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from __future__ import annotations from typing import (Any, BinaryIO, ByteString, Callable, Generic, List, Optional, Sequence, Text, Tuple, TypeVar, Union) del annotations HAS_ATSUI_FONT: bool = ... HAS_FT_FONT: bool = ... HAS_GLITZ_SURFACE: bool = ... HAS_IMAGE_SURFACE: bool = ... HAS_MIME_SURFACE: bool = ... """ .. versionadded:: 1.12.0 """ HAS_PDF_SURFACE: bool = ... HAS_PNG_FUNCTIONS: bool = ... HAS_PS_SURFACE: bool = ... HAS_QUARTZ_SURFACE: bool = ... HAS_RECORDING_SURFACE: bool = ... HAS_SCRIPT_SURFACE: bool = ... """ .. versionadded:: 1.12.0 """ HAS_SVG_SURFACE: bool = ... HAS_TEE_SURFACE: bool = ... """ .. versionadded:: 1.15.3 """ HAS_USER_FONT: bool = ... HAS_WIN32_FONT: bool = ... HAS_WIN32_SURFACE: bool = ... HAS_XCB_SURFACE: bool = ... HAS_XLIB_SURFACE: bool = ... HAS_DWRITE_FONT: bool = ... """ .. versionadded:: 1.23.0 """ PDF_OUTLINE_ROOT: int = ... """ The root outline item in :meth:`PDFSurface.add_outline` .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ COLOR_PALETTE_DEFAULT: int = ... """ The default color palette index. See :meth:`FontOptions.set_color_palette` .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ version: str = ... """the pycairo version, as a string""" version_info: Tuple[int, int, int] = ... """the pycairo version, as a tuple""" CAIRO_VERSION: int = ... """ The version of cairo available at compile-time in the same format as returned by :func:`cairo_version` .. versionadded:: 1.18.0 """ CAIRO_VERSION_STRING: str = ... """ A human-readable string literal containing the version of cairo available at compile-time, in the form of "X.Y.Z". .. versionadded:: 1.18.0 """ CAIRO_VERSION_MAJOR: int = ... """ The major component of the version of cairo available at compile-time. .. versionadded:: 1.18.0 """ CAIRO_VERSION_MINOR: int = ... """ The minor component of the version of cairo available at compile-time. .. versionadded:: 1.18.0 """ CAIRO_VERSION_MICRO: int = ... """ The micro component of the version of cairo available at compile-time. .. versionadded:: 1.18.0 """ def cairo_version() -> int: """ :returns: the encoded version Returns the version of the underlying C cairo library, encoded in a single integer. """ def cairo_version_string() -> str: """ :returns: the encoded version Returns the version of the underlying C cairo library as a human-readable string of the form "X.Y.Z". """ class Path: """ *Path* cannot be instantiated directly, it is created by calling :meth:`Context.copy_path` and :meth:`Context.copy_path_flat`. str(path) lists the path elements. See :class:`path attributes <cairo.PathDataType>` Path is an iterator. See examples/warpedtext.py for example usage. """ class Rectangle(Tuple[float, float, float, float]): """ .. versionadded:: 1.15 In prior versions a (float, float, float, float) tuple was used instead of :class:`Rectangle`. A data structure for holding a rectangle. """ x: float = ... y: float = ... width: float = ... height: float = ... def __init__(self, x: float, y: float, width: float, height: float) -> None: """ :param x: X coordinate of the left side of the rectangle :param y: Y coordinate of the the top side of the rectangle :param width: width of the rectangle :param height: height of the rectangle """ class _IntEnum(int): def __init__(self, value: int) -> None: ... class Antialias(_IntEnum): """ Specifies the type of antialiasing to do when rendering text or shapes. .. versionadded:: 1.13 """ BEST: "Antialias" = ... """ Hint that the backend should render at the highest quality, sacrificing speed if necessary. """ DEFAULT: "Antialias" = ... """Use the default antialiasing for the subsystem and target device""" FAST: "Antialias" = ... """ Hint that the backend should perform some antialiasing but prefer speed over quality. """ GOOD: "Antialias" = ... """The backend should balance quality against performance.""" GRAY: "Antialias" = ... """ Perform single-color antialiasing (using shades of gray for black text on a white background, for example). """ NONE: "Antialias" = ... """Use a bilevel alpha mask""" SUBPIXEL: "Antialias" = ... """ Perform antialiasing by taking advantage of the order of subpixel elements on devices such as LCD panels. """ class Content(_IntEnum): """ These constants are used to describe the content that a :class:`Surface` will contain, whether color information, alpha information (translucence vs. opacity), or both. .. versionadded:: 1.13 """ ALPHA: "Content" = ... """The surface will hold alpha content only.""" COLOR: "Content" = ... """The surface will hold color content only.""" COLOR_ALPHA: "Content" = ... """The surface will hold color and alpha content.""" class FillRule(_IntEnum): """ These constants are used to select how paths are filled. For both fill rules, whether or not a point is included in the fill is determined by taking a ray from that point to infinity and looking at intersections with the path. The ray can be in any direction, as long as it doesn't pass through the end point of a segment or have a tricky intersection such as intersecting tangent to the path. (Note that filling is not actually implemented in this way. This is just a description of the rule that is applied.) The default fill rule is :attr:`WINDING`. .. versionadded:: 1.13 """ EVEN_ODD: "FillRule" = ... """ Counts the total number of intersections, without regard to the orientation of the contour. If the total number of intersections is odd, the point will be filled. """ WINDING: "FillRule" = ... """ If the path crosses the ray from left-to-right, counts +1. If the path crosses the ray from right to left, counts -1. (Left and right are determined from the perspective of looking along the ray from the starting point.) If the total count is non-zero, the point will be filled. """ class Format(_IntEnum): """ These constants are used to identify the memory format of :class:`ImageSurface` data. New entries may be added in future versions. .. versionadded:: 1.13 """ def stride_for_width(self, width: int) -> int: """ :param width: the desired width of an :class:`ImageSurface` to be created. :returns: the appropriate stride to use given the desired format and width, or -1 if either the format is invalid or the width too large. This method provides a stride value that will respect all alignment requirements of the accelerated image-rendering code within cairo. Typical usage will be of the form:: format = cairo.Format.RGB24 stride = format.stride_for_width(width) surface = cairo.ImageSurface.create_for_data( data, format, width, height, stride) Also available under :meth:`cairo.ImageSurface.format_stride_for_width`. .. versionadded:: 1.14 """ A1: "Format" = ... """ each pixel is a 1-bit quantity holding an alpha value. Pixels are packed together into 32-bit quantities. The ordering of the bits matches the endianess of the platform. On a big-endian machine, the first pixel is in the uppermost bit, on a little-endian machine the first pixel is in the least-significant bit. """ A8: "Format" = ... """ each pixel is a 8-bit quantity holding an alpha value. """ ARGB32: "Format" = ... """ each pixel is a 32-bit quantity, with alpha in the upper 8 bits, then red, then green, then blue. The 32-bit quantities are stored native-endian. Pre-multiplied alpha is used. (That is, 50% transparent red is 0x80800000, not 0x80ff0000.) """ INVALID: "Format" = ... """no such format exists or is supported.""" RGB16_565: "Format" = ... """ each pixel is a 16-bit quantity with red in the upper 5 bits, then green in the middle 6 bits, and blue in the lower 5 bits. """ RGB24: "Format" = ... """ each pixel is a 32-bit quantity, with the upper 8 bits unused. [#]_ Red, Green, and Blue are stored in the remaining 24 bits in that order. .. [#] Cairo operators (for example CLEAR and SRC) may overwrite unused bytes as an implementation side-effect, their values should be considered undefined. """ RGB30: "Format" = ... """ like :data:`RGB24` but with 10bpc. """ RGB96F: "Format" = ... """ 3 floats, R, G, B. .. versionadded:: 1.23 Only available with cairo 1.17.2+ """ RGBA128F: "Format" = ... """ 4 floats, R, G, B, A. .. versionadded:: 1.23 Only available with cairo 1.17.2+ """ class HintMetrics(_IntEnum): """ These constants specify whether to hint font metrics; hinting font metrics means quantizing them so that they are integer values in device space. Doing this improves the consistency of letter and line spacing, however it also means that text will be laid out differently at different zoom factors. .. versionadded:: 1.13 """ DEFAULT: "HintMetrics" = ... """ Hint metrics in the default manner for the font backend and target device """ OFF: "HintMetrics" = ... """"Do not hint font metrics""" ON: "HintMetrics" = ... """Hint font metrics""" class ColorMode(_IntEnum): """ Specifies if color fonts are to be rendered using the color glyphs or outline glyphs. Glyphs that do not have a color presentation, and non-color fonts are not affected by this font option. .. versionadded:: 1.25 Only available with cairo 1.17.8+ """ DEFAULT: "ColorMode" = ... """ Use the default color mode for font backend and target device. """ NO_COLOR: "ColorMode" = ... """ Disable rendering color glyphs. Glyphs are always rendered as outline glyphs """ COLOR: "ColorMode" = ... """ Enable rendering color glyphs. If the font contains a color presentation for a glyph, and when supported by the font backend, the glyph will be rendered in color. """ class Dither(_IntEnum): """ Dither is an intentionally applied form of noise used to randomize quantization error, preventing large-scale patterns such as color banding in images (e.g. for gradients). Ordered dithering applies a precomputed threshold matrix to spread the errors smoothly. :class:`Dither` is modeled on pixman dithering algorithm choice. As of Pixman 0.40, FAST corresponds to a 8x8 ordered bayer noise and GOOD and BEST use an ordered 64x64 precomputed blue noise. .. versionadded:: 1.25 Only available with cairo 1.18.0+ """ NONE: "Dither" = ... """ No dithering. """ DEFAULT: "Dither" = ... """ Default choice at cairo compile time. Currently NONE. """ FAST: "Dither" = ... """ Fastest dithering algorithm supported by the backend """ GOOD: "Dither" = ... """ An algorithm with smoother dithering than FAST """ BEST: "Dither" = ... """ Best algorithm available in the backend """ class HintStyle(_IntEnum): """ These constants specify the type of hinting to do on font outlines. Hinting is the process of fitting outlines to the pixel grid in order to improve the appearance of the result. Since hinting outlines involves distorting them, it also reduces the faithfulness to the original outline shapes. Not all of the outline hinting styles are supported by all font backends. New entries may be added in future versions. .. versionadded:: 1.13 """ DEFAULT: "HintStyle" = ... """ Use the default hint style for font backend and target device """ FULL: "HintStyle" = ... """ Hint outlines to maximize contrast """ MEDIUM: "HintStyle" = ... """ Hint outlines with medium strength giving a compromise between fidelity to the original shapes and contrast """ NONE: "HintStyle" = ... """Do not hint outlines""" SLIGHT: "HintStyle" = ... """ Hint outlines slightly to improve contrast while retaining good fidelity to the original shapes. """ class SubpixelOrder(_IntEnum): """ The subpixel order specifies the order of color elements within each pixel on the display device when rendering with an antialiasing mode of :attr:`Antialias.SUBPIXEL`. .. versionadded:: 1.13 """ BGR: "SubpixelOrder" = ... """Subpixel elements are arranged horizontally with blue at the left""" DEFAULT: "SubpixelOrder" = ... """Use the default subpixel order for for the target device""" RGB: "SubpixelOrder" = ... """Subpixel elements are arranged horizontally with red at the left""" VBGR: "SubpixelOrder" = ... """Subpixel elements are arranged vertically with blue at the top""" VRGB: "SubpixelOrder" = ... """Subpixel elements are arranged vertically with red at the top""" class LineCap(_IntEnum): """ These constants specify how to render the endpoints of the path when stroking. The default line cap style is :attr:`BUTT` .. versionadded:: 1.13 """ BUTT: "LineCap" = ... """start(stop) the line exactly at the start(end) point""" ROUND: "LineCap" = ... """use a round ending, the center of the circle is the end point""" SQUARE: "LineCap" = ... """use squared ending, the center of the square is the end point""" class LineJoin(_IntEnum): """ These constants specify how to render the junction of two lines when stroking. The default line join style is :attr:`MITER` .. versionadded:: 1.13 """ BEVEL: "LineJoin" = ... """ use a cut-off join, the join is cut off at half the line width from the joint point """ MITER: "LineJoin" = ... """ use a sharp (angled) corner, see :meth:`Context.set_miter_limit` """ ROUND: "LineJoin" = ... """use a rounded join, the center of the circle is the joint point""" class Filter(_IntEnum): """ These constants are used to indicate what filtering should be applied when reading pixel values from patterns. See :meth:`Pattern.set_filter` for indicating the desired filter to be used with a particular pattern. .. versionadded:: 1.13 """ BEST: "Filter" = ... """ The highest-quality available, performance may not be suitable for interactive use. """ BILINEAR: "Filter" = ... """Linear interpolation in two dimensions""" FAST: "Filter" = ... """A high-performance filter, with quality similar *FILTER_NEAREST*""" GAUSSIAN: "Filter" = ... """ This filter value is currently unimplemented, and should not be used in current code. """ GOOD: "Filter" = ... """ A reasonable-performance filter, with quality similar to *FILTER_BILINEAR* """ NEAREST: "Filter" = ... """Nearest-neighbor filtering""" class Operator(_IntEnum): """ These constants are used to set the compositing operator for all cairo drawing operations. The default operator is :attr:`OVER`. The operators marked as *unbounded* modify their destination even outside of the mask layer (that is, their effect is not bound by the mask layer). However, their effect can still be limited by way of clipping. To keep things simple, the operator descriptions here document the behavior for when both source and destination are either fully transparent or fully opaque. The actual implementation works for translucent layers too. For a more detailed explanation of the effects of each operator, including the mathematical definitions, see https://cairographics.org/operators. .. versionadded:: 1.13 """ ADD: "Operator" = ... """source and destination layers are accumulated""" ATOP: "Operator" = ... """draw source on top of destination content and only there""" CLEAR: "Operator" = ... """clear destination layer (bounded)""" COLOR_BURN: "Operator" = ... """darkens the destination color to reflect the source color.""" COLOR_DODGE: "Operator" = ... """brightens the destination color to reflect the source color.""" DARKEN: "Operator" = ... """ replaces the destination with the source if it is darker, otherwise keeps the source. """ DEST: "Operator" = ... """ignore the source""" DEST_ATOP: "Operator" = ... """leave destination on top of source content and only there (unbounded)""" DEST_IN: "Operator" = ... """leave destination only where there was source content (unbounded)""" DEST_OUT: "Operator" = ... """leave destination only where there was no source content""" DEST_OVER: "Operator" = ... """draw destination on top of source""" DIFFERENCE: "Operator" = ... """Takes the difference of the source and destination color.""" EXCLUSION: "Operator" = ... """Produces an effect similar to difference, but with lower contrast.""" HARD_LIGHT: "Operator" = ... """Multiplies or screens, dependent on source color.""" HSL_COLOR: "Operator" = ... """ Creates a color with the hue and saturation of the source and the luminosity of the target. This preserves the gray levels of the target and is useful for coloring monochrome images or tinting color images. """ HSL_HUE: "Operator" = ... """ Creates a color with the hue of the source and the saturation and luminosity of the target. """ HSL_LUMINOSITY: "Operator" = ... """ Creates a color with the luminosity of the source and the hue and saturation of the target. This produces an inverse effect to :attr:`HSL_COLOR` """ HSL_SATURATION: "Operator" = ... """ Creates a color with the saturation of the source and the hue and luminosity of the target. Painting with this mode onto a gray area produces no change. """ IN: "Operator" = ... """draw source where there was destination content (unbounded)""" LIGHTEN: "Operator" = ... """ replaces the destination with the source if it is lighter, otherwise keeps the source. """ MULTIPLY: "Operator" = ... """ source and destination layers are multiplied. This causes the result to be at least as dark as the darker inputs. """ OUT: "Operator" = ... """draw source where there was no destination content (unbounded)""" OVER: "Operator" = ... """draw source layer on top of destination layer (bounded)""" OVERLAY: "Operator" = ... """ multiplies or screens, depending on the lightness of the destination color. """ SATURATE: "Operator" = ... """like over, but assuming source and dest are disjoint geometries""" SCREEN: "Operator" = ... """ source and destination are complemented and multiplied. This causes the result to be at least as light as the lighter inputs. """ SOFT_LIGHT: "Operator" = ... """Darkens or lightens, dependent on source color.""" SOURCE: "Operator" = ... """replace destination layer (bounded)""" XOR: "Operator" = ... """source and destination are shown where there is only one of them""" class Extend(_IntEnum): """ These constants are used to describe how :class:`Pattern` color/alpha will be determined for areas "outside" the pattern's natural area, (for example, outside the surface bounds or outside the gradient geometry). The default extend mode is :attr:`NONE` for :class:`SurfacePattern` and :attr:`PAD` for :class:`Gradient` patterns. .. versionadded:: 1.13 """ NONE: "Extend" = ... """pixels outside of the source pattern are fully transparent""" PAD: "Extend" = ... """ pixels outside of the pattern copy the closest pixel from the source (Since 1.2; but only implemented for surface patterns since 1.6) """ REFLECT: "Extend" = ... """ the pattern is tiled by reflecting at the edges (Implemented for surface patterns since 1.6) """ REPEAT: "Extend" = ... """the pattern is tiled by repeating""" class FontSlant(_IntEnum): """ These constants specify variants of a :class:`FontFace` based on their slant. .. versionadded:: 1.13 """ ITALIC: "FontSlant" = ... """Italic font style""" NORMAL: "FontSlant" = ... """Upright font style""" OBLIQUE: "FontSlant" = ... """Oblique font style""" class FontWeight(_IntEnum): """ These constants specify variants of a :class:`FontFace` based on their weight. .. versionadded:: 1.13 """ BOLD: "FontWeight" = ... """Bold font weight""" NORMAL: "FontWeight" = ... """Normal font weight""" class Status(_IntEnum): """ .. versionadded:: 1.13 """ CLIP_NOT_REPRESENTABLE: "Status" = ... DEVICE_ERROR: "Status" = ... DEVICE_FINISHED: "Status" = ... DEVICE_TYPE_MISMATCH: "Status" = ... FILE_NOT_FOUND: "Status" = ... FONT_TYPE_MISMATCH: "Status" = ... INVALID_CLUSTERS: "Status" = ... INVALID_CONTENT: "Status" = ... INVALID_DASH: "Status" = ... INVALID_DSC_COMMENT: "Status" = ... INVALID_FORMAT: "Status" = ... INVALID_INDEX: "Status" = ... INVALID_MATRIX: "Status" = ... INVALID_MESH_CONSTRUCTION: "Status" = ... INVALID_PATH_DATA: "Status" = ... INVALID_POP_GROUP: "Status" = ... INVALID_RESTORE: "Status" = ... INVALID_SIZE: "Status" = ... INVALID_SLANT: "Status" = ... INVALID_STATUS: "Status" = ... INVALID_STRIDE: "Status" = ... INVALID_STRING: "Status" = ... INVALID_VISUAL: "Status" = ... INVALID_WEIGHT: "Status" = ... JBIG2_GLOBAL_MISSING: "Status" = ... """ .. versionadded:: 1.14 """ LAST_STATUS: "Status" = ... NEGATIVE_COUNT: "Status" = ... NO_CURRENT_POINT: "Status" = ... NO_MEMORY: "Status" = ... NULL_POINTER: "Status" = ... PATTERN_TYPE_MISMATCH: "Status" = ... READ_ERROR: "Status" = ... SUCCESS: "Status" = ... SURFACE_FINISHED: "Status" = ... SURFACE_TYPE_MISMATCH: "Status" = ... TEMP_FILE_ERROR: "Status" = ... USER_FONT_ERROR: "Status" = ... USER_FONT_IMMUTABLE: "Status" = ... USER_FONT_NOT_IMPLEMENTED: "Status" = ... WRITE_ERROR: "Status" = ... TAG_ERROR: "Status" = ... """ .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ FREETYPE_ERROR: "Status" = ... """ .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ PNG_ERROR: "Status" = ... """ .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ WIN32_GDI_ERROR: "Status" = ... """ .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ DWRITE_ERROR: "Status" = ... """ .. versionadded:: 1.23.0 Only available with cairo 1.17.6+ """ SVG_FONT_ERROR: "Status" = ... """ .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ class PDFVersion(_IntEnum): """ These constants are used to describe the version number of the PDF specification that a generated PDF file will conform to. .. versionadded:: 1.13 """ VERSION_1_4: "PDFVersion" = ... """The version 1.4 of the PDF specification.""" VERSION_1_5: "PDFVersion" = ... """The version 1.5 of the PDF specification.""" VERSION_1_6: "PDFVersion" = ... """ The version 1.6 of the PDF specification. .. versionadded:: 1.23.0 Only available with cairo 1.17.6+ """ VERSION_1_7: "PDFVersion" = ... """ The version 1.7 of the PDF specification. .. versionadded:: 1.23.0 Only available with cairo 1.17.6+ """ class PSLevel(_IntEnum): """ These constants are used to describe the language level of the PostScript Language Reference that a generated PostScript file will conform to. Note: the constants are only defined when cairo has been compiled with PS support enabled. .. versionadded:: 1.13 """ LEVEL_2: "PSLevel" = ... """The language level 2 of the PostScript specification.""" LEVEL_3: "PSLevel" = ... """The language level 3 of the PostScript specification.""" class PathDataType(_IntEnum): """ These constants are used to describe the type of one portion of a path when represented as a :class:`Path`. .. versionadded:: 1.13 """ CLOSE_PATH: "PathDataType" = ... """A close-path operation""" CURVE_TO: "PathDataType" = ... """A curve-to operation""" LINE_TO: "PathDataType" = ... """ A line-to operation""" MOVE_TO: "PathDataType" = ... """A move-to operation""" class RegionOverlap(_IntEnum): """ .. versionadded:: 1.13 """ IN: "RegionOverlap" = ... """The contents are entirely inside the region.""" OUT: "RegionOverlap" = ... """The contents are entirely outside the region.""" PART: "RegionOverlap" = ... """The contents are partially inside and partially outside the region.""" class SVGVersion(_IntEnum): """ These constants are used to describe the version number of the SVG specification that a generated SVG file will conform to. .. versionadded:: 1.13 """ VERSION_1_1: "SVGVersion" = ... """The version 1.1 of the SVG specification.""" VERSION_1_2: "SVGVersion" = ... """The version 1.2 of the SVG specification.""" class SVGUnit(_IntEnum): """ :class:`SVGUnit` is used to describe the units valid for coordinates and lengths in the SVG specification. See also: * https://www.w3.org/TR/SVG/coords.htmlUnits * https://www.w3.org/TR/SVG/types.htmlDataTypeLength * https://www.w3.org/TR/css-values-3/lengths .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ USER: "SVGUnit" = ... """ User unit, a value in the current coordinate system. If used in the root element for the initial coordinate systems it corresponds to pixels. """ EM: "SVGUnit" = ... """The size of the element's font.""" EX: "SVGUnit" = ... """The x-height of the element’s font.""" PX: "SVGUnit" = ... """Pixels (1px = 1/96th of 1in).""" IN: "SVGUnit" = ... """Inches (1in = 2.54cm = 96px)""" CM: "SVGUnit" = ... """Centimeters (1cm = 96px/2.54).""" MM: "SVGUnit" = ... """Millimeters (1mm = 1/10th of 1cm).""" PT: "SVGUnit" = ... """Points (1pt = 1/72th of 1in).""" PC: "SVGUnit" = ... """Picas (1pc = 1/6th of 1in).""" PERCENT: "SVGUnit" = ... """Percent, a value that is some fraction of another reference value.""" class PDFMetadata(_IntEnum): """ :class:`PDFMetadata` is used by the :meth:`PDFSurface.set_metadata` method to specify the metadata to set. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ TITLE: "PDFMetadata" = ... """The document title""" AUTHOR: "PDFMetadata" = ... """The document author""" SUBJECT: "PDFMetadata" = ... """The document subject""" KEYWORDS: "PDFMetadata" = ... """The document keywords""" CREATOR: "PDFMetadata" = ... """The document creator""" CREATE_DATE: "PDFMetadata" = ... """The document creation date""" MOD_DATE: "PDFMetadata" = ... """The document modification date""" class PDFOutlineFlags(_IntEnum): """ :class:`PDFOutlineFlags` is used by the :meth:`PDFSurface.add_outline` method to specify the attributes of an outline item. These flags may be bitwise-or'd to produce any combination of flags. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ OPEN: "PDFOutlineFlags" = ... """The outline item defaults to open in the PDF viewer""" BOLD: "PDFOutlineFlags" = ... """The outline item is displayed by the viewer in bold text""" ITALIC: "PDFOutlineFlags" = ... """The outline item is displayed by the viewer in italic text""" class ScriptMode(_IntEnum): """ A set of script output variants. .. versionadded:: 1.14 """ ASCII: "ScriptMode" = ... """the output will be in readable text (default)""" BINARY: "ScriptMode" = ... """the output will use byte codes.""" class Matrix: """ *Matrix* is used throughout cairo to convert between different coordinate spaces. A *Matrix* holds an affine transformation, such as a scale, rotation, shear, or a combination of these. The transformation of a point (x,y) is given by:: x_new = xx * x + xy * y + x0 y_new = yx * x + yy * y + y0 The current transformation matrix of a :class:`Context`, represented as a *Matrix*, defines the transformation from user-space coordinates to device-space coordinates. Some standard Python operators can be used with matrices: To read the values from a *Matrix*:: xx, yx, xy, yy, x0, y0 = matrix To multiply two matrices:: matrix3 = matrix1.multiply(matrix2) # or equivalently matrix3 = matrix1 * matrix2 To compare two matrices:: matrix1 == matrix2 matrix1 != matrix2 For more information on matrix transformation see https://www.cairographics.org/cookbook/matrix_transform/ """ def __init__(self, xx: float = 1.0, yx: float = 0.0, xy: float = 0.0, yy: float = 1.0, x0: float = 0.0, y0: float = 0.0) -> None: """ :param xx: xx component of the affine transformation :param yx: yx component of the affine transformation :param xy: xy component of the affine transformation :param yy: yy component of the affine transformation :param x0: X translation component of the affine transformation :param y0: Y translation component of the affine transformation Create a new *Matrix* with the affine transformation given by *xx, yx, xy, yy, x0, y0*. The transformation is given by:: x_new = xx * x + xy * y + x0 y_new = yx * x + yy * y + y0 To create a new identity matrix:: matrix = cairo.Matrix() To create a matrix with a transformation which translates by tx and ty in the X and Y dimensions, respectively:: matrix = cairo.Matrix(x0=tx, y0=ty) To create a matrix with a transformation that scales by sx and sy in the X and Y dimensions, respectively:: matrix = cairo.Matrix(xx=sy, yy=sy) """ @classmethod def init_rotate(cls, radians: float) -> "Matrix": """ :param radians: angle of rotation, in radians. The direction of rotation is defined such that positive angles rotate in the direction from the positive X axis toward the positive Y axis. With the default axis orientation of cairo, positive angles rotate in a clockwise direction. :returns: a new *Matrix* set to a transformation that rotates by *radians*. """ def invert(self) -> Optional["Matrix"]: """ :returns: If *Matrix* has an inverse, modifies *Matrix* to be the inverse matrix and returns *None* :raises: :exc:`cairo.Error` if the *Matrix* as no inverse Changes *Matrix* to be the inverse of it's original value. Not all transformation matrices have inverses; if the matrix collapses points together (it is *degenerate*), then it has no inverse and this function will fail. """ def multiply(self, matrix2: "Matrix") -> "Matrix": """ :param matrix2: a second matrix :returns: a new *Matrix* Multiplies the affine transformations in *Matrix* and *matrix2* together. The effect of the resulting transformation is to first apply the transformation in *Matrix* to the coordinates and then apply the transformation in *matrix2* to the coordinates. It is allowable for result to be identical to either *Matrix* or *matrix2*. """ def rotate(self, radians: float) -> None: """ :param radians: angle of rotation, in radians. The direction of rotation is defined such that positive angles rotate in the direction from the positive X axis toward the positive Y axis. With the default axis orientation of cairo, positive angles rotate in a clockwise direction. Initialize *Matrix* to a transformation that rotates by *radians*. """ def scale(self, sx: float, sy: float) -> None: """ :param sx: scale factor in the X direction :param sy: scale factor in the Y direction Applies scaling by *sx, sy* to the transformation in *Matrix*. The effect of the new transformation is to first scale the coordinates by *sx* and *sy*, then apply the original transformation to the coordinates. """ def transform_distance(self, dx: float, dy: float) -> Tuple[float, float]: """ :param dx: X component of a distance vector. :param dy: Y component of a distance vector. :returns: the transformed distance vector (dx,dy), both float Transforms the distance vector *(dx,dy)* by *Matrix*. This is similar to :meth:`.transform_point` except that the translation components of the transformation are ignored. The calculation of the returned vector is as follows:: dx2 = dx1 * a + dy1 * c dy2 = dx1 * b + dy1 * d Affine transformations are position invariant, so the same vector always transforms to the same vector. If *(x1,y1)* transforms to *(x2,y2)* then *(x1+dx1,y1+dy1)* will transform to *(x1+dx2,y1+dy2)* for all values of *x1* and *x2*. """ def transform_point(self, x: float, y: float) -> Tuple[float, float]: """ :param x: X position. :param y: Y position. :returns: the transformed point (x,y), both float Transforms the point *(x, y)* by *Matrix*. """ def translate(self, tx: float, ty: float) -> None: """ :param tx: amount to translate in the X direction :param ty: amount to translate in the Y direction Applies a transformation by *tx, ty* to the transformation in *Matrix*. The effect of the new transformation is to first translate the coordinates by *tx* and *ty*, then apply the original transformation to the coordinates. """ xx: float = ... """ xx component of the affine transformation .. versionadded:: 1.12.0 """ yx: float = ... """ yx component of the affine transformation .. versionadded:: 1.12.0 """ xy: float = ... """ xy component of the affine transformation .. versionadded:: 1.12.0 """ yy: float = ... """ yy component of the affine transformation .. versionadded:: 1.12.0 """ x0: float = ... """ X translation component of the affine transformation .. versionadded:: 1.12.0 """ y0: float = ... """ Y translation component of the affine transformation .. versionadded:: 1.12.0 """ class Pattern: """ *Pattern* is the abstract base class from which all the other pattern classes derive. It cannot be instantiated directly. """ def get_extend(self) -> Extend: """ :returns: the current extend strategy used for drawing the *Pattern*. Gets the current extend mode for the *Pattern*. See :class:`cairo.Extend` attributes for details on the semantics of each extend strategy. """ def get_matrix(self) -> Matrix: """ :returns: a new :class:`Matrix` which stores a copy of the *Pattern's* transformation matrix """ def get_filter(self) -> Filter: """ :returns: the current filter used for resizing the pattern. .. versionadded:: 1.12.0 Used to be a method of :class:`SurfacePattern` before """ def set_filter(self, filter: Filter) -> None: """ :param filter: a filter describing the filter to use for resizing the pattern Note that you might want to control filtering even when you do not have an explicit *Pattern* object, (for example when using :meth:`Context.set_source_surface`). In these cases, it is convenient to use :meth:`Context.get_source` to get access to the pattern that cairo creates implicitly. For example:: context.set_source_surface(image, x, y) context.get_source().set_filter(cairo.FILTER_NEAREST) .. versionadded:: 1.12.0 Used to be a method of :class:`SurfacePattern` before """ def set_extend(self, extend: Extend) -> None: """ :param extend: an extend describing how the area outside of the *Pattern* will be drawn Sets the mode to be used for drawing outside the area of a *Pattern*. The default extend mode is :attr:`cairo.Extend.NONE` for :class:`SurfacePattern` and :attr:`cairo.Extend.PAD` for :class:`Gradient` Patterns. """ def set_matrix(self, matrix: Matrix) -> None: """ :param matrix: a :class:`Matrix` Sets the *Pattern's* transformation matrix to *matrix*. This matrix is a transformation from user space to pattern space. When a *Pattern* is first created it always has the identity matrix for its transformation matrix, which means that pattern space is initially identical to user space. Important: Please note that the direction of this transformation matrix is from user space to pattern space. This means that if you imagine the flow from a *Pattern* to user space (and on to device space), then coordinates in that flow will be transformed by the inverse of the *Pattern* matrix. For example, if you want to make a *Pattern* appear twice as large as it does by default the correct code to use is:: matrix = cairo.Matrix(xx=0.5,yy=0.5) pattern.set_matrix(matrix) Meanwhile, using values of 2.0 rather than 0.5 in the code above would cause the *Pattern* to appear at half of its default size. Also, please note the discussion of the user-space locking semantics of :class:`Context.set_source`. """ def get_dither(self) -> Dither: """ :returns: the current dithering mode. Gets the current dithering mode, as set by :meth:`Pattern.set_dither`. .. versionadded:: 1.25.0 Only available with cairo 1.18.0+ """ def set_dither(self, dither: Dither) -> None: """ :param dither: a :class:`Dither` describing the new dithering mode Set the dithering mode of the rasterizer used for drawing shapes. This value is a hint, and a particular backend may or may not support a particular value. At the current time, only pixman is supported. .. versionadded:: 1.25.0 Only available with cairo 1.18.0+ """ class Glyph(Tuple[int, float, float]): """ The :class:`Glyph` holds information about a single glyph when drawing or measuring text. A font is (in simple terms) a collection of shapes used to draw text. A glyph is one of these shapes. There can be multiple glyphs for a single character (alternates to be used in different contexts, for example), or a glyph can be a ligature of multiple characters. Cairo doesn't expose any way of converting input text into glyphs, so in order to use the Cairo interfaces that take arrays of glyphs, you must directly access the appropriate underlying font system. Note that the offsets given by x and y are not cumulative. When drawing or measuring text, each glyph is individually positioned with respect to the overall origin .. versionadded:: 1.15 In prior versions a (int, float, float) tuple was used instead of :class:`Glyph`. """ index: int = ... # type: ignore x: float = ... y: float = ... def __init__(self, index: int, x: float, y: float) -> None: """ :param index: glyph index in the font. The exact interpretation of the glyph index depends on the font technology being used. :param x: the offset in the X direction between the origin used for drawing or measuring the string and the origin of this glyph. :param y: the offset in the Y direction between the origin used for drawing or measuring the string and the origin of this glyph. """ class TextCluster(Tuple[int, int]): """ .. versionadded:: 1.15 The :class:`TextCluster` structure holds information about a single text cluster. A text cluster is a minimal mapping of some glyphs corresponding to some UTF-8 text. For a cluster to be valid, both ``num_bytes`` and ``num_glyphs`` should be non-negative, and at least one should be non-zero. Note that clusters with zero glyphs are not as well supported as normal clusters. For example, PDF rendering applications typically ignore those clusters when PDF text is being selected. See :meth:`Context.show_text_glyphs` for how clusters are used in advanced text operations. """ num_bytes: int = ... num_glyphs: int = ... def __init__(self, num_bytes: int, num_glyphs: int) -> None: """ :param num_bytes: the number of bytes of UTF-8 text covered by cluster :param num_glyphs: the number of glyphs covered by cluster """ class TextClusterFlags(_IntEnum): """ Specifies properties of a text cluster mapping. .. versionadded:: 1.14 """ BACKWARD: "TextClusterFlags" = ... """ The clusters in the cluster array map to glyphs in the glyph array from end to start. """ class TextExtents(Tuple[float, float, float, float, float, float]): """ .. versionadded:: 1.15 In prior versions a (float, float, float, float, float, float) tuple was used instead of :class:`TextExtents`. The :class:`TextExtents` class stores the extents of a single glyph or a string of glyphs in user-space coordinates. Because text extents are in user-space coordinates, they are mostly, but not entirely, independent of the current transformation matrix. If you call ``context.scale(2.0, 2.0)``, text will be drawn twice as big, but the reported text extents will not be doubled. They will change slightly due to hinting (so you can't assume that metrics are independent of the transformation matrix), but otherwise will remain unchanged. """ x_bearing: float = ... y_bearing: float = ... width: float = ... height: float = ... x_advance: float = ... y_advance: float = ... def __init__(self, x_bearing: float, y_bearing: float, width: float, height: float, x_advance: float, y_advance: float) -> None: """ :param x_bearing: the horizontal distance from the origin to the leftmost part of the glyphs as drawn. Positive if the glyphs lie entirely to the right of the origin. :param y_bearing: the vertical distance from the origin to the topmost part of the glyphs as drawn. Positive only if the glyphs lie completely below the origin; will usually be negative. :param width: width of the glyphs as drawn :param height: height of the glyphs as drawn :param x_advance: distance to advance in the X direction after drawing these glyphs :param y_advance: distance to advance in the Y direction after drawing these glyphs. Will typically be zero except for vertical text layout as found in East-Asian languages. """ class RectangleInt: """ RectangleInt is a data structure for holding a rectangle with integer coordinates. .. versionadded:: 1.11.0 """ height: int = ... width: int = ... x: int = ... y: int = ... def __init__(self, x: int=0, y: int=0, width: int=0, height: int=0) -> None: """ :param x: X coordinate of the left side of the rectangle. :param y: Y coordinate of the top side of the rectangle. :param width: Width of the rectangle. :param height: Height of the rectangle. Allocates a new RectangleInt object. """ class FontFace: """ A *cairo.FontFace* specifies all aspects of a font other than the size or font matrix (a font matrix is used to distort a font by sheering it or scaling it unequally in the two directions). A *FontFace* can be set on a :class:`Context` by using :meth:`Context.set_font_face` the size and font matrix are set with :meth:`Context.set_font_size` and :meth:`Context.set_font_matrix`. There are various types of *FontFace*, depending on the font backend they use. .. note:: This class cannot be instantiated directly, it is returned by :meth:`Context.get_font_face`. """ class FontOptions: """ An opaque structure holding all options that are used when rendering fonts. Individual features of a *FontOptions* can be set or accessed using functions named *FontOptions.set_<feature_name>* and *FontOptions.get_<feature_name>*, like :meth:`FontOptions.set_antialias` and :meth:`FontOptions.get_antialias`. New features may be added to a *FontOptions* in the future. For this reason, :meth:`FontOptions.copy()`, :meth:`FontOptions.equal()`, :meth:`FontOptions.merge()`, and :meth:`FontOptions.hash()` should be used to copy, check for equality, merge, or compute a hash value of FontOptions objects. Implements `__eq__` and `__ne__` using `equal()` since 1.12.0. """ def __init__(self) -> None: """ Allocates a new FontOptions object with all options initialized to default values. """ def get_antialias(self) -> Antialias: """ :returns: the antialias mode for the *FontOptions* object """ def get_hint_style(self) -> HintStyle: """ :returns: the hint style for the *FontOptions* object """ def get_subpixel_order(self) -> SubpixelOrder: """ :returns: the subpixel order for the *FontOptions* object """ def set_antialias(self, antialias: Antialias) -> None: """ :param antialias: the antialias mode This specifies the type of antialiasing to do when rendering text. """ def set_hint_metrics(self, hint_metrics: HintMetrics) -> None: """ :param hint_metrics: the hint metrics mode This controls whether metrics are quantized to integer values in device units. """ def set_hint_style(self, hint_style: HintStyle) -> None: """ :param hint_style: the hint style This controls whether to fit font outlines to the pixel grid, and if so, whether to optimize for fidelity or contrast. """ def merge(self, other: "FontOptions") -> None: """ :param FontOptions other: another :class:`FontOptions` Merges non-default options from other into options , replacing existing values. This operation can be thought of as somewhat similar to compositing other onto options with the operation of :attr:`Operator.OVER`. .. versionadded:: 1.12.0 """ def copy(self) -> "FontOptions": """ :returns: a new :class:`FontOptions` Returns a new font options object copying the option values from original. .. versionadded:: 1.12.0 """ def hash(self) -> int: """ :returns: the hash value for the font options object Compute a hash for the font options object; this value will be useful when storing an object containing a :class:`FontOptions` in a hash table. .. versionadded:: 1.12.0 """ def equal(self, other: "FontOptions") -> bool: """ :param other: another :class:`FontOptions` :returns: :obj:`True` if all fields of the two font options objects match. Note that this function will return :obj:`False` if either object is in error. Compares two font options objects for equality. .. versionadded:: 1.12.0 """ def set_variations(self, variations: Optional[str]) -> None: """ :param variations: the new font variations, or :obj:`None` Sets the OpenType font variations for the font options object. Font variations are specified as a string with a format that is similar to the CSS font-variation-settings. The string contains a comma-separated list of axis assignments, which each assignment consists of a 4-character axis name and a value, separated by whitespace and optional equals sign. Examples: * wght=200,wdth=140.5 * wght 200 , wdth 140.5 .. versionadded:: 1.18.0 Only available with cairo 1.15.12+ """ def get_variations(self) -> str: """ :returns: the font variations for the font options object. The returned string belongs to the options and must not be modified. It is valid until either the font options object is destroyed or the font variations in this object is modified with :meth:`set_variations`. Gets the OpenType font variations for the font options object. See :meth:`set_variations` for details about the string format. .. versionadded:: 1.18.0 Only available with cairo 1.15.12+ """ def get_hint_metrics(self) -> HintMetrics: """ :returns: the hint metrics mode for the *FontOptions* object """ def set_subpixel_order(self, subpixel_order: SubpixelOrder) -> None: """ :param subpixel_order: the subpixel order The subpixel order specifies the order of color elements within each pixel on the display device when rendering with an antialiasing mode of :attr:`cairo.Antialias.SUBPIXEL`. """ def set_color_mode(self, color_mode: ColorMode) -> None: """ :param color_mode: the new color mode Sets the color mode for the font options object. This controls whether color fonts are to be rendered in color or as outlines. See the documentation for :class:`ColorMode` for full details. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ def get_color_mode(self) -> ColorMode: """ :returns: the color mode for the font options object Gets the color mode for the font options object. See the documentation for :class:`ColorMode` for full details. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ def set_color_palette(self, palette_index: int) -> None: """ :param palette_index: the palette index in the CPAL table Sets the OpenType font color palette for the font options object. OpenType color fonts with a CPAL table may contain multiple palettes. The default color palette index is :data:`COLOR_PALETTE_DEFAULT`. If palette_index is invalid, the default palette is used. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ def get_color_palette(self) -> int: """ :returns: the palette index Gets the OpenType color font palette for the font options object. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ def set_custom_palette_color(self, index: int, red: float, green: float, blue: float, alpha: float) -> None: """ :param index: the index of the color to set :param red: red component of color :param green: green component of color :param blue: blue component of color :param alpha: alpha component of color Sets a custom palette color for the font options object. This overrides the palette color at the specified color index. This override is independent of the selected palette index and will remain in place even if :meth:`FontOptions.set_color_palette` is called to change the palette index. It is only possible to override color indexes already in the font palette. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ def get_custom_palette_color(self, index: int) -> Tuple[float, float, float, float]: """ :param index: the index of the color to get :returns: a (red, green, blue, alpha) tuple of float :raises Error: if no custom color exists for the color index. Gets the custom palette color for the color index for the font options object. .. versionadded:: 1.25.0 Only available with cairo 1.17.8+ """ class ScaledFont: """ A *ScaledFont* is a font scaled to a particular size and device resolution. A *ScaledFont* is most useful for low-level font usage where a library or application wants to cache a reference to a scaled font to speed up the computation of metrics. There are various types of scaled fonts, depending on the font backend they use. """ def __init__(self, font_face: FontFace, font_matrix: Matrix, ctm: Matrix, options: FontOptions) -> None: """ :param font_face: a :class:`FontFace` instance :param font_matrix: font space to user space transformation :class:`Matrix` for the font. In the simplest case of a N point font, this matrix is just a scale by N, but it can also be used to shear the font or stretch it unequally along the two axes. See :meth:`Context.set_font_matrix`. :param ctm: user to device transformation :class:`Matrix` with which the font will be used. :param options: a :class:`FontOptions` instance to use when getting metrics for the font and rendering with it. Creates a *ScaledFont* object from a *FontFace* and matrices that describe the size of the font and the environment in which it will be used. """ def extents(self) -> Tuple[float, float, float, float, float]: """ Gets the metrics for a *ScaledFont*. """ def get_ctm(self) -> Matrix: """ :returns: the CTM Returns the CTM with which scaled_font was created into ctm. Note that the translation offsets (x0, y0) of the CTM are ignored by :func:`ScaledFont`. So, the matrix this function returns always has 0, 0 as x0, y0. .. versionadded:: 1.12.0 """ def get_font_face(self) -> FontFace: """ :returns: the :class:`FontFace` that this *ScaledFont* was created for. .. versionadded:: 1.2 """ def get_font_matrix(self) -> Matrix: """ :returns: the matrix Returns the font matrix with which scaled_font was created. """ def get_font_options(self) -> FontOptions: """ :returns: font options Returns the font options with which scaled_font was created. .. versionadded:: 1.12.0 """ def get_scale_matrix(self) -> Matrix: """ :returns: the scale :class:`Matrix` The scale matrix is product of the font matrix and the ctm associated with the scaled font, and hence is the matrix mapping from font space to device space. .. versionadded:: 1.8 """ def glyph_extents(self, glyphs: Sequence[Glyph]) -> TextExtents: """ :param glyphs: glyphs, a sequence of :class:`Glyph` .. versionadded:: 1.15 Gets the extents for a list of glyphs. The extents describe a user-space rectangle that encloses the "inked" portion of the glyphs, (as they would be drawn by :meth:`Context.show_glyphs` if the cairo graphics state were set to the same font_face, font_matrix, ctm, and font_options as scaled_font ). Additionally, the x_advance and y_advance values indicate the amount by which the current point would be advanced by cairo_show_glyphs(). Note that whitespace glyphs do not contribute to the size of the rectangle (extents.width and extents.height). """ def text_extents(self, text: str) -> TextExtents: """ :param text: text Gets the extents for a string of text. The extents describe a user-space rectangle that encloses the "inked" portion of the text drawn at the origin (0,0) (as it would be drawn by :meth:`Context.show_text` if the cairo graphics state were set to the same font_face, font_matrix, ctm, and font_options as *ScaledFont*). Additionally, the x_advance and y_advance values indicate the amount by which the current point would be advanced by :meth:`Context.show_text`. Note that whitespace characters do not directly contribute to the size of the rectangle (width and height). They do contribute indirectly by changing the position of non-whitespace characters. In particular, trailing whitespace characters are likely to not affect the size of the rectangle, though they will affect the x_advance and y_advance values. .. versionadded:: 1.2 """ def text_to_glyphs(self, x: float, y: float, utf8: str, with_clusters: bool = True) -> Union[Tuple[List[Glyph], List["TextCluster"], TextClusterFlags], List[Glyph]]: """ :param x: X position to place first glyph :param y: Y position to place first glyph :param utf8: a string of text :param with_clusters: If :obj:`False` only the glyph list will computed and returned :returns: a tuple of ([:class:`Glyph`], [:class:`TextCluster`], :class:`TextClusterFlags`) :raises Error: .. versionadded:: 1.15 Converts UTF-8 text to a list of glyphs, with cluster mapping, that can be used to render later. For details of how clusters, and cluster_flags map input UTF-8 text to the output glyphs see :meth:`Context.show_text_glyphs`. The output values can be readily passed to :meth:`Context.show_text_glyphs` :meth:`Context.show_glyphs`, or related functions, assuming that the exact same scaled font is used for the operation. """ _SomeDevice = TypeVar("_SomeDevice", bound="Device") class Device: """ A :class:`Device` represents the driver interface for drawing operations to a :class:`Surface`. .. versionadded:: 1.14 .. note:: .. versionadded:: 1.17.0 :class:`cairo.Device` can be used as a context manager: .. code:: python # device.finish() will be called on __exit__ with cairo.ScriptDevice(f) as device: pass """ def finish(self) -> None: """ This function finishes the device and drops all references to external resources. All surfaces, fonts and other objects created for this device will be finished, too. Further operations on the device will not affect the device but will instead trigger a :attr:`Status.DEVICE_FINISHED` error. This function may acquire devices. .. versionadded:: 1.14 """ def flush(self) -> None: """ Finish any pending operations for the device and also restore any temporary modifications cairo has made to the device's state. This function must be called before switching from using the device with Cairo to operating on it directly with native APIs. If the device doesn't support direct access, then this function does nothing. This function may acquire devices. .. versionadded:: 1.14 """ def acquire(self) -> None: """ :raises cairo.Error: If the device is in an error state and could not be acquired. Acquires the device for the current thread. This function will block until no other thread has acquired the device. If the does not raise, you successfully acquired the device. From now on your thread owns the device and no other thread will be able to acquire it until a matching call to :meth:`release`. It is allowed to recursively acquire the device multiple times from the same thread. After a successful call to :meth:`acquire`, a matching call to :meth:`release` is required. .. note:: You must never acquire two different devices at the same time unless this is explicitly allowed. Otherwise the possibility of deadlocks exist. As various Cairo functions can acquire devices when called, these functions may also cause deadlocks when you call them with an acquired device. So you must not have a device acquired when calling them. These functions are marked in the documentation. .. versionadded:: 1.14 """ def release(self) -> None: """ Releases a device previously acquired using :meth:`acquire`. See that function for details. .. versionadded:: 1.14 """ def __enter__(self: _SomeDevice) -> _SomeDevice: ... __exit__: Any = ... _PathLike = Union[Text, ByteString] _FileLike = BinaryIO _SomeSurface = TypeVar("_SomeSurface", bound="Surface") class Surface: """ cairo.Surface is the abstract type representing all different drawing targets that cairo can render to. The actual drawings are performed using a :class:`Context`. A cairo.Surface is created by using backend-specific constructors of the form cairo.<XXX>Surface(). *Surface* is the abstract base class from which all the other surface classes derive. It cannot be instantiated directly. .. note:: .. versionadded:: 1.17.0 :class:`cairo.Surface` can be used as a context manager: .. code:: python # surface.finish() will be called on __exit__ with cairo.SVGSurface("example.svg", 200, 200) as surface: pass # surface.unmap_image(image_surface) will be called on __exit__ with surface.map_to_image(None) as image_surface: pass """ def copy_page(self) -> None: """ Emits the current page for backends that support multiple pages, but doesn't clear it, so that the contents of the current page will be retained for the next page. Use :meth:`.show_page` if you want to get an empty page after the emission. :meth:`Context.copy_page` is a convenience function for this. .. versionadded:: 1.6 """ def create_for_rectangle(self, x: float, y: float, width: float, height: float) -> "Surface": """ :param x: the x-origin of the sub-surface from the top-left of the target surface (in device-space units) :param y: the y-origin of the sub-surface from the top-left of the target surface (in device-space units) :param width: width of the sub-surface (in device-space units) :param height: height of the sub-surface (in device-space units) :returns: a new surface Create a new surface that is a rectangle within the target surface. All operations drawn to this surface are then clipped and translated onto the target surface. Nothing drawn via this sub-surface outside of its bounds is drawn onto the target surface, making this a useful method for passing constrained child surfaces to library routines that draw directly onto the parent surface, i.e. with no further backend allocations, double buffering or copies. .. note:: The semantics of subsurfaces have not been finalized yet unless the rectangle is in full device units, is contained within the extents of the target surface, and the target or subsurface's device transforms are not changed. .. versionadded:: 1.12.0 """ def create_similar(self, content: Content, width: int, height: int) -> "Surface": """ :param content: the content for the new surface :param width: width of the new surface, (in device-space units) :param height: height of the new surface (in device-space units) :returns: a newly allocated *Surface*. Create a *Surface* that is as compatible as possible with the existing surface. For example the new surface will have the same fallback resolution and :class:`FontOptions`. Generally, the new surface will also use the same backend, unless that is not possible for some reason. Initially the surface contents are all 0 (transparent if contents have transparency, black otherwise.) """ def create_similar_image(self, format: Format, width: int, height: int) -> "ImageSurface": """ :param cairo.Format format: the format for the new surface :param width: width of the new surface, (in device-space units) :param height: height of the new surface, (in device-space units) :returns: a new image surface Create a new image surface that is as compatible as possible for uploading to and the use in conjunction with an existing surface. However, this surface can still be used like any normal image surface. Initially the surface contents are all 0 (transparent if contents have transparency, black otherwise.) .. versionadded:: 1.12.0 """ def finish(self) -> None: """ This method finishes the Surface and drops all references to external resources. For example, for the Xlib backend it means that cairo will no longer access the drawable, which can be freed. After calling finish() the only valid operations on a Surface are flushing and finishing it. Further drawing to the surface will not affect the surface but will instead trigger a `cairo.Error` exception. """ def flush(self) -> None: """ Do any pending drawing for the *Surface* and also restore any temporary modification's cairo has made to the *Surface's* state. This method must be called before switching from drawing on the *Surface* with cairo to drawing on it directly with native APIs. If the *Surface* doesn't support direct access, then this function does nothing. """ def get_content(self) -> Content: """ :returns: The content type of *Surface*, which indicates whether the *Surface* contains color and/or alpha information. .. versionadded:: 1.2 """ def get_device(self) -> Optional["Device"]: """ :returns: the device or :obj:`None` if the surface does not have an associated device This function returns the device for a surface. .. versionadded:: 1.14.0 """ def get_device_offset(self) -> Tuple[float, float]: """ :returns: (x_offset, y_offset) a tuple of float * x_offset: the offset in the X direction, in device units * y_offset: the offset in the Y direction, in device units This method returns the previous device offset set by :meth:`.set_device_offset`. .. versionadded:: 1.2 """ def get_device_scale(self) -> Tuple[float, float]: """ :returns: (x_scale,y_scale) a 2-tuple of float This function returns the previous device offset set by :meth:`Surface.set_device_scale`. .. versionadded:: 1.14.0 """ def get_fallback_resolution(self) -> Tuple[float, float]: """ :returns: (x_pixels_per_inch, y_pixels_per_inch) a tuple of float * x_pixels_per_inch: horizontal pixels per inch * y_pixels_per_inch: vertical pixels per inch This method returns the previous fallback resolution set by :meth:`.set_fallback_resolution`, or default fallback resolution if never set. .. versionadded:: 1.8 """ def get_font_options(self) -> FontOptions: """ :returns: a :class:`FontOptions` Retrieves the default font rendering options for the *Surface*. This allows display surfaces to report the correct subpixel order for rendering on them, print surfaces to disable hinting of metrics and so forth. The result can then be used with :class:`ScaledFont`. """ def get_mime_data(self, mime_type: str) -> Optional[bytes]: """ :param mime_type: the MIME type of the image data (:ref:`constants_MIME_TYPE`) :returns: :class:`bytes` or :obj:`None` Return mime data previously attached to surface with :meth:`set_mime_data` using the specified mime type. If no data has been attached with the given mime type, :obj:`None` is returned. .. versionadded:: 1.12.0 """ def has_show_text_glyphs(self) -> bool: """ :returns: :obj:`True` if surface supports :meth:`Context.show_text_glyphs`, :obj:`False` otherwise Returns whether the surface supports sophisticated :meth:`Context.show_text_glyphs` operations. That is, whether it actually uses the provided text and cluster data to a :meth:`Context.show_text_glyphs` call. Note: Even if this function returns :obj:`False`, a :meth:`Context.show_text_glyphs` operation targeted at surface will still succeed. It just will act like a :meth:`Context.show_glyphs` operation. Users can use this function to avoid computing UTF-8 text and cluster mapping if the target surface does not use it. .. versionadded:: 1.12.0 """ def map_to_image(self, extents: Optional[RectangleInt]) -> "ImageSurface": """ :param extents: limit the extraction to an rectangular region or :obj:`None` for the whole surface :returns: newly allocated image surface :raises Error: Returns an image surface that is the most efficient mechanism for modifying the backing store of the target surface. Note, the use of the original surface as a target or source whilst it is mapped is undefined. The result of mapping the surface multiple times is undefined. Calling :meth:`Surface.finish` on the resulting image surface results in undefined behavior. Changing the device transform of the image surface or of surface before the image surface is unmapped results in undefined behavior. The caller must use :meth:`Surface.unmap_image` to destroy this image surface. .. versionadded:: 1.15.0 """ def mark_dirty(self) -> None: """ Tells cairo that drawing has been done to *Surface* using means other than cairo, and that cairo should reread any cached areas. Note that you must call :meth:`.flush` before doing such drawing. """ def mark_dirty_rectangle(self, x: int, y: int, width: int, height: int) -> None: """ :param x: X coordinate of dirty rectangle :param y: Y coordinate of dirty rectangle :param width: width of dirty rectangle :param height: height of dirty rectangle Like :meth:`.mark_dirty`, but drawing has been done only to the specified rectangle, so that cairo can retain cached contents for other parts of the surface. Any cached clip set on the *Surface* will be reset by this function, to make sure that future cairo calls have the clip set that they expect. """ def set_device_offset(self, x_offset: float, y_offset: float) -> None: """ :param x_offset: the offset in the X direction, in device units :param y_offset: the offset in the Y direction, in device units Sets an offset that is added to the device coordinates determined by the CTM when drawing to *Surface*. One use case for this function is when we want to create a *Surface* that redirects drawing for a portion of an onscreen surface to an offscreen surface in a way that is completely invisible to the user of the cairo API. Setting a transformation via :meth:`Context.translate` isn't sufficient to do this, since functions like :meth:`Context.device_to_user` will expose the hidden offset. Note that the offset affects drawing to the surface as well as using the surface in a source pattern. """ def set_device_scale(self, x_scale: float, y_scale: float) -> None: """ :param x_scale: a scale factor in the X direction :param y_scale: a scale factor in the Y direction Sets a scale that is multiplied to the device coordinates determined by the CTM when drawing to surface . One common use for this is to render to very high resolution display devices at a scale factor, so that code that assumes 1 pixel will be a certain size will still work. Setting a transformation via :meth:`Context.translate` isn't sufficient to do this, since functions like :meth:`Context.device_to_user` will expose the hidden scale. .. versionadded:: 1.14.0 """ def set_fallback_resolution(self, x_pixels_per_inch: float, y_pixels_per_inch: float) -> None: """ :param x_pixels_per_inch: horizontal setting for pixels per inch :param y_pixels_per_inch: vertical setting for pixels per inch Set the horizontal and vertical resolution for image fallbacks. When certain operations aren't supported natively by a backend, cairo will fallback by rendering operations to an image and then overlaying that image onto the output. For backends that are natively vector-oriented, this function can be used to set the resolution used for these image fallbacks, (larger values will result in more detailed images, but also larger file sizes). Some examples of natively vector-oriented backends are the ps, pdf, and svg backends. For backends that are natively raster-oriented, image fallbacks are still possible, but they are always performed at the native device resolution. So this function has no effect on those backends. Note: The fallback resolution only takes effect at the time of completing a page (with :meth:`Context.show_page` or :meth:`Context.copy_page`) so there is currently no way to have more than one fallback resolution in effect on a single page. The default fallback resoultion is 300 pixels per inch in both dimensions. .. versionadded:: 1.2 """ def set_mime_data(self, mime_type: str, data: bytes) -> None: """ :param mime_type: the MIME type of the image data (:ref:`constants_MIME_TYPE`) :param data: the image data to attach to the surface Attach an image in the format ``mime_type`` to *Surface*. To remove the data from a surface, call this function with same mime type and :obj:`None` for data. The attached image (or filename) data can later be used by backends which support it (currently: PDF, PS, SVG and Win32 Printing surfaces) to emit this data instead of making a snapshot of the surface. This approach tends to be faster and requires less memory and disk space. The recognized MIME types are listed under :ref:`constants_MIME_TYPE`. See corresponding backend surface docs for details about which MIME types it can handle. Caution: the associated MIME data will be discarded if you draw on the surface afterwards. Use this function with care. .. versionadded:: 1.12.0 """ def show_page(self) -> None: """ Emits and clears the current page for backends that support multiple pages. Use :meth:`.copy_page` if you don't want to clear the page. There is a convenience function for this that takes a :meth:`Context.show_page`. .. versionadded:: 1.6 """ def supports_mime_type(self, mime_type: str) -> bool: """ :param mime_type: the mime type (:ref:`constants_MIME_TYPE`) :returns: :obj:`True` if surface supports mime_type, :obj:`False` otherwise Return whether surface supports ``mime_type``. .. versionadded:: 1.12.0 """ def write_to_png(self, fobj: Union[_FileLike, _PathLike]) -> None: """ :param fobj: a filename or writable file object :raises: :exc:`MemoryError` if memory could not be allocated for the operation :exc:`IOError` if an I/O error occurs while attempting to write the file Writes the contents of *Surface* to *fobj* as a PNG image. *fobj* can either be a filename or a file object opened in binary mode. """ def unmap_image(self, image: "ImageSurface") -> None: """ :param image: the currently mapped image Unmaps the image surface as returned from :meth:`Surface.map_to_image`. The content of the image will be uploaded to the target surface. Afterwards, the image is destroyed. Using an image surface which wasn't returned by :meth:`Surface.map_to_image` results in undefined behavior. .. versionadded:: 1.15.0 """ def __enter__(self: _SomeSurface) -> _SomeSurface: ... __exit__: Any = ... class ImageSurface(Surface): """ A *cairo.ImageSurface* provides the ability to render to memory buffers either allocated by cairo or by the calling code. The supported image formats are those defined in :class:`cairo.Format`. """ def __init__(self, format: Format, width: int, height: int) -> None: """ :param format: format of pixels in the surface to create :param width: width of the surface, in pixels :param height: height of the surface, in pixels :returns: a new *ImageSurface* Creates an *ImageSurface* of the specified format and dimensions. Initially the surface contents are all 0. (Specifically, within each pixel, each color or alpha channel belonging to format will be 0. The contents of bits within a pixel, but not belonging to the given format are undefined). """ @classmethod def create_for_data(cls, data: memoryview, format: Format, width: int, height: int, stride: int = ...) -> "ImageSurface": """ :param data: a writable Python buffer/memoryview object :param format: the format of pixels in the buffer :param width: the width of the image to be stored in the buffer :param height: the height of the image to be stored in the buffer :param stride: the number of bytes between the start of rows in the buffer as allocated. If not given the value from :meth:`cairo.Format.stride_for_width` is used. :returns: a new *ImageSurface* :raises: :exc:`MemoryError` in case of no memory. :exc:`cairo.Error` in case of invalid *stride* value. Creates an *ImageSurface* for the provided pixel data. The initial contents of buffer will be used as the initial image contents; you must explicitly clear the buffer, using, for example, cairo_rectangle() and cairo_fill() if you want it cleared. Note that the *stride* may be larger than width*bytes_per_pixel to provide proper alignment for each pixel and row. This alignment is required to allow high-performance rendering within cairo. The correct way to obtain a legal stride value is to call :meth:`cairo.Format.stride_for_width` with the desired format and maximum image width value, and use the resulting stride value to allocate the data and to create the :class:`ImageSurface`. See :meth:`cairo.Format.stride_for_width` for example code. """ @classmethod def create_from_png(cls, fobj: Union[_PathLike, _FileLike]) -> "ImageSurface": """ :param fobj: a :obj:`_PathLike`, file, or file-like object of the PNG to load. :returns: a new *ImageSurface* initialized the contents to the given PNG file. Creates a new image surface and initializes the contents to the given PNG file. *fobj* can either be a filename or a file object opened in binary mode. """ format_stride_for_width = Format.stride_for_width """ See :meth:`cairo.Format.stride_for_width`. .. versionadded:: 1.6 """ def get_data(self) -> memoryview: """ :returns: a Python buffer object for the data of the *ImageSurface*, for direct inspection or modification. On Python 3 a memoryview object is returned. .. versionadded:: 1.2 """ def get_format(self) -> Format: """ :returns: the format of the *ImageSurface*. :rtype: cairo.Format .. versionadded:: 1.2 """ def get_height(self) -> int: """ :returns: the height of the *ImageSurface* in pixels. """ def get_stride(self) -> int: """ :returns: the stride of the *ImageSurface* in bytes. The stride is the distance in bytes from the beginning of one row of the image data to the beginning of the next row. """ def get_width(self) -> int: """ :returns: the width of the *ImageSurface* in pixels. """ class SurfacePattern(Pattern): def __init__(self, surface: Surface) -> None: """ :param surface: a cairo :class:`Surface` """ def get_surface(self) -> Surface: """ :returns: the :class:`Surface` of the *SurfacePattern*. .. versionadded:: 1.4 """ class Context(Generic[_SomeSurface]): """ *Context* is the main object used when drawing with cairo. To draw with cairo, you create a *Context*, set the target surface, and drawing options for the *Context*, create shapes with functions like :meth:`Context.move_to` and :meth:`Context.line_to`, and then draw shapes with :meth:`Context.stroke` or :meth:`Context.fill`. *Contexts* can be pushed to a stack via :meth:`Context.save`. They may then safely be changed, without losing the current state. Use :meth:`Context.restore` to restore to the saved state. """ def __init__(self, target: _SomeSurface) -> None: """ :param target: target :class:`Surface` for the context :raises: :exc:`MemoryError` in case of no memory Creates a new *Context* with all graphics state parameters set to default values and with *target* as a target surface. The target surface should be constructed with a backend-specific function such as :class:`ImageSurface` (or any other cairo backend surface create variant). """ def append_path(self, path: Path) -> None: """ :param path: :class:`Path` to be appended Append the *path* onto the current path. The *path* may be either the return value from one of :meth:`Context.copy_path` or :meth:`Context.copy_path_flat` or it may be constructed manually (in C). """ def arc(self, xc: float, yc: float, radius: float, angle1: float, angle2: float) -> None: """ :param xc: X position of the center of the arc :param yc: Y position of the center of the arc :param radius: the radius of the arc :param angle1: the start angle, in radians :param angle2: the end angle, in radians Adds a circular arc of the given *radius* to the current path. The arc is centered at (*xc, yc*), begins at *angle1* and proceeds in the direction of increasing angles to end at *angle2*. If *angle2* is less than *angle1* it will be progressively increased by 2*PI until it is greater than *angle1*. If there is a current point, an initial line segment will be added to the path to connect the current point to the beginning of the arc. If this initial line is undesired, it can be avoided by calling :meth:`Context.new_sub_path` before calling :meth:`Context.arc`. Angles are measured in radians. An angle of 0.0 is in the direction of the positive X axis (in user space). An angle of PI/2.0 radians (90 degrees) is in the direction of the positive Y axis (in user space). Angles increase in the direction from the positive X axis toward the positive Y axis. So with the default transformation matrix, angles increase in a clockwise direction. To convert from degrees to radians, use ``degrees * (math.pi / 180)``. This function gives the arc in the direction of increasing angles; see :meth:`Context.arc_negative` to get the arc in the direction of decreasing angles. The arc is circular in user space. To achieve an elliptical arc, you can scale the current transformation matrix by different amounts in the X and Y directions. For example, to draw an ellipse in the box given by *x, y, width, height*:: ctx.save() ctx.translate(x + width / 2., y + height / 2.) ctx.scale(width / 2., height / 2.) ctx.arc(0., 0., 1., 0., 2 * math.pi) ctx.restore() """ def arc_negative(self, xc: float, yc: float, radius: float, angle1: float, angle2: float) -> None: """ :param xc: X position of the center of the arc :param yc: Y position of the center of the arc :param radius: the radius of the arc :param angle1: the start angle, in radians :param angle2: the end angle, in radians Adds a circular arc of the given *radius* to the current path. The arc is centered at (*xc, yc*), begins at *angle1* and proceeds in the direction of decreasing angles to end at *angle2*. If *angle2* is greater than *angle1* it will be progressively decreased by 2*PI until it is less than *angle1*. See :meth:`Context.arc` for more details. This function differs only in the direction of the arc between the two angles. """ def clip(self) -> None: """ Establishes a new clip region by intersecting the current clip region with the current path as it would be filled by :meth:`Context.fill` and according to the current :class:`fill rule <cairo.FillRule>` (see :meth:`Context.set_fill_rule`). After :meth:`.clip`, the current path will be cleared from the :class:`Context`. The current clip region affects all drawing operations by effectively masking out any changes to the surface that are outside the current clip region. Calling :meth:`.clip` can only make the clip region smaller, never larger. But the current clip is part of the graphics state, so a temporary restriction of the clip region can be achieved by calling :meth:`.clip` within a :meth:`Context.save`/:meth:`Context.restore` pair. The only other means of increasing the size of the clip region is :meth:`Context.reset_clip`. """ def clip_extents(self) -> Tuple[float, float, float, float]: """ :returns: (x1, y1, x2, y2), all float * *x1*: left of the resulting extents * *y1*: top of the resulting extents * *x2*: right of the resulting extents * *y2*: bottom of the resulting extents Computes a bounding box in user coordinates covering the area inside the current clip. .. versionadded:: 1.4 """ def clip_preserve(self) -> None: """ Establishes a new clip region by intersecting the current clip region with the current path as it would be filled by :meth:`Context.fill` and according to the current :class:`fill rule <cairo.FillRule>` (see :meth:`Context.set_fill_rule`). Unlike :meth:`Context.clip`, :meth:`.clip_preserve` preserves the path within the :class:`Context`. The current clip region affects all drawing operations by effectively masking out any changes to the surface that are outside the current clip region. Calling :meth:`.clip_preserve` can only make the clip region smaller, never larger. But the current clip is part of the graphics state, so a temporary restriction of the clip region can be achieved by calling :meth:`.clip_preserve` within a :meth:`Context.save`/:meth:`Context.restore` pair. The only other means of increasing the size of the clip region is :meth:`Context.reset_clip`. """ def close_path(self) -> None: """ Adds a line segment to the path from the current point to the beginning of the current sub-path, (the most recent point passed to :meth:`Context.move_to`), and closes this sub-path. After this call the current point will be at the joined endpoint of the sub-path. The behavior of :meth:`.close_path` is distinct from simply calling :meth:`Context.line_to` with the equivalent coordinate in the case of stroking. When a closed sub-path is stroked, there are no caps on the ends of the sub-path. Instead, there is a line join connecting the final and initial segments of the sub-path. If there is no current point before the call to :meth:`.close_path`, this function will have no effect. Note: As of cairo version 1.2.4 any call to :meth:`.close_path` will place an explicit MOVE_TO element into the path immediately after the CLOSE_PATH element, (which can be seen in :meth:`Context.copy_path` for example). This can simplify path processing in some cases as it may not be necessary to save the "last move_to point" during processing as the MOVE_TO immediately after the CLOSE_PATH will provide that point. """ def copy_clip_rectangle_list(self) -> List[Rectangle]: """ :returns: the current clip region as a list of rectangles in user coordinates. Returns a list of :class:`Rectangle` .. versionadded:: 1.4 """ def copy_page(self) -> None: """ Emits the current page for backends that support multiple pages, but doesn't clear it, so, the contents of the current page will be retained for the next page too. Use :meth:`Context.show_page` if you want to get an empty page after the emission. This is a convenience function that simply calls :meth:`Surface.copy_page` on *Context's* target. """ def copy_path(self) -> Path: """ :returns: :class:`Path` :raises: :exc:`MemoryError` in case of no memory Creates a copy of the current path and returns it to the user as a :class:`Path`. """ def copy_path_flat(self) -> Path: """ :returns: :class:`Path` :raises: :exc:`MemoryError` in case of no memory Gets a flattened copy of the current path and returns it to the user as a :class:`Path`. This function is like :meth:`Context.copy_path` except that any curves in the path will be approximated with piecewise-linear approximations, (accurate to within the current tolerance value). That is, the result is guaranteed to not have any elements of type CAIRO_PATH_CURVE_TO which will instead be replaced by a series of CAIRO_PATH_LINE_TO elements. """ def curve_to(self, x1: float, y1: float, x2: float, y2: float, x3: float, y3: float) -> None: """ :param x1: the X coordinate of the first control point :param y1: the Y coordinate of the first control point :param x2: the X coordinate of the second control point :param y2: the Y coordinate of the second control point :param x3: the X coordinate of the end of the curve :param y3: the Y coordinate of the end of the curve Adds a cubic Bézier spline to the path from the current point to position *(x3, y3)* in user-space coordinates, using *(x1, y1)* and *(x2, y2)* as the control points. After this call the current point will be *(x3, y3)*. If there is no current point before the call to :meth:`.curve_to` this function will behave as if preceded by a call to ``ctx.move_to(x1, y1)``. """ def device_to_user(self, x: float, y: float) -> Tuple[float, float]: """ :param x: X value of coordinate :param y: Y value of coordinate :returns: (x, y), both float Transform a coordinate from device space to user space by multiplying the given point by the inverse of the current transformation matrix (CTM). """ def device_to_user_distance(self, dx: float, dy: float) -> Tuple[float, float]: """ :param dx: X component of a distance vector :param dy: Y component of a distance vector :returns: (dx, dy), both float Transform a distance vector from device space to user space. This function is similar to :meth:`Context.device_to_user` except that the translation components of the inverse CTM will be ignored when transforming *(dx,dy)*. """ def fill(self) -> None: """ A drawing operator that fills the current path according to the current :class:`fill rule <cairo.FillRule>`, (each sub-path is implicitly closed before being filled). After :meth:`.fill`, the current path will be cleared from the :class:`Context`. See :meth:`Context.set_fill_rule` and :meth:`Context.fill_preserve`. """ def fill_extents(self) -> Tuple[float, float, float, float]: """ :returns: (x1, y1, x2, y2), all float * *x1*: left of the resulting extents * *y1*: top of the resulting extents * *x2*: right of the resulting extents * *y2*: bottom of the resulting extents Computes a bounding box in user coordinates covering the area that would be affected, (the "inked" area), by a :meth:`Context.fill` operation given the current path and fill parameters. If the current path is empty, returns an empty rectangle (0,0,0,0). Surface dimensions and clipping are not taken into account. Contrast with :meth:`Context.path_extents`, which is similar, but returns non-zero extents for some paths with no inked area, (such as a simple line segment). Note that :meth:`.fill_extents` must necessarily do more work to compute the precise inked areas in light of the fill rule, so :meth:`Context.path_extents` may be more desirable for sake of performance if the non-inked path extents are desired. See :meth:`Context.fill`, :meth:`Context.set_fill_rule` and :meth:`Context.fill_preserve`. """ def fill_preserve(self) -> None: """ A drawing operator that fills the current path according to the current :class:`fill rule <cairo.FillRule>`, (each sub-path is implicitly closed before being filled). Unlike :meth:`Context.fill`, :meth:`.fill_preserve` preserves the path within the :class:`Context`. See :meth:`Context.set_fill_rule` and :meth:`Context.fill`. """ def font_extents(self) -> Tuple[float, float, float, float, float]: """ :returns: (ascent, descent, height, max_x_advance, max_y_advance), all float Gets the font extents for the currently selected font. """ def get_antialias(self) -> Antialias: """ :returns: the current antialias mode, as set by :meth:`Context.set_antialias`. """ def get_current_point(self) -> Tuple[float, float]: """ :returns: (x, y), both float * *x*: X coordinate of the current point * *y*: Y coordinate of the current point Gets the current point of the current path, which is conceptually the final point reached by the path so far. The current point is returned in the user-space coordinate system. If there is no defined current point or if :class:`Context` is in an error status, *x* and *y* will both be set to 0.0. It is possible to check this in advance with :meth:`Context.has_current_point`. Most path construction functions alter the current point. See the following for details on how they affect the current point: :meth:`Context.new_path`, :meth:`Context.new_sub_path`, :meth:`Context.append_path`, :meth:`Context.close_path`, :meth:`Context.move_to`, :meth:`Context.line_to`, :meth:`Context.curve_to`, :meth:`Context.rel_move_to`, :meth:`Context.rel_line_to`, :meth:`Context.rel_curve_to`, :meth:`Context.arc`, :meth:`Context.arc_negative`, :meth:`Context.rectangle`, :meth:`Context.text_path`, :meth:`Context.glyph_path`. Some functions use and alter the current point but do not otherwise change current path: :meth:`Context.show_text`. Some functions unset the current path and as a result, current point: :meth:`Context.fill`, :meth:`Context.stroke`. """ def get_dash(self) -> Tuple[List[float], float]: """ :returns: (dashes, offset) * *dashes*: return value as a tuple for the dash array * *offset*: return value as float for the current dash offset Gets the current dash array. .. versionadded:: 1.4 """ def get_dash_count(self) -> int: """ :returns: the length of the dash array, or 0 if no dash array set. See also :meth:`Context.set_dash` and :meth:`Context.get_dash`. .. versionadded:: 1.4 """ def get_fill_rule(self) -> FillRule: """ :returns: the current fill rule, as set by :meth:`Context.set_fill_rule`. """ def get_font_face(self) -> FontFace: """ :returns: the current :class:`FontFace` for the :class:`Context`. """ def get_font_matrix(self) -> Matrix: """ :returns: the current :class:`Matrix` for the :class:`Context`. See :meth:`Context.set_font_matrix`. """ def get_font_options(self) -> FontOptions: """ :returns: the current :class:`FontOptions` for the :class:`Context`. Retrieves font rendering options set via :meth:`Context.set_font_options`. Note that the returned options do not include any options derived from the underlying surface; they are literally the options passed to :meth:`Context.set_font_options`. """ def get_group_target(self) -> Surface: """ :returns: the target :class:`Surface`. Gets the current destination :class:`Surface` for the :class:`Context`. This is either the original target surface as passed to :class:`Context` or the target surface for the current group as started by the most recent call to :meth:`Context.push_group` or :meth:`Context.push_group_with_content`. .. versionadded:: 1.2 """ def get_hairline(self) -> bool: """ :returns: whether hairline mode is set. Returns whether or not hairline mode is set, as set by :meth:`Context.set_hairline`. .. versionadded:: 1.23 Only available with cairo 1.17.6+ """ def get_line_cap(self) -> LineCap: """ :returns: the current line cap style, as set by :meth:`Context.set_line_cap`. """ def get_line_join(self) -> LineJoin: """ :returns: the current line join style, as set by :meth:`Context.set_line_join`. """ def get_line_width(self) -> float: """ :returns: the current line width This function returns the current line width value exactly as set by :meth:`Context.set_line_width`. Note that the value is unchanged even if the CTM has changed between the calls to :meth:`Context.set_line_width` and :meth:`.get_line_width`. """ def get_matrix(self) -> Matrix: """ :returns: the current transformation :class:`Matrix` (CTM) """ def get_miter_limit(self) -> float: """ :returns: the current miter limit, as set by :meth:`Context.set_miter_limit`. """ def get_operator(self) -> Operator: """ :returns: the current compositing operator for a :class:`Context`. """ def get_scaled_font(self) -> ScaledFont: """ :returns: the current :class:`ScaledFont` for a :class:`Context`. .. versionadded:: 1.4 """ def get_source(self) -> Pattern: """ :returns: the current source :class:`Pattern` for a :class:`Context`. """ def get_target(self) -> _SomeSurface: """ :returns: the target :class:`Surface` for the :class:`Context` """ def get_tolerance(self) -> float: """ :returns: the current tolerance value, as set by :meth:`Context.set_tolerance` """ def glyph_extents(self, glyphs: Sequence[Glyph]) -> TextExtents: """ :param glyphs: glyphs, a sequence of :class:`Glyph` Gets the extents for an array of glyphs. The extents describe a user-space rectangle that encloses the "inked" portion of the glyphs, (as they would be drawn by :meth:`Context.show_glyphs`). Additionally, the x_advance and y_advance values indicate the amount by which the current point would be advanced by :meth:`Context.show_glyphs`. Note that whitespace glyphs do not contribute to the size of the rectangle (extents.width and extents.height). """ def glyph_path(self, glyphs: Sequence[Glyph]) -> None: """ :param glyphs: glyphs to show, a sequence of :class:`Glyph` Adds closed paths for the glyphs to the current path. The generated path if filled, achieves an effect similar to that of :meth:`Context.show_glyphs`. """ def has_current_point(self) -> bool: """ :returns: True iff a current point is defined on the current path. See :meth:`Context.get_current_point` for details on the current point. .. versionadded:: 1.6 """ def identity_matrix(self) -> None: """ Resets the current transformation :class:`Matrix` (CTM) by setting it equal to the identity matrix. That is, the user-space and device-space axes will be aligned and one user-space unit will transform to one device-space unit. """ def in_clip(self, x: float, y: float) -> bool: """ :param x: X coordinate of the point to test :param y: Y coordinate of the point to test :returns: :obj:`True` if the point is inside, or :obj:`False` if outside. Tests whether the given point is inside the area that would be visible through the current clip, i.e. the area that would be filled by a :meth:`paint` operation. See :meth:`clip`, and :meth:`clip_preserve`. .. versionadded:: 1.12.0 """ def in_fill(self, x: float, y: float) -> bool: """ :param x: X coordinate of the point to test :param y: Y coordinate of the point to test :returns: True iff the point is inside the area that would be affected by a :meth:`Context.fill` operation given the current path and filling parameters. Surface dimensions and clipping are not taken into account. See :meth:`Context.fill`, :meth:`Context.set_fill_rule` and :meth:`Context.fill_preserve`. """ def in_stroke(self, x: float, y: float) -> bool: """ :param x: X coordinate of the point to test :param y: Y coordinate of the point to test :returns: True iff the point is inside the area that would be affected by a :meth:`Context.stroke` operation given the current path and stroking parameters. Surface dimensions and clipping are not taken into account. See :meth:`Context.stroke`, :meth:`Context.set_line_width`, :meth:`Context.set_line_join`, :meth:`Context.set_line_cap`, :meth:`Context.set_dash`, and :meth:`Context.stroke_preserve`. """ def line_to(self, x: float, y: float) -> None: """ :param x: the X coordinate of the end of the new line :param y: the Y coordinate of the end of the new line Adds a line to the path from the current point to position *(x, y)* in user-space coordinates. After this call the current point will be *(x, y)*. If there is no current point before the call to :meth:`.line_to` this function will behave as ``ctx.move_to(x, y)``. """ def mask(self, pattern: Pattern) -> None: """ :param pattern: a :class:`Pattern` A drawing operator that paints the current source using the alpha channel of *pattern* as a mask. (Opaque areas of *pattern* are painted with the source, transparent areas are not painted.) """ def mask_surface(self, surface: Surface, x: float = 0.0, y: float = 0.0) -> None: """ :param surface: a :class:`Surface` :param x: X coordinate at which to place the origin of *surface* :param y: Y coordinate at which to place the origin of *surface* A drawing operator that paints the current source using the alpha channel of *surface* as a mask. (Opaque areas of *surface* are painted with the source, transparent areas are not painted.) """ def move_to(self, x: float, y: float) -> None: """ :param x: the X coordinate of the new position :param y: the Y coordinate of the new position Begin a new sub-path. After this call the current point will be *(x, y)*. """ def new_path(self) -> None: """ Clears the current path. After this call there will be no path and no current point. """ def new_sub_path(self) -> None: """ Begin a new sub-path. Note that the existing path is not affected. After this call there will be no current point. In many cases, this call is not needed since new sub-paths are frequently started with :meth:`Context.move_to`. A call to :meth:`.new_sub_path` is particularly useful when beginning a new sub-path with one of the :meth:`Context.arc` calls. This makes things easier as it is no longer necessary to manually compute the arc's initial coordinates for a call to :meth:`Context.move_to`. .. versionadded:: 1.6 """ def paint(self) -> None: """ A drawing operator that paints the current source everywhere within the current clip region. """ def paint_with_alpha(self, alpha: float) -> None: """ :param alpha: alpha value, between 0 (transparent) and 1 (opaque) A drawing operator that paints the current source everywhere within the current clip region using a mask of constant alpha value *alpha*. The effect is similar to :meth:`Context.paint`, but the drawing is faded out using the alpha value. """ def path_extents(self) -> Tuple[float, float, float, float]: """ :returns: (x1, y1, x2, y2), all float * *x1*: left of the resulting extents * *y1*: top of the resulting extents * *x2*: right of the resulting extents * *y2*: bottom of the resulting extents Computes a bounding box in user-space coordinates covering the points on the current path. If the current path is empty, returns an empty rectangle (0, 0, 0, 0). Stroke parameters, fill rule, surface dimensions and clipping are not taken into account. Contrast with :meth:`Context.fill_extents` and :meth:`Context.stroke_extents` which return the extents of only the area that would be "inked" by the corresponding drawing operations. The result of :meth:`.path_extents` is defined as equivalent to the limit of :meth:`Context.stroke_extents` with cairo.LINE_CAP_ROUND as the line width approaches 0.0, (but never reaching the empty-rectangle returned by :meth:`Context.stroke_extents` for a line width of 0.0). Specifically, this means that zero-area sub-paths such as :meth:`Context.move_to`; :meth:`Context.line_to` segments, (even degenerate cases where the coordinates to both calls are identical), will be considered as contributing to the extents. However, a lone :meth:`Context.move_to` will not contribute to the results of :meth:`Context.path_extents`. .. versionadded:: 1.6 """ def pop_group(self) -> SurfacePattern: """ :returns: a newly created :class:`SurfacePattern` containing the results of all drawing operations performed to the group. Terminates the redirection begun by a call to :meth:`Context.push_group` or :meth:`Context.push_group_with_content` and returns a new pattern containing the results of all drawing operations performed to the group. The :meth:`.pop_group` function calls :meth:`Context.restore`, (balancing a call to :meth:`Context.save` by the :meth:`Context.push_group` function), so that any changes to the graphics state will not be visible outside the group. .. versionadded:: 1.2 """ def pop_group_to_source(self) -> None: """ Terminates the redirection begun by a call to :meth:`Context.push_group` or :meth:`Context.push_group_with_content` and installs the resulting pattern as the source :class:`Pattern` in the given :class:`Context`. The behavior of this function is equivalent to the sequence of operations:: group = cairo_pop_group() ctx.set_source(group) but is more convenient as their is no need for a variable to store the short-lived pointer to the pattern. The :meth:`Context.pop_group` function calls :meth:`Context.restore`, (balancing a call to :meth:`Context.save` by the :meth:`Context.push_group` function), so that any changes to the graphics state will not be visible outside the group. .. versionadded:: 1.2 """ def push_group(self) -> None: """ Temporarily redirects drawing to an intermediate surface known as a group. The redirection lasts until the group is completed by a call to :meth:`Context.pop_group` or :meth:`Context.pop_group_to_source`. These calls provide the result of any drawing to the group as a pattern, (either as an explicit object, or set as the source pattern). This group functionality can be convenient for performing intermediate compositing. One common use of a group is to render objects as opaque within the group, (so that they occlude each other), and then blend the result with translucence onto the destination. Groups can be nested arbitrarily deep by making balanced calls to :meth:`Context.push_group`/:meth:`Context.pop_group`. Each call pushes/pops the new target group onto/from a stack. The :meth:`.push_group` function calls :meth:`Context.save` so that any changes to the graphics state will not be visible outside the group, (the pop_group functions call :meth:`Context.restore`). By default the intermediate group will have a :class:`cairo.Content` type of :attr:`cairo.Content.COLOR_ALPHA`. Other content types can be chosen for the group by using :meth:`Context.push_group_with_content` instead. As an example, here is how one might fill and stroke a path with translucence, but without any portion of the fill being visible under the stroke:: ctx.push_group() ctx.set_source(fill_pattern) ctx.fill_preserve() ctx.set_source(stroke_pattern) ctx.stroke() ctx.pop_group_to_source() ctx.paint_with_alpha(alpha) .. versionadded:: 1.2 """ def push_group_with_content(self, content: Content) -> None: """ :param cairo.Content content: a content indicating the type of group that will be created Temporarily redirects drawing to an intermediate surface known as a group. The redirection lasts until the group is completed by a call to :meth:`Context.pop_group` or :meth:`Context.pop_group_to_source`. These calls provide the result of any drawing to the group as a pattern, (either as an explicit object, or set as the source pattern). The group will have a content type of *content*. The ability to control this content type is the only distinction between this function and :meth:`Context.push_group` which you should see for a more detailed description of group rendering. .. versionadded:: 1.2 """ def rectangle(self, x: float, y: float, width: float, height: float) -> None: """ :param x: the X coordinate of the top left corner of the rectangle :param y: the Y coordinate to the top left corner of the rectangle :param width: the width of the rectangle :param height: the height of the rectangle Adds a closed sub-path rectangle of the given size to the current path at position *(x, y)* in user-space coordinates. This function is logically equivalent to:: ctx.move_to(x, y) ctx.rel_line_to(width, 0) ctx.rel_line_to(0, height) ctx.rel_line_to(-width, 0) ctx.close_path() """ def rel_curve_to(self, dx1: float, dy1: float, dx2: float, dy2: float, dx3: float, dy3: float) -> None: """ :param dx1: the X offset to the first control point :param dy1: the Y offset to the first control point :param dx2: the X offset to the second control point :param dy2: the Y offset to the second control point :param dx3: the X offset to the end of the curve :param dy3: the Y offset to the end of the curve :raises: :exc:`cairo.Error` if called with no current point. Relative-coordinate version of :meth:`Context.curve_to`. All offsets are relative to the current point. Adds a cubic Bézier spline to the path from the current point to a point offset from the current point by *(dx3, dy3)*, using points offset by *(dx1, dy1)* and *(dx2, dy2)* as the control points. After this call the current point will be offset by *(dx3, dy3)*. Given a current point of (x, y), ``ctx.rel_curve_to(dx1, dy1, dx2, dy2, dx3, dy3)`` is logically equivalent to ``ctx.curve_to(x+dx1, y+dy1, x+dx2, y+dy2, x+dx3, y+dy3)``. """ def rel_line_to(self, dx: float, dy: float) -> None: """ :param dx: the X offset to the end of the new line :param dy: the Y offset to the end of the new line :raises: :exc:`cairo.Error` if called with no current point. Relative-coordinate version of :meth:`Context.line_to`. Adds a line to the path from the current point to a point that is offset from the current point by *(dx, dy)* in user space. After this call the current point will be offset by *(dx, dy)*. Given a current point of (x, y), ``ctx.rel_line_to(dx, dy)`` is logically equivalent to ``ctx.line_to(x + dx, y + dy)``. """ def rel_move_to(self, dx: float, dy: float) -> None: """ :param dx: the X offset :param dy: the Y offset :raises: :exc:`cairo.Error` if called with no current point. Begin a new sub-path. After this call the current point will offset by *(dx, dy)*. Given a current point of (x, y), ``ctx.rel_move_to(dx, dy)`` is logically equivalent to ``ctx.(x + dx, y + dy)``. """ def reset_clip(self) -> None: """ Reset the current clip region to its original, unrestricted state. That is, set the clip region to an infinitely large shape containing the target surface. Equivalently, if infinity is too hard to grasp, one can imagine the clip region being reset to the exact bounds of the target surface. Note that code meant to be reusable should not call :meth:`.reset_clip` as it will cause results unexpected by higher-level code which calls :meth:`.clip`. Consider using :meth:`.save` and :meth:`.restore` around :meth:`.clip` as a more robust means of temporarily restricting the clip region. """ def restore(self) -> None: """ Restores :class:`Context` to the state saved by a preceding call to :meth:`.save` and removes that state from the stack of saved states. """ def rotate(self, angle: float) -> None: """ :param angle: angle (in radians) by which the user-space axes will be rotated Modifies the current transformation matrix (CTM) by rotating the user-space axes by *angle* radians. The rotation of the axes takes places after any existing transformation of user space. The rotation direction for positive angles is from the positive X axis toward the positive Y axis. """ def save(self) -> None: """ Makes a copy of the current state of :class:`Context` and saves it on an internal stack of saved states. When :meth:`.restore` is called, :class:`Context` will be restored to the saved state. Multiple calls to :meth:`.save` and :meth:`.restore` can be nested; each call to :meth:`.restore` restores the state from the matching paired :meth:`.save`. """ def scale(self, sx: float, sy: float) -> None: """ :param sx: scale factor for the X dimension :param sy: scale factor for the Y dimension Modifies the current transformation matrix (CTM) by scaling the X and Y user-space axes by *sx* and *sy* respectively. The scaling of the axes takes place after any existing transformation of user space. """ def select_font_face(self, family: str, slant: FontSlant = FontSlant.NORMAL, weight: FontWeight = FontWeight.NORMAL) -> None: """ :param family: a font family name :param slant: the font slant of the font, defaults to :attr:`cairo.FontSlant.NORMAL`. :param weight: the font weight of the font, defaults to :attr:`cairo.FontWeight.NORMAL`. Note: The :meth:`.select_font_face` function call is part of what the cairo designers call the "toy" text API. It is convenient for short demos and simple programs, but it is not expected to be adequate for serious text-using applications. Selects a family and style of font from a simplified description as a family name, slant and weight. Cairo provides no operation to list available family names on the system (this is a "toy", remember), but the standard CSS2 generic family names, ("serif", "sans-serif", "cursive", "fantasy", "monospace"), are likely to work as expected. For "real" font selection, see the font-backend-specific font_face_create functions for the font backend you are using. (For example, if you are using the freetype-based cairo-ft font backend, see cairo_ft_font_face_create_for_ft_face() or cairo_ft_font_face_create_for_pattern().) The resulting font face could then be used with cairo_scaled_font_create() and cairo_set_scaled_font(). Similarly, when using the "real" font support, you can call directly into the underlying font system, (such as fontconfig or freetype), for operations such as listing available fonts, etc. It is expected that most applications will need to use a more comprehensive font handling and text layout library, (for example, pango), in conjunction with cairo. If text is drawn without a call to :meth:`.select_font_face`, (nor :meth:`.set_font_face` nor :meth:`.set_scaled_font`), the default family is platform-specific, but is essentially "sans-serif". Default slant is :attr:`cairo.FontSlant.NORMAL`, and default weight is :attr:`cairo.FontWeight.NORMAL`. This function is equivalent to a call to :class:`ToyFontFace` followed by :meth:`.set_font_face`. """ def set_antialias(self, antialias: Antialias) -> None: """ :param antialias: the new antialias mode Set the antialiasing mode of the rasterizer used for drawing shapes. This value is a hint, and a particular backend may or may not support a particular value. At the current time, no backend supports :attr:`cairo.Antialias.SUBPIXEL` when drawing shapes. Note that this option does not affect text rendering, instead see :meth:`FontOptions.set_antialias`. """ def set_dash(self, dashes: Sequence[float], offset: float = 0) -> None: """ :param dashes: a sequence specifying alternate lengths of on and off stroke portions as float. :param offset: an offset into the dash pattern at which the stroke should start, defaults to 0. :raises: :exc:`cairo.Error` if any value in *dashes* is negative, or if all values are 0. Sets the dash pattern to be used by :meth:`.stroke`. A dash pattern is specified by *dashes* - a sequence of positive values. Each value provides the length of alternate "on" and "off" portions of the stroke. The *offset* specifies an offset into the pattern at which the stroke begins. Each "on" segment will have caps applied as if the segment were a separate sub-path. In particular, it is valid to use an "on" length of 0.0 with :attr:`cairo.LineCap.ROUND` or :attr:`cairo.LineCap.SQUARE` in order to distributed dots or squares along a path. Note: The length values are in user-space units as evaluated at the time of stroking. This is not necessarily the same as the user space at the time of :meth:`.set_dash`. If the number of dashes is 0 dashing is disabled. If the number of dashes is 1 a symmetric pattern is assumed with alternating on and off portions of the size specified by the single value in *dashes*. """ def set_fill_rule(self, fill_rule: FillRule) -> None: """ :param fill_rule: a fill rule to set the within the cairo context. The fill rule is used to determine which regions are inside or outside a complex (potentially self-intersecting) path. The current fill rule affects both :meth:`.fill` and :meth:`.clip`. The default fill rule is :attr:`cairo.FillRule.WINDING`. """ def set_font_face(self, font_face: Optional[FontFace]) -> None: """ :param font_face: a :class:`FontFace`, or None to restore to the default :class:`FontFace` Replaces the current :class:`FontFace` object in the :class:`Context` with *font_face*. """ def set_font_matrix(self, matrix: Matrix) -> None: """ :param matrix: a :class:`Matrix` describing a transform to be applied to the current font. Sets the current font matrix to *matrix*. The font matrix gives a transformation from the design space of the font (in this space, the em-square is 1 unit by 1 unit) to user space. Normally, a simple scale is used (see :meth:`.set_font_size`), but a more complex font matrix can be used to shear the font or stretch it unequally along the two axes """ def set_font_options(self, options: FontOptions) -> None: """ :param options: :class:`FontOptions` to use Sets a set of custom font rendering options for the :class:`Context`. Rendering options are derived by merging these options with the options derived from underlying surface; if the value in *options* has a default value (like :attr:`cairo.Antialias.DEFAULT`), then the value from the surface is used. """ def set_font_size(self, size: float) -> None: """ :param size: the new font size, in user space units Sets the current font matrix to a scale by a factor of *size*, replacing any font matrix previously set with :meth:`.set_font_size` or :meth:`.set_font_matrix`. This results in a font size of *size* user space units. (More precisely, this matrix will result in the font's em-square being a *size* by *size* square in user space.) If text is drawn without a call to :meth:`.set_font_size`, (nor :meth:`.set_font_matrix` nor :meth:`.set_scaled_font`), the default font size is 10.0. """ def set_hairline(self, set_hairline: bool) -> None: """ :param set_hairline: whether or not to set hairline mode Sets lines within the cairo context to be hairlines. Hairlines are logically zero-width lines that are drawn at the thinnest renderable width possible in the current context. On surfaces with native hairline support, the native hairline functionality will be used. Surfaces that support hairlines include: - pdf/ps: Encoded as 0-width line. - win32_printing: Rendered with PS_COSMETIC pen. - svg: Encoded as 1px non-scaling-stroke. - script: Encoded with set-hairline function. Cairo will always render hairlines at 1 device unit wide, even if an anisotropic scaling was applied to the stroke width. In the wild, handling of this situation is not well-defined. Some PDF, PS, and SVG renderers match Cairo's output, but some very popular implementations (Acrobat, Chrome, rsvg) will scale the hairline unevenly. As such, best practice is to reset any anisotropic scaling before calling :meth:`.stroke`. See https://cairographics.org/cookbook/ellipses/ for an example. .. versionadded:: 1.23 Only available with cairo 1.17.6+ """ def set_line_cap(self, line_cap: LineCap) -> None: """ :param line_cap: a line cap style Sets the current line cap style within the :class:`Context`. As with the other stroke parameters, the current line cap style is examined by :meth:`.stroke` and :meth:`.stroke_extents`, but does not have any effect during path construction. The default line cap style is :attr:`cairo.LineCap.BUTT`. """ def set_line_join(self, line_join: LineJoin) -> None: """ :param line_join: a line join style Sets the current line join style within the :class:`Context`. As with the other stroke parameters, the current line join style is examined by :meth:`.stroke` and :meth:`.stroke_extents`, but does not have any effect during path construction. The default line join style is :attr:`cairo.LineJoin.MITER`. """ def set_line_width(self, width: float) -> None: """ :param width: a line width Sets the current line width within the :class:`Context`. The line width value specifies the diameter of a pen that is circular in user space, (though device-space pen may be an ellipse in general due to scaling/shear/rotation of the CTM). Note: When the description above refers to user space and CTM it refers to the user space and CTM in effect at the time of the stroking operation, not the user space and CTM in effect at the time of the call to :meth:`.set_line_width`. The simplest usage makes both of these spaces identical. That is, if there is no change to the CTM between a call to :meth:`.set_line_width` and the stroking operation, then one can just pass user-space values to :meth:`.set_line_width` and ignore this note. As with the other stroke parameters, the current line width is examined by :meth:`.stroke` and :meth:`.stroke_extents`, but does not have any effect during path construction. The default line width value is 2.0. """ def set_matrix(self, matrix: Matrix) -> None: """ :param matrix: a transformation :class:`Matrix` from user space to device space. Modifies the current transformation matrix (CTM) by setting it equal to *matrix*. """ def set_miter_limit(self, limit: float) -> None: """ :param limit: miter limit to set Sets the current miter limit within the :class:`Context`. If the current line join style is set to :attr:`cairo.LineJoin.MITER` (see :meth:`.set_line_join`), the miter limit is used to determine whether the lines should be joined with a bevel instead of a miter. Cairo divides the length of the miter by the line width. If the result is greater than the miter limit, the style is converted to a bevel. As with the other stroke parameters, the current line miter limit is examined by :meth:`.stroke` and :meth:`.stroke_extents`, but does not have any effect during path construction. The default miter limit value is 10.0, which will convert joins with interior angles less than 11 degrees to bevels instead of miters. For reference, a miter limit of 2.0 makes the miter cutoff at 60 degrees, and a miter limit of 1.414 makes the cutoff at 90 degrees. A miter limit for a desired angle can be computed as:: miter limit = 1/math.sin(angle/2) """ def set_operator(self, op: Operator) -> None: """ :param op: the compositing operator to set for use in all drawing operations. The default operator is :attr:`cairo.Operator.OVER`. """ def set_scaled_font(self, scaled_font: ScaledFont) -> None: """ :param scaled_font: a :class:`ScaledFont` Replaces the current font face, font matrix, and font options in the :class:`Context` with those of the :class:`ScaledFont`. Except for some translation, the current CTM of the :class:`Context` should be the same as that of the :class:`ScaledFont`, which can be accessed using :meth:`ScaledFont.get_ctm`. .. versionadded:: 1.2 """ def set_source(self, source: Pattern) -> None: """ :param source: a :class:`Pattern` to be used as the source for subsequent drawing operations. Sets the source pattern within :class:`Context` to *source*. This pattern will then be used for any subsequent drawing operation until a new source pattern is set. Note: The pattern's transformation matrix will be locked to the user space in effect at the time of :meth:`.set_source`. This means that further modifications of the current transformation matrix will not affect the source pattern. See :meth:`Pattern.set_matrix`. The default source pattern is a solid pattern that is opaque black, (that is, it is equivalent to ``set_source_rgb(0.0, 0.0, 0.0)``. """ def set_source_rgb(self, red: float, green: float, blue: float) -> None: """ :param red: red component of color :param green: green component of color :param blue: blue component of color Sets the source pattern within :class:`Context` to an opaque color. This opaque color will then be used for any subsequent drawing operation until a new source pattern is set. The color components are floating point numbers in the range 0 to 1. If the values passed in are outside that range, they will be clamped. The default source pattern is opaque black, (that is, it is equivalent to ``set_source_rgb(0.0, 0.0, 0.0)``. """ def set_source_rgba(self, red: float, green: float, blue: float, alpha: float = 1.0) -> None: """ :param red: red component of color :param green: green component of color :param blue: blue component of color :param alpha: alpha component of color Sets the source pattern within :class:`Context` to a translucent color. This color will then be used for any subsequent drawing operation until a new source pattern is set. The color and alpha components are floating point numbers in the range 0 to 1. If the values passed in are outside that range, they will be clamped. The default source pattern is opaque black, (that is, it is equivalent to ``set_source_rgba(0.0, 0.0, 0.0, 1.0)``. """ def set_source_surface(self, surface: Surface, x: float = 0.0, y: float = 0.0) -> None: """ :param surface: a :class:`Surface` to be used to set the source pattern :param x: User-space X coordinate for surface origin :param y: User-space Y coordinate for surface origin This is a convenience function for creating a pattern from a :class:`Surface` and setting it as the source in :class:`Context` with :meth:`.set_source`. The *x* and *y* parameters give the user-space coordinate at which the surface origin should appear. (The surface origin is its upper-left corner before any transformation has been applied.) The *x* and *y* patterns are negated and then set as translation values in the pattern matrix. Other than the initial translation pattern matrix, as described above, all other pattern attributes, (such as its extend mode), are set to the default values as in :class:`SurfacePattern`. The resulting pattern can be queried with :meth:`.get_source` so that these attributes can be modified if desired, (eg. to create a repeating pattern with :meth:`.Pattern.set_extend`). """ def set_tolerance(self, tolerance: float) -> None: """ :param tolerance: the tolerance, in device units (typically pixels) Sets the tolerance used when converting paths into trapezoids. Curved segments of the path will be subdivided until the maximum deviation between the original path and the polygonal approximation is less than *tolerance*. The default value is 0.1. A larger value will give better performance, a smaller value, better appearance. (Reducing the value from the default value of 0.1 is unlikely to improve appearance significantly.) The accuracy of paths within Cairo is limited by the precision of its internal arithmetic, and the prescribed *tolerance* is restricted to the smallest representable internal value. """ def show_glyphs(self, glyphs: Sequence[Glyph]) -> None: """ :param glyphs: glyphs to show as a sequence of :class:`Glyph` A drawing operator that generates the shape from an array of glyphs, rendered according to the current font face, font size (font matrix), and font options. """ def show_page(self) -> None: """ Emits and clears the current page for backends that support multiple pages. Use :meth:`.copy_page` if you don't want to clear the page. This is a convenience function that simply calls ``ctx.get_target() . show_page()`` """ def show_text(self, text: str) -> None: """ :param text: text A drawing operator that generates the shape from a string of text, rendered according to the current font_face, font_size (font_matrix), and font_options. This function first computes a set of glyphs for the string of text. The first glyph is placed so that its origin is at the current point. The origin of each subsequent glyph is offset from that of the previous glyph by the advance values of the previous glyph. After this call the current point is moved to the origin of where the next glyph would be placed in this same progression. That is, the current point will be at the origin of the final glyph offset by its advance values. This allows for easy display of a single logical string with multiple calls to :meth:`.show_text`. Note: The :meth:`.show_text` function call is part of what the cairo designers call the "toy" text API. It is convenient for short demos and simple programs, but it is not expected to be adequate for serious text-using applications. See :meth:`.show_glyphs` for the "real" text display API in cairo. """ def show_text_glyphs(self, utf8: str, glyphs: List["Glyph"], clusters: List[TextCluster], cluster_flags: TextClusterFlags) -> None: """ :param utf8: a string of text :param glyphs: list of glyphs to show :param clusters: list of cluster mapping information :param cluster_flags: cluster mapping flags :raises Error: .. versionadded:: 1.15 This operation has rendering effects similar to :meth:`Context.show_glyphs` but, if the target surface supports it, uses the provided text and cluster mapping to embed the text for the glyphs shown in the output. If the target does not support the extended attributes, this function acts like the basic :meth:`Context.show_glyphs` as if it had been passed ``glyphs`` . The mapping between utf8 and glyphs is provided by a list of clusters. Each cluster covers a number of text bytes and glyphs, and neighboring clusters cover neighboring areas of utf8 and glyphs . The clusters should collectively cover utf8 and glyphs in entirety. The first cluster always covers bytes from the beginning of utf8 . If ``cluster_flags`` do not have the :attr:`TextClusterFlags.BACKWARD` set, the first cluster also covers the beginning of glyphs , otherwise it covers the end of the glyphs array and following clusters move backward. See :class:`TextCluster` for constraints on valid clusters. """ def stroke(self) -> None: """ A drawing operator that strokes the current path according to the current line width, line join, line cap, and dash settings. After :meth:`.stroke`, the current path will be cleared from the cairo context. See :meth:`.set_line_width`, :meth:`.set_line_join`, :meth:`.set_line_cap`, :meth:`.set_dash`, and :meth:`.stroke_preserve`. Note: Degenerate segments and sub-paths are treated specially and provide a useful result. These can result in two different situations: 1. Zero-length "on" segments set in :meth:`.set_dash`. If the cap style is :attr:`cairo.LineCap.ROUND` or :attr:`cairo.LineCap.SQUARE` then these segments will be drawn as circular dots or squares respectively. In the case of :attr:`cairo.LineCap.SQUARE`, the orientation of the squares is determined by the direction of the underlying path. 2. A sub-path created by :meth:`.move_to` followed by either a :meth:`.close_path` or one or more calls to :meth:`.line_to` to the same coordinate as the :meth:`.move_to`. If the cap style is :attr:`cairo.LineCap.ROUND` then these sub-paths will be drawn as circular dots. Note that in the case of :attr:`cairo.LineCap.SQUARE` a degenerate sub-path will not be drawn at all, (since the correct orientation is indeterminate). In no case will a cap style of :attr:`cairo.LineCap.BUTT` cause anything to be drawn in the case of either degenerate segments or sub-paths. """ def stroke_extents(self) -> Tuple[float, float, float, float]: """ :returns: (x1, y1, x2, y2), all float * *x1*: left of the resulting extents * *y1*: top of the resulting extents * *x2*: right of the resulting extents * *y2*: bottom of the resulting extents Computes a bounding box in user coordinates covering the area that would be affected, (the "inked" area), by a :meth:`.stroke` operation given the current path and stroke parameters. If the current path is empty, returns an empty rectangle (0, 0, 0, 0). Surface dimensions and clipping are not taken into account. Note that if the line width is set to exactly zero, then :meth:`.stroke_extents` will return an empty rectangle. Contrast with :meth:`.path_extents` which can be used to compute the non-empty bounds as the line width approaches zero. Note that :meth:`.stroke_extents` must necessarily do more work to compute the precise inked areas in light of the stroke parameters, so :meth:`.path_extents` may be more desirable for sake of performance if non-inked path extents are desired. See :meth:`.stroke`, :meth:`.set_line_width`, :meth:`.set_line_join`, :meth:`.set_line_cap`, :meth:`.set_dash`, and :meth:`.stroke_preserve`. """ def stroke_preserve(self) -> None: """ A drawing operator that strokes the current path according to the current line width, line join, line cap, and dash settings. Unlike :meth:`.stroke`, :meth:`.stroke_preserve` preserves the path within the cairo context. See :meth:`.set_line_width`, :meth:`.set_line_join`, :meth:`.set_line_cap`, :meth:`.set_dash`, and :meth:`.stroke_preserve`. """ def tag_begin(self, tag_name: str, attributes: str) -> None: """ :param tag_name: tag name :param attributes: tag attributes Marks the beginning of the tag_name structure. Call :meth:`tag_end` with the same tag_name to mark the end of the structure. The attributes string is of the form "key1=value2 key2=value2 ...". Values may be boolean (true/false or 1/0), integer, float, string, or an array. String values are enclosed in single quotes ('). Single quotes and backslashes inside the string should be escaped with a backslash. Boolean values may be set to true by only specifying the key. eg the attribute string "key" is the equivalent to "key=true". Arrays are enclosed in '[]'. eg "rect=[1.2 4.3 2.0 3.0]". If no attributes are required, attributes can be an empty string. See `Tags and Links Description <https://www.cairographics.org/manual/cairo-Tags-and-Links.html#cairo-Tags-and-Links.description>`__ for the list of tags and attributes. Invalid nesting of tags or invalid attributes will cause the context to shutdown with a status of :attr:`Status.TAG_ERROR`. See :meth:`tag_end`. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def tag_end(self, tag_name: str) -> None: """ :param tag_name: tag name Marks the end of the tag_name structure. Invalid nesting of tags will cause the context to shutdown with a status of :attr:`Status.TAG_ERROR`. See :meth:`tag_begin`. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def text_extents(self, text: str) -> TextExtents: """ :param text: text to get extents for Gets the extents for a string of text. The extents describe a user-space rectangle that encloses the "inked" portion of the text, (as it would be drawn by :meth:`Context.show_text`). Additionally, the x_advance and y_advance values indicate the amount by which the current point would be advanced by :meth:`Context.show_text`. Note that whitespace characters do not directly contribute to the size of the rectangle (extents.width and extents.height). They do contribute indirectly by changing the position of non-whitespace characters. In particular, trailing whitespace characters are likely to not affect the size of the rectangle, though they will affect the x_advance and y_advance values. """ def text_path(self, text: str) -> None: """ :param text: text Adds closed paths for text to the current path. The generated path if filled, achieves an effect similar to that of :meth:`Context.show_text`. Text conversion and positioning is done similar to :meth:`Context.show_text`. Like :meth:`Context.show_text`, After this call the current point is moved to the origin of where the next glyph would be placed in this same progression. That is, the current point will be at the origin of the final glyph offset by its advance values. This allows for chaining multiple calls to to :meth:`Context.text_path` without having to set current point in between. Note: The :meth:`.text_path` function call is part of what the cairo designers call the "toy" text API. It is convenient for short demos and simple programs, but it is not expected to be adequate for serious text-using applications. See :meth:`Context.glyph_path` for the "real" text path API in cairo. """ def transform(self, matrix: Matrix) -> None: """ :param matrix: a transformation :class:`Matrix` to be applied to the user-space axes Modifies the current transformation matrix (CTM) by applying *matrix* as an additional transformation. The new transformation of user space takes place after any existing transformation. """ def translate(self, tx: float, ty: float) -> None: """ :param tx: amount to translate in the X direction :param ty: amount to translate in the Y direction Modifies the current transformation matrix (CTM) by translating the user-space origin by *(tx, ty)*. This offset is interpreted as a user-space coordinate according to the CTM in place before the new call to :meth:`.translate`. In other words, the translation of the user-space origin takes place after any existing transformation. """ def user_to_device(self, x: float, y: float) -> Tuple[float, float]: """ :param x: X value of coordinate :param y: Y value of coordinate :returns: (x, y), both float * *x*: X value of coordinate * *y*: Y value of coordinate Transform a coordinate from user space to device space by multiplying the given point by the current transformation matrix (CTM). """ def user_to_device_distance(self, dx: float, dy: float) -> Tuple[float, float]: """ :param dx: X value of a distance vector :param dy: Y value of a distance vector :returns: (dx, dy), both float * *dx*: X value of a distance vector * *dy*: Y value of a distance vector Transform a distance vector from user space to device space. This function is similar to :meth:`Context.user_to_device` except that the translation components of the CTM will be ignored when transforming *(dx,dy)*. """ class Error(Exception): """This exception is raised when a cairo object returns an error status.""" status: Status = ... CairoError = Error """ An alias for :exc:`Error` .. versionadded:: 1.12.0 """ class Gradient(Pattern): """ *Gradient* is an abstract base class from which other *Pattern* classes derive. It cannot be instantiated directly. """ def add_color_stop_rgb(self, offset: float, red: float, green: float, blue: float) -> None: """ :param offset: an offset in the range [0.0 .. 1.0] :param red: red component of color :param green: green component of color :param blue: blue component of color Adds an opaque color stop to a *Gradient* pattern. The offset specifies the location along the gradient's control vector. For example, a *LinearGradient's* control vector is from (x0,y0) to (x1,y1) while a *RadialGradient's* control vector is from any point on the start circle to the corresponding point on the end circle. The color is specified in the same way as in :meth:`Context.set_source_rgb`. If two (or more) stops are specified with identical offset values, they will be sorted according to the order in which the stops are added, (stops added earlier will compare less than stops added later). This can be useful for reliably making sharp color transitions instead of the typical blend. """ def add_color_stop_rgba(self, offset: float, red: float, green: float, blue: float, alpha: float) -> None: """ :param offset: an offset in the range [0.0 .. 1.0] :param red: red component of color :param green: green component of color :param blue: blue component of color :param alpha: alpha component of color Adds an opaque color stop to a *Gradient* pattern. The offset specifies the location along the gradient's control vector. For example, a *LinearGradient's* control vector is from (x0,y0) to (x1,y1) while a *RadialGradient's* control vector is from any point on the start circle to the corresponding point on the end circle. The color is specified in the same way as in :meth:`Context.set_source_rgb`. If two (or more) stops are specified with identical offset values, they will be sorted according to the order in which the stops are added, (stops added earlier will compare less than stops added later). This can be useful for reliably making sharp color transitions instead of the typical blend. """ def get_color_stops_rgba(self) -> List[Tuple[float, float, float, float, float]]: """ :returns: a list of (offset, red, green, blue, alpha) tuples of float Gets the color and offset information for all color stops specified in the given gradient pattern. .. versionadded:: 1.14 """ class LinearGradient(Gradient): def __init__(self, x0: float, y0: float, x1: float, y1: float) -> None: """ :param x0: x coordinate of the start point :param y0: y coordinate of the start point :param x1: x coordinate of the end point :param y1: y coordinate of the end point Create a new *LinearGradient* along the line defined by (x0, y0) and (x1, y1). Before using the *Gradient* pattern, a number of color stops should be defined using :meth:`Gradient.add_color_stop_rgb` or :meth:`Gradient.add_color_stop_rgba` Note: The coordinates here are in pattern space. For a new *Pattern*, pattern space is identical to user space, but the relationship between the spaces can be changed with :meth:`Pattern.set_matrix` """ def get_linear_points(self) -> Tuple[float, float, float, float]: """ :returns: (x0, y0, x1, y1) - a tuple of float * x0: return value for the x coordinate of the first point * y0: return value for the y coordinate of the first point * x1: return value for the x coordinate of the second point * y1: return value for the y coordinate of the second point Gets the gradient endpoints for a *LinearGradient*. .. versionadded:: 1.4 """ class MeshPattern(Pattern): """ Mesh patterns are tensor-product patch meshes (type 7 shadings in PDF). Mesh patterns may also be used to create other types of shadings that are special cases of tensor-product patch meshes such as Coons patch meshes (type 6 shading in PDF) and Gouraud-shaded triangle meshes (type 4 and 5 shadings in PDF). Mesh patterns consist of one or more tensor-product patches, which should be defined before using the mesh pattern. Using a mesh pattern with a partially defined patch as source or mask will put the context in an error status with a status of :attr:`cairo.Status.INVALID_MESH_CONSTRUCTION`. A tensor-product patch is defined by 4 Bézier curves (side 0, 1, 2, 3) and by 4 additional control points (P0, P1, P2, P3) that provide further control over the patch and complete the definition of the tensor-product patch. The corner C0 is the first point of the patch. Degenerate sides are permitted so straight lines may be used. A zero length line on one side may be used to create 3 sided patches. :: C1 Side 1 C2 +---------------+ | | | P1 P2 | | | Side 0 | | Side 2 | | | | | P0 P3 | | | +---------------+ C0 Side 3 C3 Each patch is constructed by first calling :meth:`begin_patch`, then :meth:`move_to` to specify the first point in the patch (C0). Then the sides are specified with calls to :meth:`curve_to` and :meth:`line_to`. The four additional control points (P0, P1, P2, P3) in a patch can be specified with :meth:`set_control_point`. At each corner of the patch (C0, C1, C2, C3) a color may be specified with :meth:`set_corner_color_rgb` or :meth:`set_corner_color_rgba`. Any corner whose color is not explicitly specified defaults to transparent black. A Coons patch is a special case of the tensor-product patch where the control points are implicitly defined by the sides of the patch. The default value for any control point not specified is the implicit value for a Coons patch, i.e. if no control points are specified the patch is a Coons patch. A triangle is a special case of the tensor-product patch where the control points are implicitly defined by the sides of the patch, all the sides are lines and one of them has length 0, i.e. if the patch is specified using just 3 lines, it is a triangle. If the corners connected by the 0-length side have the same color, the patch is a Gouraud-shaded triangle. Patches may be oriented differently to the above diagram. For example the first point could be at the top left. The diagram only shows the relationship between the sides, corners and control points. Regardless of where the first point is located, when specifying colors, corner 0 will always be the first point, corner 1 the point between side 0 and side 1 etc. Calling :meth:`end_patch` completes the current patch. If less than 4 sides have been defined, the first missing side is defined as a line from the current point to the first point of the patch (C0) and the other sides are degenerate lines from C0 to C0. The corners between the added sides will all be coincident with C0 of the patch and their color will be set to be the same as the color of C0. Additional patches may be added with additional calls to :meth:`begin_patch`/:meth:`end_patch`. :: # Add a Coons patch pattern = cairo.MeshPattern() pattern.begin_patch() pattern.move_to(0, 0) pattern.curve_to(30, -30, 60, 30, 100, 0) pattern.curve_to(60, 30, 130, 60, 100, 100) pattern.curve_to(60, 70, 30, 130, 0, 100) pattern.curve_to(30, 70, -30, 30, 0, 0) pattern.set_corner_color_rgb(0, 1, 0, 0) pattern.set_corner_color_rgb(1, 0, 1, 0) pattern.set_corner_color_rgb(2, 0, 0, 1) pattern.set_corner_color_rgb(3, 1, 1, 0) pattern.end_patch() # Add a Gouraud-shaded triangle pattern = cairo.MeshPattern() pattern.begin_patch() pattern.move_to(100, 100) pattern.line_to(130, 130) pattern.line_to(130, 70) pattern.set_corner_color_rgb(0, 1, 0, 0) pattern.set_corner_color_rgb(1, 0, 1, 0) pattern.set_corner_color_rgb(2, 0, 0, 1) pattern.end_patch() When two patches overlap, the last one that has been added is drawn over the first one. When a patch folds over itself, points are sorted depending on their parameter coordinates inside the patch. The v coordinate ranges from 0 to 1 when moving from side 3 to side 1; the u coordinate ranges from 0 to 1 when going from side 0 to side Points with higher v coordinate hide points with lower v coordinate. When two points have the same v coordinate, the one with higher u coordinate is above. This means that points nearer to side 1 are above points nearer to side 3; when this is not sufficient to decide which point is above (for example when both points belong to side 1 or side 3) points nearer to side 2 are above points nearer to side 0. For a complete definition of tensor-product patches, see the PDF specification (ISO32000), which describes the parametrization in detail. Note: The coordinates are always in pattern space. For a new pattern, pattern space is identical to user space, but the relationship between the spaces can be changed with :meth:`Pattern.set_matrix`. .. versionadded:: 1.14 """ def __init__(self) -> None: """ Create a new mesh pattern. .. versionadded:: 1.14 """ def begin_patch(self) -> None: """ :raises Error: Begin a patch in a mesh pattern. After calling this function, the patch shape should be defined with :meth:`move_to`, :meth:`line_to` and :meth:`curve_to`. After defining the patch, :meth:`end_patch` must be called before using pattern as a source or mask. """ def curve_to(self, x1: float, y1: float, x2: float, y2: float, x3: float, y3: float) -> None: """ :param x1: the X coordinate of the first control point :param y1: the Y coordinate of the first control point :param x2: the X coordinate of the second control point :param y2: the Y coordinate of the second control point :param x3: the X coordinate of the end of the curve :param y3: the Y coordinate of the end of the curve :raises Error: Adds a cubic Bézier spline to the current patch from the current point to position (x3 , y3 ) in pattern-space coordinates, using (x1 , y1 ) and (x2 , y2 ) as the control points. If the current patch has no current point before the call to :meth:`curve_to`, this function will behave as if preceded by a call to ``pattern.move_to(x1, y1)``. After this call the current point will be (x3 , y3 ). """ def end_patch(self) -> None: """ :raises Error: Indicates the end of the current patch in a mesh pattern. If the current patch has less than 4 sides, it is closed with a straight line from the current point to the first point of the patch as if :meth:`line_to` was used. """ def get_control_point(self, patch_num: int, point_num: int) -> Tuple[float, float]: """ :param patch_num: the patch number to return data for :param point_num: he control point number to return data for :returns: a (x, y) tuple of float - coordinates of the control point :raises Error: Gets the control point point_num of patch patch_num for a mesh pattern. ``patch_num`` can range from 0 to n-1 where n is the number returned by :meth:`get_patch_count`. Valid values for ``point_num`` are from 0 to 3 and identify the control points as explained in :class:`MeshPattern`. """ def get_corner_color_rgba(self, patch_num: int, corner_num: int) -> Tuple[float, float, float, float]: """ :param patch_num: the patch number to return data for :param corner_num: the corner number to return data for :returns: a (red, green, blue, alpha) tuple of float :raises Error: Gets the color information in corner ``corner_num`` of patch ``patch_num`` for a mesh pattern. ``patch_num`` can range from 0 to n-1 where n is the number returned by :meth:`get_patch_count`. Valid values for ``corner_num`` are from 0 to 3 and identify the corners as explained in :class:`MeshPattern`. """ def get_patch_count(self) -> int: """ :returns: number of patches Gets the number of patches specified in the given mesh pattern. The number only includes patches which have been finished by calling :meth:`end_patch`. For example it will be 0 during the definition of the first patch. """ def line_to(self, x: float, y: float) -> None: """ :param x: the X coordinate of the end of the new line :param y: the Y coordinate of the end of the new line :raises Error: Adds a line to the current patch from the current point to position (x , y ) in pattern-space coordinates. If there is no current point before the call to :meth:`line_to` this function will behave as ``pattern.move_to(x ,y)``. After this call the current point will be (x , y ). """ def move_to(self, x: float, y: float) -> None: """ :param x: the X coordinate of the new position :param y: the Y coordinate of the new position :raises Error: Define the first point of the current patch in a mesh pattern. After this call the current point will be (x , y ). """ def set_control_point(self, point_num: int, x: float, y: float) -> None: """ :param point_num: the control point to set the position for :param x: the X coordinate of the control point :param y: the Y coordinate of the control point :raises Error: Set an internal control point of the current patch. Valid values for point_num are from 0 to 3 and identify the control points as explained in :class:`MeshPattern`. """ def set_corner_color_rgb(self, corner_num: int, red: float, green: float, blue: float) -> None: """ :param corner_num: the corner to set the color for :param red: red component of color :param green: green component of color :param blue: blue component of color :raises Error: Sets the color of a corner of the current patch in a mesh pattern. The color is specified in the same way as in :meth:`Context.set_source_rgb`. Valid values for corner_num are from 0 to 3 and identify the corners as explained in :class:`MeshPattern`. """ def set_corner_color_rgba(self, corner_num: int, red: float, green: float, blue: float, alpha: float) -> None: """ :param corner_num: the corner to set the color for :param red: red component of color :param green: green component of color :param blue: blue component of color :param alpha: alpha component of color :raises Error: Sets the color of a corner of the current patch in a mesh pattern. The color is specified in the same way as in :meth:`Context.set_source_rgba`. Valid values for corner_num are from 0 to 3 and identify the corners as explained in :class:`MeshPattern`. """ def get_path(self, patch_num: int) -> Path: """ :param patch_num: the patch number to return data for :returns: the path defining the patch :raises Error: Gets path defining the patch ``patch_num`` for a mesh pattern. ``patch_num`` can range from 0 to n-1 where n is the number returned by :meth:`get_patch_count`. """ class PDFSurface(Surface): """ The PDFSurface is used to render cairo graphics to Adobe PDF files and is a multi-page vector surface backend. .. versionadded:: 1.2 """ def __init__(self, fobj: Union[_PathLike, _FileLike], width_in_points: float, height_in_points: float) -> None: """ :param fobj: a filename or writable file object. None may be used to specify no output. This will generate a *PDFSurface* that may be queried and used as a source, without generating a temporary file. :param width_in_points: width of the surface, in points (1 point == 1/72.0 inch) :param height_in_points: height of the surface, in points (1 point == 1/72.0 inch) :returns: a new *PDFSurface* of the specified size in points to be written to *fobj*. .. versionadded:: 1.2 """ def set_custom_metadata(self, name: str, value: Optional[str]) -> None: """ :param name: The name of the custom metadata item to set. :param value: The value of the metadata. Set custom document metadata. *name* may be any string except for the following names reserved by PDF: "Title", "Author", "Subject", "Keywords", "Creator", "Producer", "CreationDate", "ModDate", "Trapped". If *value* is :obj:`None` or an empty string, the *name* metadata will not be set. For example:: surface.set_custom_metadata("ISBN", "978-0123456789") .. versionadded:: 1.23.0 Only available with cairo 1.17.6+ """ def set_size(self, width_in_points: float, height_in_points: float) -> None: """ :param width_in_points: new surface width, in points (1 point == 1/72.0 inch) :param height_in_points: new surface height, in points (1 point == 1/72.0 inch) Changes the size of a *PDFSurface* for the current (and subsequent) pages. This function should only be called before any drawing operations have been performed on the current page. The simplest way to do this is to call this function immediately after creating the surface or immediately after completing a page with either :meth:`Context.show_page` or :meth:`Context.copy_page`. .. versionadded:: 1.2 """ def restrict_to_version(self, version: PDFVersion) -> None: """ :param version: PDF version Restricts the generated PDF file to version . See :meth:`get_versions` for a list of available version values that can be used here. This function should only be called before any drawing operations have been performed on the given surface. The simplest way to do this is to call this function immediately after creating the surface. .. versionadded:: 1.12.0 """ @staticmethod def get_versions() -> List[PDFVersion]: """ :returns: supported version list Retrieve the list of supported versions. See :meth:`restrict_to_version`. .. versionadded:: 1.12.0 """ @staticmethod def version_to_string(version: PDFVersion) -> str: """ :param version: PDF version :returns: the string associated to the given version :raises ValueError: if version isn't valid Get the string representation of the given version id. See :meth:`get_versions` for a way to get the list of valid version ids. .. versionadded:: 1.12.0 """ def add_outline(self, parent_id: int, utf8: str, link_attribs: str, flags: PDFOutlineFlags) -> int: """ :param parent_id: the id of the parent item or :data:`PDF_OUTLINE_ROOT` if this is a top level item. :param utf8: the name of the outline :param link_attribs: the link attributes specifying where this outline links to :param flags: outline item flags :returns: the id for the added item. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def set_metadata(self, metadata: PDFMetadata, utf8: str) -> None: """ :param metadata: The metadata item to set. :param utf8: metadata value Set document metadata. The :attr:`PDFMetadata.CREATE_DATE` and :attr:`PDFMetadata.MOD_DATE` values must be in ISO-8601 format: YYYY-MM-DDThh:mm:ss. An optional timezone of the form "[+/-]hh:mm" or "Z" for UTC time can be appended. All other metadata values can be any UTF-8 string. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def set_page_label(self, utf8: str) -> None: """ :param utf8: metadata value Set page label for the current page. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def set_thumbnail_size(self, width: int, height: int) -> None: """ :param width: Thumbnail width. :param height: Thumbnail height Set the thumbnail image size for the current and all subsequent pages. Setting a width or height of 0 disables thumbnails for the current and subsequent pages. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ class PSSurface(Surface): """ The *PSSurface* is used to render cairo graphics to Adobe PostScript files and is a multi-page vector surface backend. """ def __init__(self, fobj: Union[_FileLike, _PathLike], width_in_points: float, height_in_points: float) -> None: """ :param fobj: a filename or writable file object. None may be used to specify no output. This will generate a *PSSurface* that may be queried and used as a source, without generating a temporary file. :param width_in_points: width of the surface, in points (1 point == 1/72.0 inch) :param height_in_points: height of the surface, in points (1 point == 1/72.0 inch) :returns: a new *PDFSurface* of the specified size in points to be written to *fobj*. :raises: :exc:`MemoryError` in case of no memory Note that the size of individual pages of the PostScript output can vary. See :meth:`.set_size`. """ def dsc_begin_page_setup(self) -> None: """ This method indicates that subsequent calls to :meth:`.dsc_comment` should direct comments to the PageSetup section of the PostScript output. This method call is only needed for the first page of a surface. It should be called after any call to :meth:`.dsc_begin_setup` and before any drawing is performed to the surface. See :meth:`.dsc_comment` for more details. .. versionadded:: 1.2 """ def dsc_begin_setup(self) -> None: """ This function indicates that subsequent calls to :meth:`.dsc_comment` should direct comments to the Setup section of the PostScript output. This function should be called at most once per surface, and must be called before any call to :meth:`.dsc_begin_page_setup` and before any drawing is performed to the surface. See :meth:`.dsc_comment` for more details. .. versionadded:: 1.2 """ def dsc_comment(self, comment: str) -> None: """ :param comment: a comment string to be emitted into the PostScript output Emit a comment into the PostScript output for the given surface. The comment is expected to conform to the PostScript Language Document Structuring Conventions (DSC). Please see that manual for details on the available comments and their meanings. In particular, the %%IncludeFeature comment allows a device-independent means of controlling printer device features. So the PostScript Printer Description Files Specification will also be a useful reference. The comment string must begin with a percent character (%) and the total length of the string (including any initial percent characters) must not exceed 255 characters. Violating either of these conditions will place *PSSurface* into an error state. But beyond these two conditions, this function will not enforce conformance of the comment with any particular specification. The comment string should not have a trailing newline. The DSC specifies different sections in which particular comments can appear. This function provides for comments to be emitted within three sections: the header, the Setup section, and the PageSetup section. Comments appearing in the first two sections apply to the entire document while comments in the BeginPageSetup section apply only to a single page. For comments to appear in the header section, this function should be called after the surface is created, but before a call to :meth:`.dsc_begin_setup`. For comments to appear in the Setup section, this function should be called after a call to :meth:`.dsc_begin_setup` but before a call to :meth:`.dsc_begin_page_setup`. For comments to appear in the PageSetup section, this function should be called after a call to :meth:`.dsc_begin_page_setup`. Note that it is only necessary to call :meth:`.dsc_begin_page_setup` for the first page of any surface. After a call to :meth:`Context.show_page` or :meth:`Context.copy_page` comments are unambiguously directed to the PageSetup section of the current page. But it doesn't hurt to call this function at the beginning of every page as that consistency may make the calling code simpler. As a final note, cairo automatically generates several comments on its own. As such, applications must not manually generate any of the following comments: Header section: %!PS-Adobe-3.0, %Creator, %CreationDate, %Pages, %BoundingBox, %DocumentData, %LanguageLevel, %EndComments. Setup section: %BeginSetup, %EndSetup PageSetup section: %BeginPageSetup, %PageBoundingBox, %EndPageSetup. Other sections: %BeginProlog, %EndProlog, %Page, %Trailer, %EOF Here is an example sequence showing how this function might be used:: surface = PSSurface (filename, width, height) ... surface.dsc_comment (surface, "%%Title: My excellent document") surface.dsc_comment (surface, "%%Copyright: Copyright (C) 2006 Cairo Lover") ... surface.dsc_begin_setup (surface) surface.dsc_comment (surface, "%%IncludeFeature: *MediaColor White") ... surface.dsc_begin_page_setup (surface) surface.dsc_comment (surface, "%%IncludeFeature: *PageSize A3") surface.dsc_comment (surface, "%%IncludeFeature: *InputSlot LargeCapacity") surface.dsc_comment (surface, "%%IncludeFeature: *MediaType Glossy") surface.dsc_comment (surface, "%%IncludeFeature: *MediaColor Blue") ... draw to first page here .. ctx.show_page (cr) ... surface.dsc_comment (surface, "%%IncludeFeature: PageSize A5"); ... .. versionadded:: 1.2 """ def get_eps(self) -> bool: """ :returns: True iff the *PSSurface* will output Encapsulated PostScript. .. versionadded:: 1.6 """ @staticmethod def level_to_string(level: PSLevel) -> str: """ :param level: a PS level :returns: the string associated to given level. Get the string representation of the given *level*. See :meth:`get_levels` for a way to get the list of valid level ids. .. note:: Prior to 1.12 this was available under :meth:`ps_level_to_string` .. versionadded:: 1.12.0 """ ps_level_to_string = level_to_string """ Alias for :meth:`level_to_string` .. versionadded:: 1.6 """ def restrict_to_level(self, level: PSLevel) -> None: """ :param level: a PS level Restricts the generated PostSript file to *level*. See :meth:`get_levels` for a list of available level values that can be used here. This function should only be called before any drawing operations have been performed on the given surface. The simplest way to do this is to call this function immediately after creating the surface. .. versionadded:: 1.6 """ def set_eps(self, eps: bool) -> None: """ :param eps: True to output EPS format PostScript If *eps* is True, the PostScript surface will output Encapsulated PostScript. This function should only be called before any drawing operations have been performed on the current page. The simplest way to do this is to call this function immediately after creating the surface. An Encapsulated PostScript file should never contain more than one page. .. versionadded:: 1.6 """ def set_size(self, width_in_points: float, height_in_points: float) -> None: """ :param width_in_points: new surface width, in points (1 point == 1/72.0 inch) :param height_in_points: new surface height, in points (1 point == 1/72.0 inch) Changes the size of a PostScript surface for the current (and subsequent) pages. This function should only be called before any drawing operations have been performed on the current page. The simplest way to do this is to call this function immediately after creating the surface or immediately after completing a page with either :meth:`Context.show_page` or :meth:`Context.copy_page`. .. versionadded:: 1.2 """ @staticmethod def get_levels() -> List[PSLevel]: """ :returns: supported level list Retrieve the list of supported levels. See :meth:`restrict_to_level`. .. versionadded:: 1.12.0 """ class SVGSurface(Surface): """ The *SVGSurface* is used to render cairo graphics to SVG files and is a multi-page vector surface backend """ def __init__(self, fobj: "Union[_PathLike, _FileLike]", width_in_points: float, height_in_points: float) -> None: """ :param fobj: a filename or writable file object. None may be used to specify no output. This will generate a *SVGSurface* that may be queried and used as a source, without generating a temporary file. :param width_in_points: width of the surface, in points (1 point == 1/72.0 inch) :param height_in_points: height of the surface, in points (1 point == 1/72.0 inch) """ def restrict_to_version(self, version: SVGVersion) -> None: """ :param version: SVG version Restricts the generated SVG file to version . See :meth:`get_versions` for a list of available version values that can be used here. This function should only be called before any drawing operations have been performed on the given surface. The simplest way to do this is to call this function immediately after creating the surface. .. versionadded:: 1.12.0 """ @staticmethod def get_versions() -> List[SVGVersion]: """ :returns: supported version list Retrieve the list of supported versions. See :meth:`restrict_to_version`. .. versionadded:: 1.12.0 """ @staticmethod def version_to_string(version: SVGVersion) -> str: """ :param version: SVG version :returns: the string associated to the given version :raises ValueError: if version isn't valid Get the string representation of the given version id. See :meth:`get_versions` for a way to get the list of valid version ids. .. versionadded:: 1.12.0 """ def get_document_unit(self) -> SVGUnit: """ :returns: the SVG unit of the SVG surface. :rtype: SVGUnit Get the unit of the SVG surface. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ def set_document_unit(self, unit: SVGUnit) -> None: """ :param SVGUnit unit: SVG unit Use the specified unit for the width and height of the generated SVG file. See :class:`SVGUnit` for a list of available unit values that can be used here. This function can be called at any time before generating the SVG file. However to minimize the risk of ambiguities it's recommended to call it before any drawing operations have been performed on the given surface, to make it clearer what the unit used in the drawing operations is. The simplest way to do this is to call this function immediately after creating the SVG surface. Note if this function is never called, the default unit for SVG documents generated by cairo will be "pt". This is for historical reasons. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ class RadialGradient(Gradient): def __init__(self, cx0: float, cy0: float, radius0: float, cx1: float, cy1: float, radius1: float) -> None: """ :param cx0: x coordinate for the center of the start circle :param cy0: y coordinate for the center of the start circle :param radius0: radius of the start circle :param cx1: x coordinate for the center of the end circle :param cy1: y coordinate for the center of the end circle :param radius1: radius of the end circle Creates a new *RadialGradient* pattern between the two circles defined by (cx0, cy0, radius0) and (cx1, cy1, radius1). Before using the gradient pattern, a number of color stops should be defined using :meth:`Gradient.add_color_stop_rgb` or :meth:`Gradient.add_color_stop_rgba`. Note: The coordinates here are in pattern space. For a new pattern, pattern space is identical to user space, but the relationship between the spaces can be changed with :meth:`Pattern.set_matrix`. """ def get_radial_circles(self) -> Tuple[float, float, float, float, float, float]: """ :returns: (x0, y0, r0, x1, y1, r1) - a tuple of float * x0: return value for the x coordinate of the center of the first circle * y0: return value for the y coordinate of the center of the first circle * r0: return value for the radius of the first circle * x1: return value for the x coordinate of the center of the second circle * y1: return value for the y coordinate of the center of the second circle * r1: return value for the radius of the second circle Gets the *Gradient* endpoint circles for a *RadialGradient*, each specified as a center coordinate and a radius. .. versionadded:: 1.4 """ _AcquireCallback = Callable[[Surface, RectangleInt], Surface] _ReleaseCallback = Callable[[Surface], None] class RasterSourcePattern(Pattern): """ The raster source provides the ability to supply arbitrary pixel data whilst rendering. The pixels are queried at the time of rasterisation by means of user callback functions, allowing for the ultimate flexibility. For example, in handling compressed image sources, you may keep a MRU cache of decompressed images and decompress sources on the fly and discard old ones to conserve memory. For the raster source to be effective, you must at least specify the acquire and release callbacks which are used to retrieve the pixel data for the region of interest and demark when it can be freed afterwards. Other callbacks are provided for when the pattern is copied temporarily during rasterisation, or more permanently as a snapshot in order to keep the pixel data available for printing. .. versionadded:: 1.15 """ def __init__(self, content: Content, width: int, height: int) -> None: """ :param content: content type for the pixel data that will be returned. Knowing the content type ahead of time is used for analysing the operation and picking the appropriate rendering path. :param width: maximum size of the sample area :param height: maximum size of the sample area Creates a new user pattern for providing pixel data. Use the setter functions to associate callbacks with the returned pattern. .. versionadded:: 1.15 """ def set_acquire(self, acquire: Optional[_AcquireCallback], release: Optional[_ReleaseCallback]) -> None: """ :param acquire: acquire callback or :obj:`None` to unset it :type acquire: :obj:`callable` :param release: (optional) release callback or :obj:`None` :type release: :obj:`callable` :raises Error: Specifies the callbacks used to generate the image surface for a rendering operation (acquire) and the function used to cleanup that surface afterwards. The acquire callback should create a surface (preferably an image surface created to match the target using :meth:`Surface.create_similar_image`) that defines at least the region of interest specified by extents. The surface is allowed to be the entire sample area, but if it does contain a subsection of the sample area, the surface extents should be provided by setting the device offset (along with its width and height) using :meth:`Surface.set_device_offset`. .. function:: acquire(target, extents) :param Surface target: the rendering target surface :param RectangleInt extents: rectangular region of interest in pixels in sample space :rtype: Surface This function is called when a pattern is being rendered from. It should create a surface that provides the pixel data for the region of interest as defined by extents, though the surface itself does not have to be limited to that area. For convenience the surface should probably be of image type, created with :meth:`Surface.create_similar_image` for the target (which enables the number of copies to be reduced during transfer to the device). Another option, might be to return a similar surface to the target for explicit handling by the application of a set of cached sources on the device. The region of sample data provided should be defined using :meth:`Surface.set_device_offset` to specify the top-left corner of the sample data (along with width and height of the surface). .. function:: release(surface) :param Surface surface: the surface created during acquire This function is called when the pixel data is no longer being accessed by the pattern for the rendering operation. .. versionadded:: 1.15 """ def get_acquire(self) -> Tuple[Optional[_AcquireCallback], Optional[_ReleaseCallback]]: """ :returns: a (acquire, release) tuple of callables or None as set through :meth:`set_acquire` Queries the current acquire and release callbacks. .. versionadded:: 1.15 """ class RecordingSurface(Surface): """ A *RecordingSurface* is a surface that records all drawing operations at the highest level of the surface backend interface, (that is, the level of paint, mask, stroke, fill, and show_text_glyphs). The recording surface can then be "replayed" against any target surface by using it as a source surface. If you want to replay a surface so that the results in target will be identical to the results that would have been obtained if the original operations applied to the recording surface had instead been applied to the target surface, you can use code like this:: cr = cairo.Context(target) cr.set_source_surface(recording_surface, 0.0, 0.0) cr.paint() A *RecordingSurface* is logically unbounded, i.e. it has no implicit constraint on the size of the drawing surface. However, in practice this is rarely useful as you wish to replay against a particular target surface with known bounds. For this case, it is more efficient to specify the target extents to the recording surface upon creation. The recording phase of the recording surface is careful to snapshot all necessary objects (paths, patterns, etc.), in order to achieve accurate replay. .. versionadded:: 1.11.0 """ def __init__(self, content: Content, rectangle: Rectangle) -> None: """ :param content: the content for the new surface :param rectangle: or None to record unbounded operations. Creates a *RecordingSurface* which can be used to record all drawing operations at the highest level (that is, the level of paint, mask, stroke, fill and show_text_glyphs). The *RecordingSurface* can then be "replayed" against any target surface by using it as a source to drawing operations. The recording phase of the *RecordingSurface* is careful to snapshot all necessary objects (paths, patterns, etc.), in order to achieve accurate replay. .. versionadded:: 1.11.0 """ def ink_extents(self) -> Tuple[float, float, float, float]: """ * x0: the x-coordinate of the top-left of the ink bounding box * y0: the y-coordinate of the top-left of the ink bounding box * width: the width of the ink bounding box * height: the height of the ink bounding box Measures the extents of the operations stored within the *RecordingSurface*. This is useful to compute the required size of an *ImageSurface* (or equivalent) into which to replay the full sequence of drawing operations. .. versionadded:: 1.11.0 """ def get_extents(self) -> Optional[Rectangle]: """ :returns: a rectangle or :obj:`None` if the surface is unbounded. Get the extents of the recording-surface. .. versionadded:: 1.12.0 """ class Region: """ Region is a simple graphical data type representing an area of integer-aligned rectangles. They are often used on raster surfaces to track areas of interest, such as change or clip areas. .. versionadded:: 1.11.0 """ def __init__(self, rectangle: Union[RectangleInt, List[RectangleInt]]) -> None: """ :param rectangle_int: a rectangle or a list of rectangle Allocates a new empty region object or a region object with the containing rectangle(s). """ def copy(self) -> "Region": """ :returns: A newly allocated :class:`Region`. Allocates a new *Region* object copying the area from original. """ def get_extents(self) -> RectangleInt: """ :returns: The bounding rectangle of region """ def num_rectangles(self) -> int: """ :returns: The number of rectangles contained in region """ def get_rectangle(self, nth: int) -> RectangleInt: """ :param nth: a number indicating which rectangle should be returned :returns: The *nth* rectangle from the region """ def is_empty(self) -> bool: """ :returns: Whether region is empty """ def contains_point(self, x: int, y: int) -> bool: """ :param x: The x coordinate of a point :param y: The y coordinate of a point :returns: Whether (x , y) is contained in the region """ def contains_rectangle(self, rectangle: RectangleInt) -> RegionOverlap: """ :param rectangle: a region :returns: region overlap Checks whether rectangle is inside, outside or partially contained in region """ def equal(self, region: "Region") -> bool: """ :param region: a region :returns: Whether both regions contained the same coverage """ def translate(self, dx: int, dy: int) -> None: """ :param dx: Amount to translate in the x direction :param dy: Amount to translate in the y direction Translates region by (dx , dy ). """ def intersect(self, other: "Union[Region, RectangleInt]") -> "Region": """ :param other: region or rectangle :returns: The intersection of the region and the passed region or rectangle """ def subtract(self, other: "Union[Region, RectangleInt]") -> "Region": """ :param other: region or rectangle :returns: The result of the subtraction of the region and the passed region or rectangle """ def union(self, other: "Union[Region, RectangleInt]") -> "Region": """ :param other: region or rectangle :returns: The union of the region and the passed region or rectangle """ def xor(self, other: "Union[Region, RectangleInt]") -> "Region": """ :param other: region or rectangle :returns: The exclusive difference of the region and the passed region or rectangle """ class ScriptDevice(Device): """ .. versionadded:: 1.14 """ def __init__(self, fobj: Union[_FileLike, _PathLike]) -> None: """ :param fobj: a filename or writable file object. Creates a output device for emitting the script, used when creating the individual surfaces. """ def set_mode(self, mode: ScriptMode) -> None: """ :param mode: the new mode Change the output mode of the script """ def get_mode(self) -> ScriptMode: """ :returns: the current output mode of the script Queries the script for its current output mode. """ def write_comment(self, comment: str) -> None: """ :param comment: the string to emit Emit a string verbatim into the script. """ def from_recording_surface(self, recording_surface: RecordingSurface) -> None: """ :param recording_surface: the recording surface to replay :raises cairo.Error: Converts the record operations in recording_surface into a script. """ class ScriptSurface(Surface): """ The script surface provides the ability to render to a native script that matches the cairo drawing model. The scripts can be replayed using tools under the util/cairo-script directory, or with cairo-perf-trace. .. versionadded:: 1.14 """ def __init__(self, script: ScriptDevice, content: Content, width: float, height: float) -> None: """ :param script: the script (output device) :param content: the content of the surface :param width: width in pixels :param height: height in pixels :raises cairo.Error: Create a new surface that will emit its rendering through ``script``. """ @classmethod def create_for_target(cls, script: ScriptDevice, target: Surface) -> "ScriptSurface": """ :param script: the script (output device) :param target: a target surface to wrap :raises cairo.Error: Create a proxy surface that will render to ``target`` and record the operations to ``device``. .. versionadded:: 1.14 """ class Win32Surface(Surface): """ The Microsoft Windows surface is used to render cairo graphics to Microsoft Windows windows, bitmaps, and printing device contexts. """ def __init__(self, hdc: int) -> None: """ :param hdc: the DC to create a surface for :type hdc: int Creates a cairo surface that targets the given DC. The DC will be queried for its initial clip extents, and this will be used as the size of the cairo surface. The resulting surface will always be of format cairo.FORMAT_RGB24, see :class:`cairo.Format`. """ class Win32PrintingSurface(Surface): """ The Win32PrintingSurface is a multi-page vector surface type. """ def __init__(self, hdc: int) -> None: """ :param hdc: the DC to create a surface for :returns: the newly created surface Creates a cairo surface that targets the given DC. The DC will be queried for its initial clip extents, and this will be used as the size of the cairo surface. The DC should be a printing DC; antialiasing will be ignored, and GDI will be used as much as possible to draw to the surface. The returned surface will be wrapped using the paginated surface to provide correct complex rendering behaviour; :meth:`cairo.Surface.show_page` and associated methods must be used for correct output. """ class SolidPattern(Pattern): def __init__(self, red: float, green: float, blue: float, alpha: float=1.0) -> None: """ :param red: red component of the color :param green: green component of the color :param blue: blue component of the color :param alpha: alpha component of the color Creates a new *SolidPattern* corresponding to a translucent color. The color components are floating point numbers in the range 0 to 1. If the values passed in are outside that range, they will be clamped. """ def get_rgba(self) -> Tuple[float, float, float, float]: """ :returns: (red, green, blue, alpha) a tuple of float Gets the solid color for a *SolidPattern*. .. versionadded:: 1.4 """ class SurfaceObserverMode(_IntEnum): """ Whether operations should be recorded. .. versionadded:: 1.14 """ NORMAL: "SurfaceObserverMode" = ... """no recording is done""" RECORD_OPERATIONS: "SurfaceObserverMode" = ... """operations are recorded""" class TeeSurface(Surface): """ This surface supports redirecting all its input to multiple surfaces. .. versionadded:: 1.14 """ def __init__(self, master: Surface) -> None: ... def add(self, target: Surface) -> None: """ :param target: :raises cairo.Error: Add the surface .. versionadded:: 1.14 """ def remove(self, target: Surface) -> None: """ :param target: :raises cairo.Error: Remove the surface .. versionadded:: 1.14 """ def index(self, index: int) -> Surface: """ :param index: :raises cairo.Error: Returns the surface at index ``index``. The master surface is at index 0. .. versionadded:: 1.14 """ class ToyFontFace(FontFace): """ The *cairo.ToyFontFace* class can be used instead of :meth:`Context.select_font_face` to create a toy font independently of a context. .. versionadded:: 1.8.4 """ def __init__(self, family: str, slant: FontSlant=..., weight: FontWeight=...) -> None: """ :param family: a font family name :param slant: the font slant of the font, defaults to :attr:`cairo.FontSlant.NORMAL`. :param weight: the font weight of the font, defaults to :attr:`cairo.FontWeight.NORMAL`. Creates a *ToyFontFace* from a triplet of family, slant, and weight. These font faces are used in implementation of the the "toy" font API. If family is the zero-length string "", the platform-specific default family is assumed. The default family then can be queried using :meth:`.get_family`. The :meth:`Context.select_font_face` method uses this to create font faces. See that function for limitations of toy font faces. """ def get_family(self) -> str: """ :returns: the family name of a toy font .. versionadded:: 1.8.4 """ def get_slant(self) -> FontSlant: """ :returns: the font slant value .. versionadded:: 1.8.4 """ def get_weight(self) -> FontWeight: """ :returns: the font weight value .. versionadded:: 1.8.4 """ class XCBSurface(Surface): """ The XCB surface is used to render cairo graphics to X Window System windows and pixmaps using the XCB library. Note that the XCB surface automatically takes advantage of the X render extension if it is available. """ def __init__(self, connection: Any, drawable: Any, visualtype: Any, width: int, height: int) -> None: """ :param connection: an XCB connection :param drawable: a X drawable :param visualtype: a X visualtype :param width: The surface width :param height: The surface height Creates a cairo surface that targets the given drawable (pixmap or window). .. note:: This type isn't implemented. Please file a bug if you need it. """ def set_size(self, width: int, height: int) -> None: """ :param width: The width of the surface :param height: The height of the surface Informs cairo of the new size of the X Drawable underlying the surface. For a surface created for a Window (rather than a Pixmap), this function must be called each time the size of the window changes. (For a subwindow, you are normally resizing the window yourself, but for a toplevel window, it is necessary to listen for ConfigureNotify events.) A Pixmap can never change size, so it is never necessary to call this function on a surface created for a Pixmap. """ class XlibSurface(Surface): """ The XLib surface is used to render cairo graphics to X Window System windows and pixmaps using the XLib library. Note that the XLib surface automatically takes advantage of X render extension if it is available. .. note:: *XlibSurface* cannot be instantiated directly because Python interaction with Xlib would require open source Python bindings to Xlib which provided a C API. However, an *XlibSurface* instance can be returned from a function call when using pygtk http://www.pygtk.org/. """ def get_depth(self) -> int: """ :returns: the number of bits used to represent each pixel value. .. versionadded:: 1.2 """ def get_height(self) -> int: """ :returns: the height of the X Drawable underlying the surface in pixels. .. versionadded:: 1.2 """ def get_width(self) -> int: """ :returns: the width of the X Drawable underlying the surface in pixels. .. versionadded:: 1.2 """ def get_include() -> str: """ :returns: a path to the directory containing the C header files Gives the include path which should be passed to the compiler. .. versionadded:: 1.16.0 """ MIME_TYPE_JP2: str = ... """ The Joint Photographic Experts Group (JPEG) 2000 image coding standard (ISO/IEC 15444-1). .. versionadded:: 1.12.0 """ MIME_TYPE_JPEG: str = ... """ The Joint Photographic Experts Group (JPEG) image coding standard (ISO/IEC 10918-1). .. versionadded:: 1.12.0 """ MIME_TYPE_PNG: str = ... """ The Portable Network Graphics image file format (ISO/IEC 15948). .. versionadded:: 1.12.0 """ MIME_TYPE_URI: str = ... """ URI for an image file (unofficial MIME type). .. versionadded:: 1.12.0 """ MIME_TYPE_UNIQUE_ID: str = ... """ Unique identifier for a surface (cairo specific MIME type). All surfaces with the same unique identifier will only be embedded once. .. versionadded:: 1.12.0 """ MIME_TYPE_CCITT_FAX: str = ... """ Group 3 or Group 4 CCITT facsimile encoding (International Telecommunication Union, Recommendations T.4 and T.6.) .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ MIME_TYPE_CCITT_FAX_PARAMS: str = ... """ Decode parameters for Group 3 or Group 4 CCITT facsimile encoding. See `CCITT Fax Images <https://cairographics.org/manual/cairo-PDF-Surfaces.html#ccitt>`__. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ MIME_TYPE_EPS: str = ... """ Encapsulated PostScript file. Encapsulated PostScript File Format Specification .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ MIME_TYPE_EPS_PARAMS: str = ... """ Embedding parameters Encapsulated PostScript data. See Embedding EPS files. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ MIME_TYPE_JBIG2: str = ... """ Joint Bi-level Image Experts Group image coding standard (ISO/IEC 11544). .. versionadded:: 1.18.0 """ MIME_TYPE_JBIG2_GLOBAL: str = ... """ Joint Bi-level Image Experts Group image coding standard (ISO/IEC 11544) global segment. .. versionadded:: 1.18.0 """ MIME_TYPE_JBIG2_GLOBAL_ID: str = ... """ An unique identifier shared by a JBIG2 global segment and all JBIG2 images that depend on the global segment. .. versionadded:: 1.18.0 """ TAG_DEST: str = ... """ Create a destination for a hyperlink. Destination tag attributes are detailed at Destinations. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ TAG_LINK: str = ... """ Create hyperlink. Link tag attributes are detailed at Links. .. versionadded:: 1.18.0 Only available with cairo 1.15.10+ """ TAG_CONTENT: str = ... """ Create a content tag. .. versionadded:: 1.25.0 Only available with cairo 1.18.0+ """ TAG_CONTENT_REF: str = ... """ Create a content reference tag. .. versionadded:: 1.25.0 Only available with cairo 1.18.0+ """ CAPI: Any = ... ANTIALIAS_BEST = Antialias.BEST ANTIALIAS_DEFAULT = Antialias.DEFAULT ANTIALIAS_FAST = Antialias.FAST ANTIALIAS_GOOD = Antialias.GOOD ANTIALIAS_GRAY = Antialias.GRAY ANTIALIAS_NONE = Antialias.NONE ANTIALIAS_SUBPIXEL = Antialias.SUBPIXEL CONTENT_ALPHA = Content.ALPHA CONTENT_COLOR = Content.COLOR CONTENT_COLOR_ALPHA = Content.COLOR_ALPHA EXTEND_NONE = Extend.NONE EXTEND_PAD = Extend.PAD EXTEND_REFLECT = Extend.REFLECT EXTEND_REPEAT = Extend.REPEAT FILL_RULE_EVEN_ODD = FillRule.EVEN_ODD FILL_RULE_WINDING = FillRule.WINDING FILTER_BEST = Filter.BEST FILTER_BILINEAR = Filter.BILINEAR FILTER_FAST = Filter.FAST FILTER_GAUSSIAN = Filter.GAUSSIAN FILTER_GOOD = Filter.GOOD FILTER_NEAREST = Filter.NEAREST FONT_SLANT_ITALIC = FontSlant.ITALIC FONT_SLANT_NORMAL = FontSlant.NORMAL FONT_SLANT_OBLIQUE = FontSlant.OBLIQUE FONT_WEIGHT_BOLD = FontWeight.BOLD FONT_WEIGHT_NORMAL = FontWeight.NORMAL FORMAT_A1 = Format.A1 FORMAT_A8 = Format.A8 FORMAT_ARGB32 = Format.ARGB32 FORMAT_INVALID = Format.INVALID FORMAT_RGB16_565 = Format.RGB16_565 FORMAT_RGB24 = Format.RGB24 FORMAT_RGB30 = Format.RGB30 FORMAT_RGB96F = Format.RGB96F FORMAT_RGBA128F = Format.RGBA128F HINT_METRICS_DEFAULT = HintMetrics.DEFAULT HINT_METRICS_OFF = HintMetrics.OFF HINT_METRICS_ON = HintMetrics.ON HINT_STYLE_DEFAULT = HintStyle.DEFAULT HINT_STYLE_FULL = HintStyle.FULL HINT_STYLE_MEDIUM = HintStyle.MEDIUM HINT_STYLE_NONE = HintStyle.NONE HINT_STYLE_SLIGHT = HintStyle.SLIGHT LINE_CAP_BUTT = LineCap.BUTT LINE_CAP_ROUND = LineCap.ROUND LINE_CAP_SQUARE = LineCap.SQUARE LINE_JOIN_BEVEL = LineJoin.BEVEL LINE_JOIN_MITER = LineJoin.MITER LINE_JOIN_ROUND = LineJoin.ROUND OPERATOR_ADD = Operator.ADD OPERATOR_ATOP = Operator.ATOP OPERATOR_CLEAR = Operator.CLEAR OPERATOR_COLOR_BURN = Operator.COLOR_BURN OPERATOR_COLOR_DODGE = Operator.COLOR_DODGE OPERATOR_DARKEN = Operator.DARKEN OPERATOR_DEST = Operator.DEST OPERATOR_DEST_ATOP = Operator.DEST_ATOP OPERATOR_DEST_IN = Operator.DEST_IN OPERATOR_DEST_OUT = Operator.DEST_OUT OPERATOR_DEST_OVER = Operator.DEST_OVER OPERATOR_DIFFERENCE = Operator.DIFFERENCE OPERATOR_EXCLUSION = Operator.EXCLUSION OPERATOR_HARD_LIGHT = Operator.HARD_LIGHT OPERATOR_HSL_COLOR = Operator.HSL_COLOR OPERATOR_HSL_HUE = Operator.HSL_HUE OPERATOR_HSL_LUMINOSITY = Operator.HSL_LUMINOSITY OPERATOR_HSL_SATURATION = Operator.HSL_SATURATION OPERATOR_IN = Operator.IN OPERATOR_LIGHTEN = Operator.LIGHTEN OPERATOR_MULTIPLY = Operator.MULTIPLY OPERATOR_OUT = Operator.OUT OPERATOR_OVER = Operator.OVER OPERATOR_OVERLAY = Operator.OVERLAY OPERATOR_SATURATE = Operator.SATURATE OPERATOR_SCREEN = Operator.SCREEN OPERATOR_SOFT_LIGHT = Operator.SOFT_LIGHT OPERATOR_SOURCE = Operator.SOURCE OPERATOR_XOR = Operator.XOR PATH_CLOSE_PATH = PathDataType.CLOSE_PATH PATH_CURVE_TO = PathDataType.CURVE_TO PATH_LINE_TO = PathDataType.LINE_TO PATH_MOVE_TO = PathDataType.MOVE_TO PDF_VERSION_1_4 = PDFVersion.VERSION_1_4 PDF_VERSION_1_5 = PDFVersion.VERSION_1_5 PDF_VERSION_1_6 = PDFVersion.VERSION_1_6 PDF_VERSION_1_7 = PDFVersion.VERSION_1_7 PS_LEVEL_2 = PSLevel.LEVEL_2 PS_LEVEL_3 = PSLevel.LEVEL_3 REGION_OVERLAP_IN = RegionOverlap.IN REGION_OVERLAP_OUT = RegionOverlap.OUT REGION_OVERLAP_PART = RegionOverlap.PART SCRIPT_MODE_ASCII = ScriptMode.ASCII SCRIPT_MODE_BINARY = ScriptMode.BINARY STATUS_CLIP_NOT_REPRESENTABLE = Status.CLIP_NOT_REPRESENTABLE STATUS_DEVICE_ERROR = Status.DEVICE_ERROR STATUS_DEVICE_FINISHED = Status.DEVICE_FINISHED STATUS_DEVICE_TYPE_MISMATCH = Status.DEVICE_TYPE_MISMATCH STATUS_FILE_NOT_FOUND = Status.FILE_NOT_FOUND STATUS_FONT_TYPE_MISMATCH = Status.FONT_TYPE_MISMATCH STATUS_INVALID_CLUSTERS = Status.INVALID_CLUSTERS STATUS_INVALID_CONTENT = Status.INVALID_CONTENT STATUS_INVALID_DASH = Status.INVALID_DASH STATUS_INVALID_DSC_COMMENT = Status.INVALID_DSC_COMMENT STATUS_INVALID_FORMAT = Status.INVALID_FORMAT STATUS_INVALID_INDEX = Status.INVALID_INDEX STATUS_INVALID_MATRIX = Status.INVALID_MATRIX STATUS_INVALID_MESH_CONSTRUCTION = Status.INVALID_MESH_CONSTRUCTION STATUS_INVALID_PATH_DATA = Status.INVALID_PATH_DATA STATUS_INVALID_POP_GROUP = Status.INVALID_POP_GROUP STATUS_INVALID_RESTORE = Status.INVALID_RESTORE STATUS_INVALID_SIZE = Status.INVALID_SIZE STATUS_INVALID_SLANT = Status.INVALID_SLANT STATUS_INVALID_STATUS = Status.INVALID_STATUS STATUS_INVALID_STRIDE = Status.INVALID_STRIDE STATUS_INVALID_STRING = Status.INVALID_STRING STATUS_INVALID_VISUAL = Status.INVALID_VISUAL STATUS_INVALID_WEIGHT = Status.INVALID_WEIGHT STATUS_JBIG2_GLOBAL_MISSING = Status.JBIG2_GLOBAL_MISSING STATUS_LAST_STATUS = Status.LAST_STATUS STATUS_NEGATIVE_COUNT = Status.NEGATIVE_COUNT STATUS_NO_CURRENT_POINT = Status.NO_CURRENT_POINT STATUS_NO_MEMORY = Status.NO_MEMORY STATUS_NULL_POINTER = Status.NULL_POINTER STATUS_PATTERN_TYPE_MISMATCH = Status.PATTERN_TYPE_MISMATCH STATUS_READ_ERROR = Status.READ_ERROR STATUS_SUCCESS = Status.SUCCESS STATUS_SURFACE_FINISHED = Status.SURFACE_FINISHED STATUS_SURFACE_TYPE_MISMATCH = Status.SURFACE_TYPE_MISMATCH STATUS_TEMP_FILE_ERROR = Status.TEMP_FILE_ERROR STATUS_USER_FONT_ERROR = Status.USER_FONT_ERROR STATUS_USER_FONT_IMMUTABLE = Status.USER_FONT_IMMUTABLE STATUS_USER_FONT_NOT_IMPLEMENTED = Status.USER_FONT_NOT_IMPLEMENTED STATUS_WRITE_ERROR = Status.WRITE_ERROR SUBPIXEL_ORDER_BGR = SubpixelOrder.BGR SUBPIXEL_ORDER_DEFAULT = SubpixelOrder.DEFAULT SUBPIXEL_ORDER_RGB = SubpixelOrder.RGB SUBPIXEL_ORDER_VBGR = SubpixelOrder. VBGR SUBPIXEL_ORDER_VRGB = SubpixelOrder.VRGB SURFACE_OBSERVER_NORMAL = SurfaceObserverMode.NORMAL SURFACE_OBSERVER_RECORD_OPERATIONS = SurfaceObserverMode.RECORD_OPERATIONS SVG_VERSION_1_1 = SVGVersion.VERSION_1_1 SVG_VERSION_1_2 = SVGVersion.VERSION_1_2 TEXT_CLUSTER_FLAG_BACKWARD = TextClusterFlags.BACKWARD PDF_METADATA_TITLE = PDFMetadata.TITLE PDF_METADATA_AUTHOR = PDFMetadata.AUTHOR PDF_METADATA_SUBJECT = PDFMetadata.SUBJECT PDF_METADATA_KEYWORDS = PDFMetadata.KEYWORDS PDF_METADATA_CREATOR = PDFMetadata.CREATOR PDF_METADATA_CREATE_DATE = PDFMetadata.CREATE_DATE PDF_METADATA_MOD_DATE = PDFMetadata.MOD_DATE SVG_UNIT_USER = SVGUnit.USER SVG_UNIT_EM = SVGUnit.EM SVG_UNIT_EX = SVGUnit.EX SVG_UNIT_PX = SVGUnit.PX SVG_UNIT_IN = SVGUnit.IN SVG_UNIT_CM = SVGUnit.CM SVG_UNIT_MM = SVGUnit.MM SVG_UNIT_PT = SVGUnit.PT SVG_UNIT_PC = SVGUnit.PC SVG_UNIT_PERCENT = SVGUnit.PERCENT STATUS_TAG_ERROR = Status.TAG_ERROR STATUS_FREETYPE_ERROR = Status.FREETYPE_ERROR STATUS_WIN32_GDI_ERROR = Status.WIN32_GDI_ERROR STATUS_PNG_ERROR = Status.PNG_ERROR STATUS_DWRITE_ERROR = Status.DWRITE_ERROR STATUS_SVG_FONT_ERROR = Status.SVG_FONT_ERROR PDF_OUTLINE_FLAG_OPEN = PDFOutlineFlags.OPEN PDF_OUTLINE_FLAG_BOLD = PDFOutlineFlags.BOLD PDF_OUTLINE_FLAG_ITALIC = PDFOutlineFlags.ITALIC COLOR_MODE_DEFAULT = ColorMode.DEFAULT COLOR_MODE_NO_COLOR = ColorMode.NO_COLOR COLOR_MODE_COLOR = ColorMode.COLOR DITHER_NONE = Dither.NONE DITHER_DEFAULT = Dither.DEFAULT DITHER_FAST = Dither.FAST DITHER_GOOD = Dither.GOOD DITHER_BEST = Dither.BEST