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钟尚武
dlib
Commits
333db05c
Commit
333db05c
authored
Dec 09, 2012
by
Davis King
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Added draw_solid_convex_polygon()
parent
49ffb860
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2 changed files
with
253 additions
and
0 deletions
+253
-0
canvas_drawing.h
dlib/gui_widgets/canvas_drawing.h
+228
-0
canvas_drawing_abstract.h
dlib/gui_widgets/canvas_drawing_abstract.h
+25
-0
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dlib/gui_widgets/canvas_drawing.h
View file @
333db05c
...
...
@@ -438,6 +438,234 @@ namespace dlib
double
radius
)
{
draw_solid_circle
(
c
,
center_point
,
radius
,
0
);
}
// ----------------------------------------------------------------------------------------
namespace
impl
{
template
<
typename
alloc
>
void
get_convex_polygon_shape
(
const
std
::
vector
<
point
>&
points
,
const
long
top
,
const
long
bottom
,
std
::
vector
<
double
,
alloc
>&
left_boundary
,
std
::
vector
<
double
,
alloc
>&
right_boundary
)
/*!
requires
- 0 <= top <= bottom
ensures
- interprets points as the coordinates defining a convex polygon. In
particular, we interpret points as a list of the vertices of the polygon
and assume they are ordered in clockwise order.
- #left_boundary.size() == bottom-top+1
- #right_boundary.size() == bottom-top+1
- for all top <= y <= bottom:
- #left_boundary[y-top] == the x coordinate for the left most side of
the polygon at coordinate y.
- #right_boundary[y-top] == the x coordinate for the right most side of
the polygon at coordinate y.
!*/
{
using
std
::
min
;
using
std
::
max
;
left_boundary
.
assign
(
bottom
-
top
+
1
,
std
::
numeric_limits
<
double
>::
infinity
());
right_boundary
.
assign
(
bottom
-
top
+
1
,
-
std
::
numeric_limits
<
double
>::
infinity
());
// trace out the points along the edge of the polynomial and record them
for
(
unsigned
long
i
=
0
;
i
<
points
.
size
();
++
i
)
{
const
point
p1
=
points
[
i
];
const
point
p2
=
points
[(
i
+
1
)
%
points
.
size
()];
if
(
p1
.
y
()
==
p2
.
y
())
{
if
(
top
<=
p1
.
y
()
&&
p1
.
y
()
<=
bottom
)
{
const
long
y
=
p1
.
y
()
-
top
;
const
double
xmin
=
min
(
p1
.
x
(),
p2
.
x
());
const
double
xmax
=
min
(
p1
.
x
(),
p2
.
x
());
left_boundary
[
y
]
=
min
(
left_boundary
[
y
],
xmin
);
right_boundary
[
y
]
=
max
(
right_boundary
[
y
],
xmax
);
}
}
else
{
// Here we trace out the line from p1 to p2 and record where it hits.
// x = m*y + b
const
double
m
=
(
p2
.
x
()
-
p1
.
x
())
/
(
double
)(
p2
.
y
()
-
p1
.
y
());
const
double
b
=
p1
.
x
()
-
m
*
p1
.
y
();
// because: x1 = m*y1 + b
const
long
ymin
=
max
(
top
,
min
(
p1
.
y
(),
p2
.
y
()));
const
long
ymax
=
min
(
bottom
,
max
(
p1
.
y
(),
p2
.
y
()));
for
(
long
y
=
ymin
;
y
<=
ymax
;
++
y
)
{
const
double
x
=
m
*
y
+
b
;
const
unsigned
long
idx
=
y
-
top
;
left_boundary
[
idx
]
=
min
(
left_boundary
[
idx
],
x
);
right_boundary
[
idx
]
=
max
(
right_boundary
[
idx
],
x
);
}
}
}
}
// ------------------------------------------------------------------------------------
}
template
<
typename
pixel_type
>
void
draw_solid_convex_polygon
(
const
canvas
&
c
,
const
std
::
vector
<
point
>&
polygon
,
const
pixel_type
&
pixel
,
const
rectangle
&
area
=
rectangle
(
std
::
numeric_limits
<
long
>::
min
(),
std
::
numeric_limits
<
long
>::
min
(),
std
::
numeric_limits
<
long
>::
max
(),
std
::
numeric_limits
<
long
>::
max
())
)
{
using
std
::
max
;
using
std
::
min
;
const
rectangle
valid_area
(
c
.
intersect
(
area
));
rectangle
bounding_box
;
for
(
unsigned
long
i
=
0
;
i
<
polygon
.
size
();
++
i
)
bounding_box
+=
polygon
[
i
];
// Don't do anything if the polygon is totally outside the area we can draw in
// right now.
if
(
bounding_box
.
intersect
(
valid_area
).
is_empty
())
return
;
rgb_alpha_pixel
alpha_pixel
;
assign_pixel
(
alpha_pixel
,
pixel
);
const
unsigned
char
max_alpha
=
alpha_pixel
.
alpha
;
// we will only want to loop over the part of left_boundary that is part of the
// valid_area.
long
top
=
max
(
valid_area
.
top
(),
bounding_box
.
top
());
long
bottom
=
min
(
valid_area
.
bottom
(),
bounding_box
.
bottom
());
// Since we look at the adjacent rows of boundary information when doing the alpha
// blending, we want to make sure we always have some boundary information unless
// we are at the absolute edge of the polygon.
const
long
top_offset
=
(
top
==
bounding_box
.
top
())
?
0
:
1
;
const
long
bottom_offset
=
(
bottom
==
bounding_box
.
bottom
())
?
0
:
1
;
if
(
top
!=
bounding_box
.
top
())
top
-=
1
;
if
(
bottom
!=
bounding_box
.
bottom
())
bottom
+=
1
;
std
::
vector
<
double
>
left_boundary
;
std
::
vector
<
double
>
right_boundary
;
impl
::
get_convex_polygon_shape
(
polygon
,
top
,
bottom
,
left_boundary
,
right_boundary
);
// draw the polygon row by row
for
(
unsigned
long
i
=
top_offset
;
i
<
left_boundary
.
size
();
++
i
)
{
long
left_x
=
std
::
ceil
(
left_boundary
[
i
]);
long
right_x
=
std
::
floor
(
right_boundary
[
i
]);
left_x
=
max
(
left_x
,
valid_area
.
left
());
right_x
=
min
(
right_x
,
valid_area
.
right
());
if
(
i
<
left_boundary
.
size
()
-
bottom_offset
)
{
// draw the main body of the polygon
for
(
long
x
=
left_x
;
x
<=
right_x
;
++
x
)
{
const
long
y
=
i
+
top
;
assign_pixel
(
c
[
y
-
c
.
top
()][
x
-
c
.
left
()],
pixel
);
}
}
if
(
i
==
0
)
continue
;
// Now alpha blend the edges so they don't look all pixely.
// Alpha blend the edges on the left side.
double
delta
=
left_boundary
[
i
-
1
]
-
left_boundary
[
i
];
if
(
std
::
abs
(
delta
)
<=
1
)
{
if
(
std
::
floor
(
left_boundary
[
i
])
!=
left_x
)
{
const
point
p
(
std
::
floor
(
left_boundary
[
i
]),
i
+
top
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
max_alpha
-
static_cast
<
unsigned
char
>
((
left_boundary
[
i
]
-
p
.
x
())
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
else
if
(
delta
<
0
)
// on the bottom side
{
for
(
long
x
=
std
::
ceil
(
left_boundary
[
i
-
1
]);
x
<
left_x
;
++
x
)
{
const
point
p
(
x
,
i
+
top
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
static_cast
<
unsigned
char
>
((
x
-
left_boundary
[
i
-
1
])
/
std
::
abs
(
delta
)
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
else
// on the top side
{
const
long
old_left_x
=
std
::
ceil
(
left_boundary
[
i
-
1
]);
for
(
long
x
=
left_x
;
x
<
old_left_x
;
++
x
)
{
const
point
p
(
x
,
i
+
top
-
1
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
static_cast
<
unsigned
char
>
((
x
-
left_boundary
[
i
])
/
delta
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
// Alpha blend the edges on the right side
delta
=
right_boundary
[
i
-
1
]
-
right_boundary
[
i
];
if
(
std
::
abs
(
delta
)
<=
1
)
{
if
(
std
::
ceil
(
right_boundary
[
i
])
!=
right_x
)
{
const
point
p
(
std
::
ceil
(
right_boundary
[
i
]),
i
+
top
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
max_alpha
-
static_cast
<
unsigned
char
>
((
p
.
x
()
-
right_boundary
[
i
])
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
else
if
(
delta
<
0
)
// on the top side
{
for
(
long
x
=
std
::
floor
(
right_boundary
[
i
-
1
])
+
1
;
x
<=
right_x
;
++
x
)
{
const
point
p
(
x
,
i
+
top
-
1
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
static_cast
<
unsigned
char
>
((
right_boundary
[
i
]
-
x
)
/
std
::
abs
(
delta
)
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
else
// on the bottom side
{
const
long
old_right_x
=
std
::
floor
(
right_boundary
[
i
-
1
]);
for
(
long
x
=
right_x
+
1
;
x
<=
old_right_x
;
++
x
)
{
const
point
p
(
x
,
i
+
top
);
rgb_alpha_pixel
temp
=
alpha_pixel
;
temp
.
alpha
=
static_cast
<
unsigned
char
>
((
right_boundary
[
i
-
1
]
-
x
)
/
delta
*
max_alpha
);
if
(
valid_area
.
contains
(
p
))
assign_pixel
(
c
[
p
.
y
()
-
c
.
top
()][
p
.
x
()
-
c
.
left
()],
temp
);
}
}
}
}
inline
void
draw_solid_convex_polygon
(
const
canvas
&
c
,
const
std
::
vector
<
point
>&
polygon
)
{
draw_solid_convex_polygon
(
c
,
polygon
,
0
);
}
// ----------------------------------------------------------------------------------------
template
<
...
...
dlib/gui_widgets/canvas_drawing_abstract.h
View file @
333db05c
...
...
@@ -113,6 +113,31 @@ namespace dlib
- Uses the given pixel color.
!*/
// ----------------------------------------------------------------------------------------
template
<
typename
pixel_type
>
void
draw_solid_convex_polygon
(
const
canvas
&
c
,
const
std
::
vector
<
point
>&
polygon
,
const
pixel_type
&
pixel
=
rgb_pixel
(
0
,
0
,
0
),
const
rectangle
&
area
=
rectangle
(
-
infinity
,
-
infinity
,
infinity
,
infinity
)
);
/*!
requires
- pixel_traits<pixel_type> is defined
ensures
- Interprets the given std::vector polygon object as defining a convex polygon
shape. In particular, the polygon is given by taking the points and drawing
lines between them. That is, imagine drawing a line connecting polygon[i]
and polygon[(i+1)%polygon.size()], for all valid i, and then filling in the
interior of the polygon. That is what this function does.
- When drawing the polygon, only the part of the polygon which overlaps both
the given canvas and area rectangle is drawn.
- Uses the given pixel color to draw the polygon.
!*/
// ----------------------------------------------------------------------------------------
void
draw_button_down
(
...
...
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