""" Handles the creation of patterns and gradients """ from abc import ABC from typing import List, Optional, TYPE_CHECKING, Tuple, Union from .drawing import DeviceCMYK, DeviceGray, DeviceRGB, convert_to_device_color from .syntax import Name, PDFArray, PDFObject if TYPE_CHECKING: from .fpdf import FPDF class Pattern(PDFObject): """ Represents a PDF Pattern object. Currently, this class supports only "shading patterns" (pattern_type 2), using either a linear or radial gradient. Tiling patterns (pattern_type 1) are not yet implemented. """ def __init__(self, shading: Union["LinearGradient", "RadialGradient"]): super().__init__() self.type = Name("Pattern") # 1 for a tiling pattern or type 2 for a shading pattern: self.pattern_type = 2 self._shading = shading @property def shading(self): return f"{self._shading.get_shading_object().id} 0 R" class Type2Function(PDFObject): """Transition between 2 colors""" def __init__(self, color_1, color_2): super().__init__() # 0: Sampled function; 2: Exponential interpolation function; 3: Stitching function; 4: PostScript calculator function self.function_type = 2 self.domain = "[0 1]" self.c0 = f'[{" ".join(f"{c:.2f}" for c in color_1.colors)}]' self.c1 = f'[{" ".join(f"{c:.2f}" for c in color_2.colors)}]' self.n = 1 class Type3Function(PDFObject): """When multiple colors are used, a type 3 function is necessary to stitch type 2 functions together and define the bounds between each color transition""" def __init__(self, functions, bounds): super().__init__() # 0: Sampled function; 2: Exponential interpolation function; 3: Stitching function; 4: PostScript calculator function self.function_type = 3 self.domain = "[0 1]" self._functions = functions self.bounds = f"[{' '.join(f'{bound:.2f}' for bound in bounds)}]" self.encode = f"[{' '.join('0 1' for _ in functions)}]" self.n = 1 @property def functions(self): return f"[{' '.join(f'{f.id} 0 R' for f in self._functions)}]" class Shading(PDFObject): def __init__( self, shading_type: int, # 2 for axial shading, 3 for radial shading background: Optional[Union[DeviceRGB, DeviceGray, DeviceCMYK]], color_space: str, coords: List[int], function: Union[Type2Function, Type3Function], extend_before: bool, extend_after: bool, ): super().__init__() self.shading_type = shading_type self.background = ( f'[{" ".join(f"{c:.2f}" for c in background.colors)}]' if background else None ) self.color_space = Name(color_space) self.coords = coords self.function = f"{function.id} 0 R" self.extend = f'[{"true" if extend_before else "false"} {"true" if extend_after else "false"}]' class Gradient(ABC): def __init__(self, colors, background, extend_before, extend_after, bounds): self.color_space, self.colors = self._convert_colors(colors) self.background = None if background: self.background = ( convert_to_device_color(background) if isinstance(background, (str, DeviceGray, DeviceRGB, DeviceCMYK)) else convert_to_device_color(*background) ) if self.background and self.background.__class__.__name__ != self.color_space: raise ValueError( "The background color must be of the same color space as the gradient" ) self.extend_before = extend_before self.extend_after = extend_after self.bounds = ( bounds if bounds else [(i + 1) / (len(self.colors) - 1) for i in range(len(self.colors) - 2)] ) if len(self.bounds) != len(self.colors) - 2: raise ValueError( "Bounds array length must be two less than the number of colors" ) self.functions = self._generate_functions() self.pattern = Pattern(self) self._shading_object = None self.coords = None self.shading_type = 0 @classmethod def _convert_colors(cls, colors) -> Tuple[str, List]: color_list = [] if len(colors) < 2: raise ValueError("A gradient must have at least two colors") color_spaces = set() for color in colors: current_color = ( convert_to_device_color(color) if isinstance(color, (str, DeviceGray, DeviceRGB, DeviceCMYK)) else convert_to_device_color(*color) ) color_list.append(current_color) color_spaces.add(type(current_color).__name__) if len(color_spaces) == 1: return color_spaces.pop(), color_list if "DeviceCMYK" in color_spaces: raise ValueError("Can't mix CMYK with other color spaces.") # mix of DeviceGray and DeviceRGB converted = [] for color in color_list: if isinstance(color, DeviceGray): converted.append(DeviceRGB(color.g, color.g, color.g)) else: converted.append(color) return "DeviceRGB", converted def _generate_functions(self): if len(self.colors) < 2: raise ValueError("A gradient must have at least two colors") if len(self.colors) == 2: return [Type2Function(self.colors[0], self.colors[1])] number_of_colors = len(self.colors) functions = [] for i in range(number_of_colors - 1): functions.append(Type2Function(self.colors[i], self.colors[i + 1])) functions.append(Type3Function(functions[:], self.bounds)) return functions def get_shading_object(self): if not self._shading_object: self._shading_object = Shading( shading_type=self.shading_type, background=self.background, color_space=self.color_space, coords=PDFArray(self.coords), function=self.functions[-1], extend_before=self.extend_before, extend_after=self.extend_after, ) return self._shading_object def get_pattern(self): return self.pattern class LinearGradient(Gradient): def __init__( self, fpdf: "FPDF", from_x: int, from_y: int, to_x: int, to_y: int, colors: List, background=None, extend_before: bool = False, extend_after: bool = False, bounds: List[int] = None, ): """ A shading pattern that creates a linear (axial) gradient in a PDF. The gradient is defined by two points: (from_x, from_y) and (to_x, to_y), along which the specified colors are interpolated. Optionally, you can set a background color, extend the gradient beyond its start or end, and specify custom color stop positions via `bounds`. Args: fpdf (FPDF): The FPDF instance used for PDF generation. from_x (int or float): The x-coordinate of the starting point of the gradient, in user space units. from_y (int or float): The y-coordinate of the starting point of the gradient, in user space units. to_x (int or float): The x-coordinate of the ending point of the gradient, in user space units. to_y (int or float): The y-coordinate of the ending point of the gradient, in user space units. colors (List[str or Tuple[int, int, int]]): A list of colors along which the gradient will be interpolated. Colors may be given as hex strings (e.g., "#FF0000") or (R, G, B) tuples. background (str or Tuple[int, int, int], optional): A background color to use if the gradient does not fully cover the region it is applied to. Defaults to None (no background). extend_before (bool, optional): Whether to extend the first color beyond the starting point (from_x, from_y). Defaults to False. extend_after (bool, optional): Whether to extend the last color beyond the ending point (to_x, to_y). Defaults to False. bounds (List[float], optional): An optional list of floats in the range (0, 1) that represent gradient stops for color transitions. The number of bounds should be two less than the number of colors (for multi-color gradients). Defaults to None, which evenly distributes color stops. """ super().__init__(colors, background, extend_before, extend_after, bounds) coords = [from_x, fpdf.h - from_y, to_x, fpdf.h - to_y] self.coords = [f"{fpdf.k * c:.2f}" for c in coords] self.shading_type = 2 class RadialGradient(Gradient): def __init__( self, fpdf: "FPDF", start_circle_x: int, start_circle_y: int, start_circle_radius: int, end_circle_x: int, end_circle_y: int, end_circle_radius: int, colors: List, background=None, extend_before: bool = False, extend_after: bool = False, bounds: List[int] = None, ): """ A shading pattern that creates a radial (or circular/elliptical) gradient in a PDF. The gradient is defined by two circles (start and end). Colors are blended from the start circle to the end circle, forming a radial gradient. You can optionally set a background color, extend the gradient beyond its circles, and provide custom color stop positions via `bounds`. Args: fpdf (FPDF): The FPDF instance used for PDF generation. start_circle_x (int or float): The x-coordinate of the inner circle's center, in user space units. start_circle_y (int or float): The y-coordinate of the inner circle's center, in user space units. start_circle_radius (int or float): The radius of the inner circle, in user space units. end_circle_x (int or float): The x-coordinate of the outer circle's center, in user space units. end_circle_y (int or float): The y-coordinate of the outer circle's center, in user space units. end_circle_radius (int or float): The radius of the outer circle, in user space units. colors (List[str or Tuple[int, int, int]]): A list of colors along which the gradient will be interpolated. Colors may be given as hex strings (e.g., "#FF0000") or (R, G, B) tuples. background (str or Tuple[int, int, int], optional): A background color to display if the gradient does not fully cover the region it's applied to. Defaults to None (no background). extend_before (bool, optional): Whether to extend the gradient beyond the start circle. Defaults to False. extend_after (bool, optional): Whether to extend the gradient beyond the end circle. Defaults to False. bounds (List[float], optional): An optional list of floats in the range (0, 1) that represent gradient stops for color transitions. The number of bounds should be one less than the number of colors (for multi-color gradients). Defaults to None, which evenly distributes color stops. """ super().__init__(colors, background, extend_before, extend_after, bounds) coords = [ start_circle_x, fpdf.h - start_circle_y, start_circle_radius, end_circle_x, fpdf.h - end_circle_y, end_circle_radius, ] self.coords = [f"{fpdf.k * c:.2f}" for c in coords] self.shading_type = 3