agg/examples/alpha_mask2.cpp

420 lines
12 KiB
C++

#include <stdlib.h>
#include <ctype.h>
#include <stdio.h>
#include "agg_basics.h"
#include "agg_rendering_buffer.h"
#include "agg_rasterizer_scanline_aa.h"
#include "agg_scanline_u.h"
#include "agg_scanline_p.h"
#include "agg_color_gray.h"
#include "agg_renderer_mclip.h"
#include "agg_renderer_scanline.h"
#include "agg_path_storage.h"
#include "agg_conv_transform.h"
#include "agg_bounding_rect.h"
#include "agg_renderer_outline_aa.h"
#include "agg_pixfmt_gray.h"
#include "agg_pixfmt_amask_adaptor.h"
#include "agg_renderer_primitives.h"
#include "agg_renderer_markers.h"
#include "agg_span_allocator.h"
#include "agg_span_gradient.h"
#include "agg_span_interpolator_linear.h"
#include "agg_rasterizer_outline_aa.h"
#include "agg_alpha_mask_u8.h"
#include "agg_ellipse.h"
#include "ctrl/agg_slider_ctrl.h"
#include "platform/agg_platform_support.h"
//#define AGG_GRAY8
#define AGG_BGR24
//#define AGG_RGB24
//#define AGG_BGR48
//#define AGG_BGR96
//#define AGG_BGRA32
//#define AGG_RGBA32
//#define AGG_ARGB32
//#define AGG_ABGR32
//#define AGG_BGRA128
//#define AGG_RGB565
//#define AGG_RGB555
#include "pixel_formats.h"
enum flip_y_e { flip_y = true };
agg::rasterizer_scanline_aa<> g_rasterizer;
agg::scanline_u8 g_scanline;
agg::path_storage g_path;
agg::srgba8 g_colors[100];
unsigned g_path_idx[100];
unsigned g_npaths = 0;
double g_x1 = 0;
double g_y1 = 0;
double g_x2 = 0;
double g_y2 = 0;
double g_base_dx = 0;
double g_base_dy = 0;
double g_angle = 0;
double g_scale = 1.0;
double g_skew_x = 0;
double g_skew_y = 0;
int g_nclick = 0;
unsigned parse_lion(agg::path_storage& ps, agg::srgba8* colors, unsigned* path_idx);
void parse_lion()
{
g_npaths = parse_lion(g_path, g_colors, g_path_idx);
agg::pod_array_adaptor<unsigned> path_idx(g_path_idx, 100);
agg::bounding_rect(g_path, path_idx, 0, g_npaths, &g_x1, &g_y1, &g_x2, &g_y2);
g_base_dx = (g_x2 - g_x1) / 2.0;
g_base_dy = (g_y2 - g_y1) / 2.0;
}
namespace agg
{
// Specializations of the gradient_linear_color for srgba8 and sgray8
// color types. Only for the sake of performance.
//========================================================================
template<> struct gradient_linear_color<srgba8>
{
typedef srgba8 color_type;
gradient_linear_color() {}
gradient_linear_color(const color_type& c1, const color_type& c2) :
m_c1(c1), m_c2(c2) {}
static unsigned size() { return 256; }
color_type operator [] (unsigned v) const
{
color_type c;
c.r = (int8u)((((m_c2.r - m_c1.r) * int(v)) + (m_c1.r << 8)) >> 8);
c.g = (int8u)((((m_c2.g - m_c1.g) * int(v)) + (m_c1.g << 8)) >> 8);
c.b = (int8u)((((m_c2.b - m_c1.b) * int(v)) + (m_c1.b << 8)) >> 8);
c.a = (int8u)((((m_c2.a - m_c1.a) * int(v)) + (m_c1.a << 8)) >> 8);
return c;
}
void colors(const color_type& c1, const color_type& c2)
{
m_c1 = c1;
m_c2 = c2;
}
color_type m_c1;
color_type m_c2;
};
//========================================================================
template<> struct gradient_linear_color<sgray8>
{
typedef sgray8 color_type;
gradient_linear_color() {}
gradient_linear_color(const color_type& c1, const color_type& c2) :
m_c1(c1), m_c2(c2) {}
static unsigned size() { return 256; }
color_type operator [] (unsigned v) const
{
color_type c;
c.v = (int8u)((((m_c2.v - m_c1.v) * int(v)) + (m_c1.v << 8)) >> 8);
c.a = (int8u)((((m_c2.a - m_c1.a) * int(v)) + (m_c1.a << 8)) >> 8);
return c;
}
void colors(const color_type& c1, const color_type& c2)
{
m_c1 = c1;
m_c2 = c2;
}
color_type m_c1;
color_type m_c2;
};
}
class the_application : public agg::platform_support
{
agg::slider_ctrl<agg::rgba> m_num_cb;
typedef agg::amask_no_clip_gray8 alpha_mask_type;
//typedef agg::alpha_mask_gray8 alpha_mask_type;
unsigned char* m_alpha_buf;
agg::rendering_buffer m_alpha_mask_rbuf;
alpha_mask_type m_alpha_mask;
double m_slider_value;
public:
~the_application()
{
delete [] m_alpha_buf;
}
the_application(agg::pix_format_e format, bool flip_y) :
agg::platform_support(format, flip_y),
m_num_cb(5, 5, 150, 12, !flip_y),
m_alpha_buf(0),
m_alpha_mask_rbuf(),
m_alpha_mask(m_alpha_mask_rbuf),
m_slider_value(0.0)
{
parse_lion();
add_ctrl(m_num_cb);
m_num_cb.range(5, 100);
m_num_cb.value(10);
m_num_cb.label("N=%.2f");
m_num_cb.no_transform();
}
void generate_alpha_mask(int cx, int cy)
{
delete [] m_alpha_buf;
m_alpha_buf = new unsigned char[cx * cy];
m_alpha_mask_rbuf.attach(m_alpha_buf, cx, cy, cx);
typedef agg::renderer_base<agg::pixfmt_sgray8> ren_base;
typedef agg::renderer_scanline_aa_solid<ren_base> renderer;
agg::pixfmt_sgray8 pixf(m_alpha_mask_rbuf);
ren_base rb(pixf);
renderer r(rb);
agg::scanline_p8 sl;
rb.clear(agg::sgray8(0));
agg::ellipse ell;
srand(1432);
int i;
for(i = 0; i < (int)m_num_cb.value(); i++)
{
ell.init(rand() % cx,
rand() % cy,
rand() % 100 + 20,
rand() % 100 + 20,
100);
g_rasterizer.add_path(ell);
r.color(agg::sgray8((rand() & 127) + 128, (rand() & 127) + 128));
agg::render_scanlines(g_rasterizer, sl, r);
}
}
virtual void on_resize(int cx, int cy)
{
generate_alpha_mask(cx, cy);
}
virtual void on_draw()
{
unsigned i;
int width = rbuf_window().width();
int height = rbuf_window().height();
if(m_num_cb.value() != m_slider_value)
{
generate_alpha_mask(width, height);
m_slider_value = m_num_cb.value();
}
pixfmt pf(rbuf_window());
typedef agg::pixfmt_amask_adaptor<pixfmt, alpha_mask_type> pixfmt_amask_type;
typedef agg::renderer_base<pixfmt_amask_type> amask_ren_type;
typedef agg::renderer_base<pixfmt> base_ren_type;
pixfmt_amask_type pfa(pf, m_alpha_mask);
amask_ren_type r(pfa);
base_ren_type rbase(pf);
agg::renderer_scanline_aa_solid<amask_ren_type> rs(r);
agg::renderer_scanline_aa_solid<base_ren_type> rb(rbase);
agg::trans_affine 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(width/2, height/2);
rbase.clear(agg::rgba(1, 1, 1));
int x, y;
// Render the lion
agg::conv_transform<agg::path_storage, agg::trans_affine> trans(g_path, mtx);
agg::render_all_paths(g_rasterizer, g_scanline, rs, trans, g_colors, g_path_idx, g_npaths);
// Render random Bresenham lines and markers
agg::renderer_markers<amask_ren_type> m(r);
for(i = 0; i < 50; i++)
{
m.line_color(agg::srgba8(rand() & 0x7F,
rand() & 0x7F,
rand() & 0x7F,
(rand() & 0x7F) + 0x7F));
m.fill_color(agg::srgba8(rand() & 0x7F,
rand() & 0x7F,
rand() & 0x7F,
(rand() & 0x7F) + 0x7F));
m.line(m.coord(rand() % width), m.coord(rand() % height),
m.coord(rand() % width), m.coord(rand() % height));
m.marker(rand() % width, rand() % height, rand() % 10 + 5,
agg::marker_e(rand() % agg::end_of_markers));
}
// Render random anti-aliased lines
double w = 5.0;
agg::line_profile_aa profile;
profile.width(w);
typedef agg::renderer_outline_aa<amask_ren_type> renderer_type;
renderer_type ren(r, profile);
typedef agg::rasterizer_outline_aa<renderer_type> rasterizer_type;
rasterizer_type ras(ren);
ras.round_cap(true);
for(i = 0; i < 50; i++)
{
ren.color(agg::srgba8(rand() & 0x7F,
rand() & 0x7F,
rand() & 0x7F,
//255));
(rand() & 0x7F) + 0x7F));
ras.move_to_d(rand() % width, rand() % height);
ras.line_to_d(rand() % width, rand() % height);
ras.render(false);
}
// Render random circles with gradient
typedef agg::gradient_linear_color<color_type> grad_color;
typedef agg::gradient_circle grad_func;
typedef agg::span_interpolator_linear<> interpolator_type;
typedef agg::span_gradient<color_type,
interpolator_type,
grad_func,
grad_color> span_grad_type;
agg::trans_affine grm;
grad_func grf;
grad_color grc(agg::srgba8(0,0,0), agg::srgba8(0,0,0));
agg::ellipse ell;
agg::span_allocator<color_type> sa;
interpolator_type inter(grm);
span_grad_type sg(inter, grf, grc, 0, 10);
agg::renderer_scanline_aa<amask_ren_type,
agg::span_allocator<color_type>,
span_grad_type> rg(r, sa, sg);
for(i = 0; i < 50; i++)
{
x = rand() % width;
y = rand() % height;
double r = rand() % 10 + 5;
grm.reset();
grm *= agg::trans_affine_scaling(r / 10.0);
grm *= agg::trans_affine_translation(x, y);
grm.invert();
grc.colors(agg::srgba8(255, 255, 255, 0),
agg::srgba8(rand() & 0x7F,
rand() & 0x7F,
rand() & 0x7F,
255));
sg.color_function(grc);
ell.init(x, y, r, r, 32);
g_rasterizer.add_path(ell);
agg::render_scanlines(g_rasterizer, g_scanline, rg);
}
agg::render_ctrl(g_rasterizer, g_scanline, rbase, m_num_cb);
}
void transform(double width, double height, double x, double y)
{
x -= width / 2;
y -= height / 2;
g_angle = atan2(y, x);
g_scale = sqrt(y * y + x * x) / 100.0;
}
virtual void on_mouse_button_down(int x, int y, unsigned flags)
{
if(flags & agg::mouse_left)
{
int width = rbuf_window().width();
int height = rbuf_window().height();
transform(width, height, x, y);
force_redraw();
}
if(flags & agg::mouse_right)
{
g_skew_x = x;
g_skew_y = y;
force_redraw();
}
}
virtual void on_mouse_move(int x, int y, unsigned flags)
{
on_mouse_button_down(x, y, flags);
}
};
int agg_main(int argc, char* argv[])
{
the_application app(pix_format, flip_y);
app.caption("AGG Example. Clipping to multiple rectangle regions");
if(app.init(512, 400, agg::window_resize))
{
return app.run();
}
return 1;
}