_gradient(span_interpolator,
gradient_adaptor,
m_gradient_lut,
0, r);
// Form the simple rectangle
//------------------
m_rasterizer.reset();
m_rasterizer.move_to_d(0,0);
m_rasterizer.line_to_d(width(), 0);
m_rasterizer.line_to_d(width(), height());
m_rasterizer.line_to_d(0, height());
// Render the gradient to the whole screen and measure the time
//------------------
start_timer();
agg::render_scanlines_aa(m_rasterizer, m_scanline, rb, m_alloc, span_gradient);
double tm = elapsed_time();
// Draw the transformed circle that shows the gradient boundary
//------------------
agg::ellipse e(cx, cy, r, r);
agg::conv_stroke<agg::ellipse> estr(e);
agg::conv_transform<
agg::conv_stroke<
agg::ellipse> > etrans(estr, trans_affine_resizing());
m_rasterizer.add_path(etrans);
agg::render_scanlines_aa_solid(m_rasterizer, m_scanline, rb, agg::rgba(1,1,1));
// Show the gradient time
//------------------
char buf[64];
agg::gsv_text t;
t.size(10.0);
agg::conv_stroke<agg::gsv_text> pt(t);
pt.width(1.5);
sprintf(buf, "%3.2f ms", tm);
t.start_point(10.0, 35.0);
t.text(buf);
m_rasterizer.add_path(pt);
agg::render_scanlines_aa_solid(m_rasterizer, m_scanline, rb, agg::rgba(0,0,0));
#if !LINEAR_RGB
// Show the controls
//------------------
agg::render_ctrl(m_rasterizer, m_scanline, rb, m_gamma);
// Apply the inverse gamma to the whole buffer
// (transform the colors to the perceptually uniform space)
//------------------
pixf.apply_gamma_inv(m_gamma_lut);
#endif
}
virtual void on_draw()
{
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
rb.clear(agg::rgba(1.0, 1.0, 1.0));
rb.copy_from(rbuf_img(0), 0, 110, 35);
agg::rasterizer_scanline_aa<> ras;
agg::scanline_u8 sl;
agg::rendering_buffer img_rbuf(g_image, 4, 4, 4*4);
double para[] = { 200, 40, 200+300, 40, 200+300, 40+300, 200, 40+300 };
agg::trans_affine img_mtx(para, 0,0,4,4);
typedef agg::span_interpolator_linear<> interpolator_type;
interpolator_type interpolator(img_mtx);
agg::span_allocator<agg::rgba8> sa;
pixfmt img_pixf(img_rbuf);
typedef agg::image_accessor_clone<pixfmt> img_source_type;
img_source_type source(img_pixf);
ras.reset();
ras.move_to_d(para[0], para[1]);
ras.line_to_d(para[2], para[3]);
ras.line_to_d(para[4], para[5]);
ras.line_to_d(para[6], para[7]);
switch(m_filters.cur_item())
{
case 0:
{
typedef agg::span_image_filter_rgba_nn<img_source_type,
interpolator_type> span_gen_type;
span_gen_type sg(source, interpolator);
agg::render_scanlines_aa(ras, sl, rb, sa, sg);
}
break;
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
case 10:
case 11:
case 12:
case 13:
case 14:
case 15:
case 16:
{
agg::image_filter_lut filter;
bool norm = m_normalize.status();
switch(m_filters.cur_item())
{
case 1:
filter.calculate(agg::image_filter_bilinear(), norm);
break;
case 2:
filter.calculate(agg::image_filter_bicubic(), norm);
break;
case 3:
filter.calculate(agg::image_filter_spline16(), norm);
break;
case 4:
filter.calculate(agg::image_filter_spline36(), norm);
break;
case 5:
filter.calculate(agg::image_filter_hanning(), norm);
break;
case 6:
filter.calculate(agg::image_filter_hamming(), norm);
break;
case 7:
filter.calculate(agg::image_filter_hermite(), norm);
break;
case 8:
filter.calculate(agg::image_filter_kaiser(), norm);
break;
case 9:
filter.calculate(agg::image_filter_quadric(), norm);
break;
case 10:
filter.calculate(agg::image_filter_catrom(), norm);
break;
case 11:
filter.calculate(agg::image_filter_gaussian(), norm);
break;
case 12:
filter.calculate(agg::image_filter_bessel(), norm);
break;
case 13:
filter.calculate(agg::image_filter_mitchell(), norm);
break;
case 14:
filter.calculate(agg::image_filter_sinc(m_radius.value()), norm);
break;
case 15:
filter.calculate(agg::image_filter_lanczos(m_radius.value()), norm);
break;
case 16:
filter.calculate(agg::image_filter_blackman(m_radius.value()), norm);
break;
}
typedef agg::span_image_filter_rgba<img_source_type,
interpolator_type> span_gen_type;
span_gen_type sg(source, interpolator, filter);
agg::render_scanlines_aa(ras, sl, rb, sa, sg);
agg::gamma_lut<agg::int8u, agg::int8u, 8, 8> gamma(m_gamma.value());
pixf.apply_gamma_inv(gamma);
double x_start = 5.0;
double x_end = 195.0;
double y_start = 235.0;
double y_end = initial_height() - 5.0;
double x_center = (x_start + x_end) / 2;
agg::path_storage p;
agg::conv_stroke<agg::path_storage> stroke(p);
stroke.width(0.8);
unsigned i;
for(i = 0; i <= 16; i++)
{
double x = x_start + (x_end - x_start) * i / 16.0;
p.remove_all();
p.move_to(x+0.5, y_start);
p.line_to(x+0.5, y_end);
ras.add_path(stroke);
agg::render_scanlines_aa_solid(ras, sl, rb,
agg::rgba8(0, 0, 0, i == 8 ? 255 : 100));
}
double ys = y_start + (y_end - y_start) / 6.0;
p.remove_all();
p.move_to(x_start, ys);
p.line_to(x_end, ys);
ras.add_path(stroke);
agg::render_scanlines_aa_solid(ras, sl, rb, agg::rgba8(0, 0, 0));
double radius = filter.radius();
unsigned n = unsigned(radius * 256 * 2);
double dx = (x_end - x_start) * radius / 8.0;
double dy = y_end - ys;
const agg::int16* weights = filter.weight_array();
double xs = (x_end + x_start)/2.0 - (filter.diameter() * (x_end - x_start) / 32.0);
unsigned nn = filter.diameter() * 256;
p.remove_all();
p.move_to(xs+0.5, ys + dy * weights[0] / agg::image_filter_scale);
for(i = 1; i < nn; i++)
{
p.line_to(xs + dx * i / n + 0.5,
ys + dy * weights[i] / agg::image_filter_scale);
}
ras.add_path(stroke);
agg::render_scanlines_aa_solid(ras, sl, rb, agg::rgba8(100, 0, 0));
}
break;
}
agg::render_ctrl(ras, sl, rb, m_gamma);
if(m_filters.cur_item() >= 14)
{
agg::render_ctrl(ras, sl, rb, m_radius);
}
agg::render_ctrl(ras, sl, rb, m_filters);
agg::render_ctrl(ras, sl, rb, m_normalize);
}
virtual void on_draw()
{
typedef agg::renderer_base<pixfmt> renderer_base;
typedef agg::renderer_base<pixfmt_pre> renderer_base_pre;
pixfmt pixf(rbuf_window());
pixfmt_pre pixf_pre(rbuf_window());
renderer_base rb(pixf);
renderer_base_pre rb_pre(pixf_pre);
rb.clear(agg::rgba(1.0, 1.0, 1.0));
agg::trans_affine src_mtx;
src_mtx *= agg::trans_affine_translation(-initial_width()/2 - 10, -initial_height()/2 - 20 - 10);
src_mtx *= agg::trans_affine_rotation(m_angle.value() * agg::pi / 180.0);
src_mtx *= agg::trans_affine_scaling(m_scale.value());
src_mtx *= agg::trans_affine_translation(initial_width()/2, initial_height()/2 + 20);
src_mtx *= trans_affine_resizing();
agg::trans_affine img_mtx;
img_mtx *= agg::trans_affine_translation(-initial_width()/2 + 10, -initial_height()/2 + 20 + 10);
img_mtx *= agg::trans_affine_rotation(m_angle.value() * agg::pi / 180.0);
img_mtx *= agg::trans_affine_scaling(m_scale.value());
img_mtx *= agg::trans_affine_translation(initial_width()/2, initial_height()/2 + 20);
img_mtx *= trans_affine_resizing();
img_mtx.invert();
agg::span_allocator<color_type> sa;
typedef agg::span_interpolator_linear<> interpolator_type;
interpolator_type interpolator(img_mtx);
typedef agg::image_accessor_clip<pixfmt> img_source_type;
pixfmt img_pixf(rbuf_img(0));
img_source_type img_src(img_pixf, agg::rgba_pre(0, 0.4, 0, 0.5));
/*
// Version without filtering (nearest neighbor)
//------------------------------------------
typedef agg::span_image_filter_rgb_nn<img_source_type,
interpolator_type> span_gen_type;
span_gen_type sg(img_src, interpolator);
//------------------------------------------
*/
// Version with "hardcoded" bilinear filter and without
// image_accessor (direct filter, the old variant)
//------------------------------------------
typedef agg::span_image_filter_rgb_bilinear_clip<pixfmt,
interpolator_type> span_gen_type;
span_gen_type sg(img_pixf, agg::rgba_pre(0, 0.4, 0, 0.5), interpolator);
//------------------------------------------
/*
// Version with arbitrary 2x2 filter
//------------------------------------------
typedef agg::span_image_filter_rgb_2x2<img_source_type,
interpolator_type> span_gen_type;
agg::image_filter<agg::image_filter_kaiser> filter;
span_gen_type sg(img_src, interpolator, filter);
//------------------------------------------
*/
/*
// Version with arbitrary filter
//------------------------------------------
typedef agg::span_image_filter_rgb<img_source_type,
interpolator_type> span_gen_type;
agg::image_filter<agg::image_filter_spline36> filter;
span_gen_type sg(img_src, interpolator, filter);
//------------------------------------------
*/
agg::rasterizer_scanline_aa<> ras;
ras.clip_box(0, 0, width(), height());
agg::scanline_u8 sl;
double r = initial_width();
if(initial_height() - 60 < r) r = initial_height() - 60;
agg::ellipse ell(initial_width() / 2.0 + 10,
initial_height() / 2.0 + 20 + 10,
r / 2.0 + 16.0,
r / 2.0 + 16.0, 200);
agg::conv_transform<agg::ellipse> tr(ell, src_mtx);
ras.add_path(tr);
agg::render_scanlines_aa(ras, sl, rb_pre, sa, sg);
agg::render_ctrl(ras, sl, rb, m_angle);
agg::render_ctrl(ras, sl, rb, m_scale);
}
virtual void on_draw()
{
typedef agg::pixfmt_bgr24 pixfmt;
typedef agg::renderer_base<pixfmt> renderer_base;
typedef agg::renderer_scanline_aa_solid<renderer_base> renderer_solid;
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
renderer_solid rs(rb);
rb.clear(agg::rgba(1.0, 1.0, 1.0));
agg::rasterizer_scanline_aa<> ras;
agg::scanline_p8 sl;
double x_start = 125.0;
double x_end = initial_width() - 15.0;
double y_start = 10.0;
double y_end = initial_height() - 10.0;
double x_center = (x_start + x_end) / 2;
unsigned i;
agg::path_storage p;
agg::conv_stroke<agg::path_storage> pl(p);
agg::conv_transform<agg::conv_stroke<agg::path_storage> > tr(pl, trans_affine_resizing());
for(i = 0; i <= 16; i++)
{
double x = x_start + (x_end - x_start) * i / 16.0;
p.remove_all();
p.move_to(x+0.5, y_start);
p.line_to(x+0.5, y_end);
ras.add_path(tr);
rs.color(agg::rgba8(0, 0, 0, i == 8 ? 255 : 100));
agg::render_scanlines(ras, sl, rs);
}
double ys = y_start + (y_end - y_start) / 6.0;
p.remove_all();
p.move_to(x_start, ys);
p.line_to(x_end, ys);
ras.add_path(tr);
rs.color(agg::rgba8(0, 0, 0));
agg::render_scanlines(ras, sl, rs);
pl.width(1.0);
for(i = 0; i < m_num_filters; i++)
{
if(m_filters[i]->status())
{
m_filter_func[i]->set_radius(m_radius.value());
unsigned j;
double radius = m_filter_func[i]->radius();
unsigned n = unsigned(radius * 256 * 2);
double dy = y_end - ys;
double xs = (x_end + x_start)/2.0 - (radius * (x_end - x_start) / 16.0);
double dx = (x_end - x_start) * radius / 8.0;
p.remove_all();
p.move_to(xs+0.5, ys + dy * m_filter_func[i]->calc_weight(-radius));
for(j = 1; j < n; j++)
{
p.line_to(xs + dx * j / n + 0.5,
ys + dy * m_filter_func[i]->calc_weight(j / 256.0 - radius));
}
ras.add_path(tr);
rs.color(agg::rgba8(100, 0, 0));
agg::render_scanlines(ras, sl, rs);
p.remove_all();
unsigned xint;
int ir = int(ceil(radius) + 0.1);
for(xint = 0; xint < 256; xint++)
{
int xfract;
double sum = 0;
for(xfract = -ir; xfract < ir; xfract++)
{
double xf = xint/256.0 + xfract;
if(xf >= -radius || xf <= radius)
{
sum += m_filter_func[i]->calc_weight(xf);
}
}
double x = x_center + ((-128.0 + xint) / 128.0) * radius * (x_end - x_start) / 16.0;
double y = ys + sum * 256 - 256;
if(xint == 0) p.move_to(x, y);
else p.line_to(x, y);
}
ras.add_path(tr);
rs.color(agg::rgba8(0, 100, 0));
agg::render_scanlines(ras, sl, rs);
agg::image_filter_lut normalized(*m_filter_func[i]);
const agg::int16* weights = normalized.weight_array();
xs = (x_end + x_start)/2.0 - (normalized.diameter() * (x_end - x_start) / 32.0);
unsigned nn = normalized.diameter() * 256;
p.remove_all();
p.move_to(xs+0.5, ys + dy * weights[0] / agg::image_filter_scale);
for(j = 1; j < nn; j++)
{
p.line_to(xs + dx * j / n + 0.5,
ys + dy * weights[j] / agg::image_filter_scale);
}
ras.add_path(tr);
rs.color(agg::rgba8(0, 0, 100, 255));
agg::render_scanlines(ras, sl, rs);
}
}
for(i = 0; i < m_num_filters; i++)
{
agg::render_ctrl(ras, sl, rb, *m_filters[i]);
}
if(m_sinc.status() || m_lanczos.status() || m_blackman.status())
{
agg::render_ctrl(ras, sl, rb, m_radius);
}
}
virtual void on_draw()
{
typedef agg::pixfmt_bgr24 pixfmt;
typedef agg::renderer_base<pixfmt> renderer_base;
pixfmt pixf(rbuf_window());
renderer_base rb(pixf);
rb.clear(agg::rgba(1.0, 1.0, 1.0));
agg::trans_affine src_mtx;
src_mtx *= agg::trans_affine_translation(-initial_width()/2, -initial_height()/2);
src_mtx *= agg::trans_affine_rotation(10.0 * agg::pi / 180.0);
src_mtx *= agg::trans_affine_translation(initial_width()/2, initial_height()/2);
src_mtx *= trans_affine_resizing();
agg::trans_affine img_mtx = src_mtx;
img_mtx.invert();
typedef agg::span_allocator<agg::rgba8> span_alloc;
unsigned i;
unsigned char brightness_alpha_array[agg::span_conv_brightness_alpha_rgb8::array_size];
for(i = 0; i < agg::span_conv_brightness_alpha_rgb8::array_size; i++)
{
brightness_alpha_array[i] =
agg::int8u(m_alpha.value(double(i) /
double(agg::span_conv_brightness_alpha_rgb8::array_size)) * 255.0);
}
agg::span_conv_brightness_alpha_rgb8 color_alpha(brightness_alpha_array);
typedef agg::image_accessor_clip<pixfmt> img_source_type;
typedef agg::span_interpolator_linear<> interpolator_type;
typedef agg::span_image_filter_rgb_bilinear<img_source_type,
interpolator_type> span_gen;
typedef agg::span_converter<span_gen,
agg::span_conv_brightness_alpha_rgb8> span_conv;
span_alloc sa;
interpolator_type interpolator(img_mtx);
pixfmt img_pixf(rbuf_img(0));
img_source_type img_src(img_pixf, agg::rgba(0,0,0,0));
span_gen sg(img_src, interpolator);
span_conv sc(sg, color_alpha);
agg::ellipse ell;
agg::rasterizer_scanline_aa<> ras;
agg::scanline_u8 sl;
for(i = 0; i < 50; i++)
{
ell.init(m_x[i], m_y[i], m_rx[i], m_ry[i], 50);
ras.add_path(ell);
agg::render_scanlines_aa_solid(ras, sl, rb, m_colors[i]);
}
ell.init(initial_width() / 2.0,
initial_height() / 2.0,
initial_width() / 1.9,
initial_height() / 1.9, 200);
agg::conv_transform<agg::ellipse> tr(ell, src_mtx);
ras.add_path(tr);
agg::render_scanlines_aa(ras, sl, rb, sa, sc);
agg::render_ctrl(ras, sl, rb, m_alpha);
}
//------------------------------------------------------------------------
virtual void on_init()
{
m_polygon_cx = initial_width() / 2.0;
m_polygon_cy = initial_height() / 2.0;
generate_pattern();
}
int MonitorWindow::initial_top() { return pw->screen_height() - initial_height(); }
