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pygame.mask
- pygame module for image masks.
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Creates a Mask from the given surface
—
Creates a mask by thresholding Surfaces
—
pygame object for representing 2D bitmasks
Useful for fast pixel perfect collision detection. A mask uses 1 bit per-pixel to store which parts collide.
New in pygame 1.8.
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pygame.mask.
from_surface
()¶ - Creates a Mask from the given surfacefrom_surface(Surface) -> Maskfrom_surface(Surface, threshold=127) -> Mask
Creates a
Mask
object from the given surface by setting all the opaque pixels and not setting the transparent pixels.If the surface uses a color-key, then it is used to decide which bits in the resulting mask are set. All the pixels that are not equal to the color-key are set and the pixels equal to the color-key are not set.
If a color-key is not used, then the alpha value of each pixel is used to decide which bits in the resulting mask are set. All the pixels that have an alpha value greater than the
threshold
parameter are set and the pixels with an alpha value less than or equal to thethreshold
are not set.- Parameters
surface (Surface) -- the surface to create the mask from
threshold (int) -- (optional) the alpha threshold (default is 127) to compare with each surface pixel's alpha value, if the
surface
is color-keyed this parameter is ignored
- Returns
a newly created
Mask
object from the given surface- Return type
Note
This function is used to create the masks for
pygame.sprite.collide_mask()
Collision detection between two sprites, using masks..
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pygame.mask.
from_threshold
()¶ - Creates a mask by thresholding Surfacesfrom_threshold(Surface, color) -> Maskfrom_threshold(Surface, color, threshold=(0, 0, 0, 255), othersurface=None, palette_colors=1) -> Mask
This is a more featureful method of getting a
Mask
from a surface.If the optional
othersurface
is not used, all the pixels within thethreshold
of thecolor
parameter are set in the resulting mask.If the optional
othersurface
is used, every pixel in the first surface that is within thethreshold
of the corresponding pixel inothersurface
is set in the resulting mask.- Parameters
surface (Surface) -- the surface to create the mask from
color (Color or int or tuple(int, int, int, [int]) or list[int, int, int, [int]]) -- color used to check if the surface's pixels are within the given
threshold
range, this parameter is ignored if the optionalothersurface
parameter is suppliedthreshold (Color or int or tuple(int, int, int, [int]) or list[int, int, int, [int]]) -- (optional) the threshold range used to check the difference between two colors (default is
(0, 0, 0, 255)
)othersurface (Surface) -- (optional) used to check whether the pixels of the first surface are within the given
threshold
range of the pixels from this surface (default isNone
)palette_colors (int) -- (optional) indicates whether to use the palette colors or not, a nonzero value causes the palette colors to be used and a 0 causes them not to be used (default is 1)
- Returns
a newly created
Mask
object from the given surface- Return type
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pygame.mask.
Mask
¶ - pygame object for representing 2D bitmasksMask(size=(width, height)) -> MaskMask(size=(width, height), fill=False) -> Mask
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Returns a new copy of the mask
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Returns the size of the mask
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Returns a Rect based on the size of the mask
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Gets the bit at the given position
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Sets the bit at the given position
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Returns the point of intersection
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Returns the number of overlapping set bits
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Returns a mask of the overlapping set bits
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Sets all bits to 1
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Sets all bits to 0
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Flips all the bits
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Resizes a mask
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Draws a mask onto another
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Erases a mask from another
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Returns the number of set bits
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Returns the centroid of the set bits
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Returns the orientation of the set bits
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Returns a list of points outlining an object
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Returns the convolution of this mask with another mask
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Returns a mask containing a connected component
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Returns a list of masks of connected components
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Returns a list of bounding rects of connected components
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Returns a surface with the mask drawn on it
A
Mask
object is used to represent a 2D bitmask. Each bit in the mask represents a pixel. 1 is used to indicate a set bit and 0 is used to indicate an unset bit. Set bits in a mask can be used to detect collisions with other masks and their set bits.A filled mask has all of its bits set to 1, conversely an unfilled/cleared/empty mask has all of its bits set to 0. Masks can be created unfilled (default) or filled by using the
fill
parameter. Masks can also be cleared or filled using thepygame.mask.Mask.clear()
Sets all bits to 0 andpygame.mask.Mask.fill()
Sets all bits to 1 methods respectively.A mask's coordinates start in the top left corner at
(0, 0)
just likepygame.Surface
pygame object for representing images. Individual bits can be accessed using thepygame.mask.Mask.get_at()
Gets the bit at the given position andpygame.mask.Mask.set_at()
Sets the bit at the given position methods.The methods
overlap()
,overlap_area()
,overlap_mask()
,draw()
,erase()
, andconvolve()
use an offset parameter to indicate the offset of another mask's top left corner from the calling mask's top left corner. The calling mask's top left corner is considered to be the origin(0, 0)
. Offsets are a tuple or list of 2 integer values(x_offset, y_offset)
. Positive and negative offset values are supported.0 to x (x_offset) : : 0 ..... +----:---------+ to | : | y .......... +-----------+ (y_offset) | | othermask | | +-----------+ | calling_mask | +--------------+
- Parameters
size (tuple(int, int) or list[int, int]) -- the dimensions of the mask (width and height)
fill (bool) -- (optional) create an unfilled mask (default:
False
) or filled mask (True
)
- Returns
a newly created
Mask
object- Return type
Changed in pygame 2.0.0: Shallow copy support added. The
Mask
class supports the special method__copy__()
and shallow copying viacopy.copy(mask)
.Changed in pygame 2.0.0: Subclassing support added. The
Mask
class can be used as a base class.Changed in pygame 1.9.5: Added support for keyword arguments.
Changed in pygame 1.9.5: Added the optional keyword parameter
fill
.Changed in pygame 1.9.5: Added support for masks with a width and/or a height of 0.
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copy
()¶ - Returns a new copy of the maskcopy() -> Mask
- Returns
a new copy of this mask, the new mask will have the same width, height, and set/unset bits as the original
- Return type
Note
If a mask subclass needs to copy any instance specific attributes then it should override the
__copy__()
method. The overridden__copy__()
method needs to callsuper().__copy__()
and then copy the required data as in the following example code.class SubMask(pygame.mask.Mask): def __copy__(self): new_mask = super().__copy__() # Do any SubMask attribute copying here. return new_mask
New in pygame 2.0.0.
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get_size
()¶ - Returns the size of the maskget_size() -> (width, height)
- Returns
the size of the mask, (width, height)
- Return type
tuple(int, int)
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get_rect
()¶ - Returns a Rect based on the size of the maskget_rect(**kwargs) -> Rect
Returns a new
pygame.Rect()
pygame object for storing rectangular coordinates object based on the size of this mask. The rect's default position will be(0, 0)
and its default width and height will be the same as this mask's. The rect's attributes can be altered viapygame.Rect()
pygame object for storing rectangular coordinates attribute keyword arguments/values passed into this method. As an example,a_mask.get_rect(center=(10, 5))
would create apygame.Rect()
pygame object for storing rectangular coordinates based on the mask's size centered at the given position.- Parameters
kwargs (dict) --
pygame.Rect()
pygame object for storing rectangular coordinates attribute keyword arguments/values that will be applied to the rect- Returns
a new
pygame.Rect()
pygame object for storing rectangular coordinates object based on the size of this mask with anypygame.Rect()
pygame object for storing rectangular coordinates attribute keyword arguments/values applied to it- Return type
New in pygame 2.0.0.
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get_at
()¶ - Gets the bit at the given positionget_at((x, y)) -> int
- Parameters
pos (tuple(int, int) or list[int, int]) -- the position of the bit to get
- Returns
1 if the bit is set, 0 if the bit is not set
- Return type
int
- Raises
IndexError -- if the position is outside of the mask's bounds
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set_at
()¶ - Sets the bit at the given positionset_at((x, y)) -> Noneset_at((x, y), value=1) -> None
- Parameters
pos (tuple(int, int) or list[int, int]) -- the position of the bit to set
value (int) -- any nonzero int will set the bit to 1, 0 will set the bit to 0 (default is 1)
- Returns
None
- Return type
NoneType
- Raises
IndexError -- if the position is outside of the mask's bounds
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overlap
()¶ - Returns the point of intersectionoverlap(othermask, offset) -> (x, y)overlap(othermask, offset) -> None
Returns the first point of intersection encountered between this mask and
othermask
. A point of intersection is 2 overlapping set bits.The current algorithm searches the overlapping area in
sizeof(unsigned long int) * CHAR_BIT
bit wide column blocks (the value ofsizeof(unsigned long int) * CHAR_BIT
is platform dependent, for clarity it will be referred to asW
). Starting at the top left corner it checks bits 0 toW - 1
of the first row ((0, 0)
to(W - 1, 0)
) then continues to the next row ((0, 1)
to(W - 1, 1)
). Once this entire column block is checked, it continues to the next one (W
to2 * W - 1
). This is repeated until it finds a point of intersection or the entire overlapping area is checked.- Parameters
othermask (Mask) -- the other mask to overlap with this mask
offset (tuple(int, int) or list[int, int]) -- the offset of
othermask
from this mask, for more details refer to the Mask offset notes
- Returns
point of intersection or
None
if no intersection- Return type
tuple(int, int) or NoneType
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overlap_area
()¶ - Returns the number of overlapping set bitsoverlap_area(othermask, offset) -> numbits
Returns the number of overlapping set bits between between this mask and
othermask
.This can be useful for collision detection. An approximate collision normal can be found by calculating the gradient of the overlapping area through the finite difference.
dx = mask.overlap_area(othermask, (x + 1, y)) - mask.overlap_area(othermask, (x - 1, y)) dy = mask.overlap_area(othermask, (x, y + 1)) - mask.overlap_area(othermask, (x, y - 1))
- Parameters
othermask (Mask) -- the other mask to overlap with this mask
offset (tuple(int, int) or list[int, int]) -- the offset of
othermask
from this mask, for more details refer to the Mask offset notes
- Returns
the number of overlapping set bits
- Return type
int
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overlap_mask
()¶ - Returns a mask of the overlapping set bitsoverlap_mask(othermask, offset) -> Mask
Returns a
Mask
, the same size as this mask, containing the overlapping set bits between this mask andothermask
.- Parameters
othermask (Mask) -- the other mask to overlap with this mask
offset (tuple(int, int) or list[int, int]) -- the offset of
othermask
from this mask, for more details refer to the Mask offset notes
- Returns
a newly created
Mask
with the overlapping bits set- Return type
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fill
()¶ - Sets all bits to 1fill() -> None
Sets all bits in the mask to 1.
- Returns
None
- Return type
NoneType
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clear
()¶ - Sets all bits to 0clear() -> None
Sets all bits in the mask to 0.
- Returns
None
- Return type
NoneType
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invert
()¶ - Flips all the bitsinvert() -> None
Flips all of the bits in the mask. All the set bits are cleared to 0 and all the unset bits are set to 1.
- Returns
None
- Return type
NoneType
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scale
()¶ - Resizes a maskscale((width, height)) -> Mask
Creates a new
Mask
of the requested size with its bits scaled from this mask.
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draw
()¶ - Draws a mask onto anotherdraw(othermask, offset) -> None
Performs a bitwise OR, drawing
othermask
onto this mask.- Parameters
othermask (Mask) -- the mask to draw onto this mask
offset (tuple(int, int) or list[int, int]) -- the offset of
othermask
from this mask, for more details refer to the Mask offset notes
- Returns
None
- Return type
NoneType
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erase
()¶ - Erases a mask from anothererase(othermask, offset) -> None
Erases (clears) all bits set in
othermask
from this mask.- Parameters
othermask (Mask) -- the mask to erase from this mask
offset (tuple(int, int) or list[int, int]) -- the offset of
othermask
from this mask, for more details refer to the Mask offset notes
- Returns
None
- Return type
NoneType
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count
()¶ - Returns the number of set bitscount() -> bits
- Returns
the number of set bits in the mask
- Return type
int
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centroid
()¶ - Returns the centroid of the set bitscentroid() -> (x, y)
Finds the centroid (the center mass of the set bits) for this mask.
- Returns
a coordinate tuple indicating the centroid of the mask, it will return
(0, 0)
if the mask has no bits set- Return type
tuple(int, int)
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angle
()¶ - Returns the orientation of the set bitsangle() -> theta
Finds the approximate orientation (from -90 to 90 degrees) of the set bits in the mask. This works best if performed on a mask with only one connected component.
- Returns
the orientation of the set bits in the mask, it will return
0.0
if the mask has no bits set- Return type
float
Note
See
connected_component()
for details on how a connected component is calculated.
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outline
()¶ - Returns a list of points outlining an objectoutline() -> [(x, y), ...]outline(every=1) -> [(x, y), ...]
Returns a list of points of the outline of the first connected component encountered in the mask. To find a connected component, the mask is searched per row (left to right) starting in the top left corner.
The
every
optional parameter skips set bits in the outline. For example, setting it to 10 would return a list of every 10th set bit in the outline.- Parameters
every (int) -- (optional) indicates the number of bits to skip over in the outline (default is 1)
- Returns
a list of points outlining the first connected component encountered, an empty list is returned if the mask has no bits set
- Return type
list[tuple(int, int)]
Note
See
connected_component()
for details on how a connected component is calculated.
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convolve
()¶ - Returns the convolution of this mask with another maskconvolve(othermask) -> Maskconvolve(othermask, outputmask=None, offset=(0, 0)) -> Mask
Convolve this mask with the given
othermask
.- Parameters
- Returns
a
Mask
with the(i - offset[0], j - offset[1])
bit set, if shiftingothermask
(such that its bottom right corner is at(i, j)
) causes it to overlap with this maskIf an
outputmask
is specified, the output is drawn onto it and it is returned. Otherwise a mask of size(MAX(0, width + othermask's width - 1), MAX(0, height + othermask's height - 1))
is created and returned.- Return type
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connected_component
()¶ - Returns a mask containing a connected componentconnected_component() -> Maskconnected_component((x, y)) -> Mask
A connected component is a group (1 or more) of connected set bits (orthogonally and diagonally). The SAUF algorithm, which checks 8 point connectivity, is used to find a connected component in the mask.
By default this method will return a
Mask
containing the largest connected component in the mask. Optionally, a bit coordinate can be specified and the connected component containing it will be returned. If the bit at the given location is not set, the returnedMask
will be empty (no bits set).- Parameters
pos (tuple(int, int) or list[int, int]) -- (optional) selects the connected component that contains the bit at this position
- Returns
a
Mask
object (same size as this mask) with the largest connected component from this mask, if this mask has no bits set then an empty mask will be returnedIf the
pos
parameter is provided then the mask returned will have the connected component that contains this position. An empty mask will be returned if thepos
parameter selects an unset bit.- Return type
- Raises
IndexError -- if the optional
pos
parameter is outside of the mask's bounds
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connected_components
()¶ - Returns a list of masks of connected componentsconnected_components() -> [Mask, ...]connected_components(min=0) -> [Mask, ...]
Provides a list containing a
Mask
object for each connected component.- Parameters
min (int) -- (optional) indicates the minimum number of bits (to filter out noise) per connected component (default is 0, which equates to no minimum and is equivalent to setting it to 1, as a connected component must have at least 1 bit set)
- Returns
a list containing a
Mask
object for each connected component, an empty list is returned if the mask has no bits set- Return type
list[Mask]
Note
See
connected_component()
for details on how a connected component is calculated.
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get_bounding_rects
()¶ - Returns a list of bounding rects of connected componentsget_bounding_rects() -> [Rect, ...]
Provides a list containing a bounding rect for each connected component.
- Returns
a list containing a bounding rect for each connected component, an empty list is returned if the mask has no bits set
- Return type
list[Rect]
Note
See
connected_component()
for details on how a connected component is calculated.
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to_surface
()¶ - Returns a surface with the mask drawn on itto_surface() -> Surfaceto_surface(surface=None, setsurface=None, unsetsurface=None, setcolor=(255, 255, 255, 255), unsetcolor=(0, 0, 0, 255), dest=(0, 0)) -> Surface
Draws this mask on the given surface. Set bits (bits set to 1) and unset bits (bits set to 0) can be drawn onto a surface.
- Parameters
surface (Surface or None) -- (optional) Surface to draw mask onto, if no surface is provided one will be created (default is
None
, which will cause a surface with the parametersSurface(size=mask.get_size(), flags=SRCALPHA, depth=32)
to be created, drawn on, and returned)setsurface (Surface or None) -- (optional) use this surface's color values to draw set bits (default is
None
), if this surface is smaller than the mask any bits outside its bounds will use thesetcolor
valueunsetsurface (Surface or None) -- (optional) use this surface's color values to draw unset bits (default is
None
), if this surface is smaller than the mask any bits outside its bounds will use theunsetcolor
valuesetcolor (Color or int or tuple(int, int, int, [int]) or list(int, int, int, [int]) or None) -- (optional) color to draw set bits (default is
(255, 255, 255, 255)
, white), useNone
to skip drawing the set bits, thesetsurface
parameter (if set) will takes precedence over this parameterunsetcolor (Color or int or tuple(int, int, int, [int]) or list(int, int, int, [int]) or None) -- (optional) color to draw unset bits (default is
(0, 0, 0, 255)
, black), useNone
to skip drawing the unset bits, theunsetsurface
parameter (if set) will takes precedence over this parameterdest (Rect or tuple(int, int) or list(int, int) or Vector2(int, int)) -- (optional) surface destination of where to position the topleft corner of the mask being drawn (default is
(0, 0)
), if a Rect is used as thedest
parameter, itsx
andy
attributes will be used as the destination, NOTE1: rects with a negative width or height value will not be normalized before using theirx
andy
values, NOTE2: this destination value is only used to position the mask on the surface, it does not offset thesetsurface
andunsetsurface
from the mask, they are always aligned with the mask (i.e. position(0, 0)
on the mask always corresponds to position(0, 0)
on thesetsurface
andunsetsurface
)
- Returns
the
surface
parameter (or a newly created surface if nosurface
parameter was provided) with this mask drawn on it- Return type
- Raises
ValueError -- if the
setsurface
parameter orunsetsurface
parameter does not have the same format (bytesize/bitsize/alpha) as thesurface
parameter
Note
To skip drawing the set bits, both
setsurface
andsetcolor
must beNone
. Thesetsurface
parameter defaults toNone
, butsetcolor
defaults to a color value and therefore must be set toNone
.Note
To skip drawing the unset bits, both
unsetsurface
andunsetcolor
must beNone
. Theunsetsurface
parameter defaults toNone
, butunsetcolor
defaults to a color value and therefore must be set toNone
.New in pygame 2.0.0.
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