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#!/usr/bin/env python
# -*- coding: utf-8 -*-

# Copyright 2019 Hiroshi Murayama <opiopan@gmail.com>
# Copyright 2022 Jan Sebastian Götte <gerbonara@jaseg.de>

import warnings
import contextlib
import math
from dataclasses import dataclass, fields

from .expression import Expression, UnitExpression, ConstantExpression, expr

from .. import graphic_primitives as gp
from .. import graphic_objects as go
from ..utils import rotate_point, LengthUnit


def point_distance(a, b):
    x1, y1 = a
    x2, y2 = b
    return math.sqrt((x2 - x1)**2 + (y2 - y1)**2)


# we make our own here instead of using math.degrees to make sure this works with expressions, too.
def deg_to_rad(a):
    return a * (math.pi / 180)


def rad_to_deg(a):
    return a * (180 / math.pi)


@dataclass(frozen=True, slots=True)
class Primitive:
    unit: LengthUnit
    exposure : Expression

    def __post_init__(self):
        for field in fields(self):
            if field.type == UnitExpression:
                value = getattr(self, field.name)
                if not isinstance(value, UnitExpression):
                    value = UnitExpression(expr(value), self.unit)
                object.__setattr__(self, field.name, value)
            elif field.type == Expression:
                object.__setattr__(self, field.name, expr(getattr(self, field.name)))

    def to_gerber(self, unit=None):
        return f'{self.code},' + ','.join(
                getattr(self, name).to_gerber(unit) for name in type(self).__annotations__)

    def __str__(self):
        attrs = ','.join(str(getattr(self, name)).strip('<>') for name in type(self).__annotations__)
        return f'<{type(self).__name__} {attrs}>'

    def __repr__(self):
        return str(self)

    @classmethod
    def from_arglist(kls, arglist):
        return kls(*arglist)

    class Calculator:
        def __init__(self, instance, variable_binding={}, unit=None):
            self.instance = instance
            self.variable_binding = variable_binding
            self.unit = unit

        def __enter__(self):
            return self

        def __exit__(self, _type, _value, _traceback):
            pass

        def __getattr__(self, name):
            return getattr(self.instance, name).calculate(self.variable_binding, self.unit)

        def __call__(self, expr):
            return expr.calculate(self.variable_binding, self.unit)


@dataclass(frozen=True, slots=True)
class Circle(Primitive):
    code = 1
    diameter : UnitExpression
    # center x/y
    x : UnitExpression
    y : UnitExpression
    rotation : Expression = 0

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            x, y = rotate_point(calc.x, calc.y, -(deg_to_rad(calc.rotation) + rotation), 0, 0)
            x, y = x+offset[0], y+offset[1]
            return [ gp.Circle(x, y, calc.diameter/2, polarity_dark=(bool(calc.exposure) == polarity_dark)) ]

    def dilated(self, offset, unit):
        return replace(self, diameter=self.diameter + UnitExpression(offset, unit))

    def scaled(self, scale):
        return replace(self, x=self.x * UnitExpression(scale), y=self.y * UnitExpression(scale),
                       diameter=self.diameter * UnitExpression(scale))


@dataclass(frozen=True, slots=True)
class VectorLine(Primitive):
    code = 20
    width : UnitExpression
    start_x : UnitExpression
    start_y : UnitExpression
    end_x : UnitExpression
    end_y : UnitExpression
    rotation : Expression = 0

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            center_x = (calc.end_x + calc.start_x) / 2
            center_y = (calc.end_y + calc.start_y) / 2
            delta_x = calc.end_x - calc.start_x
            delta_y = calc.end_y - calc.start_y
            length = point_distance((calc.start_x, calc.start_y), (calc.end_x, calc.end_y))

            center_x, center_y = rotate_point(center_x, center_y, -(deg_to_rad(calc.rotation) + rotation), 0, 0)
            center_x, center_y = center_x+offset[0], center_y+offset[1]
            rotation += deg_to_rad(calc.rotation) + math.atan2(delta_y, delta_x)

            return [ gp.Rectangle(center_x, center_y, length, calc.width, rotation=rotation,
                        polarity_dark=(bool(calc.exposure) == polarity_dark)) ]

    def dilated(self, offset, unit):
        return replace(self, width=self.width + UnitExpression(2*offset, unit))

    def scaled(self, scale):
        return replace(self, 
                       start_x=self.start_x * UnitExpression(scale),
                       start_y=self.start_y * UnitExpression(scale),
                       end_x=self.end_x * UnitExpression(scale),
                       end_y=self.end_y * UnitExpression(scale))


@dataclass(frozen=True, slots=True)
class CenterLine(Primitive):
    code = 21
    width : UnitExpression
    height : UnitExpression
    # center x/y
    x : UnitExpression = 0
    y : UnitExpression = 0
    rotation : Expression = 0

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            rotation += deg_to_rad(calc.rotation)
            x, y = gp.rotate_point(calc.x, calc.y, -rotation, 0, 0)
            x, y = x+offset[0], y+offset[1]
            w, h = calc.width, calc.height

            return [ gp.Rectangle(x, y, w, h, rotation, polarity_dark=(bool(calc.exposure) == polarity_dark)) ]

    def dilated(self, offset, unit):
        return replace(self, width=self.width + UnitExpression(2*offset, unit))

    def scaled(self, scale):
        return replace(self, 
                       width=self.width * UnitExpression(scale),
                       height=self.height * UnitExpression(scale),
                       x=self.x * UnitExpression(scale),
                       y=self.y * UnitExpression(scale))
            

@dataclass(frozen=True, slots=True)
class Polygon(Primitive):
    code = 5
    n_vertices : Expression
    # center x/y
    x : UnitExpression
    y : UnitExpression
    diameter : UnitExpression
    rotation : Expression = 0

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            rotation += deg_to_rad(calc.rotation)
            x, y = rotate_point(calc.x, calc.y, -rotation, 0, 0)
            x, y = x+offset[0], y+offset[1]
            return [ gp.ArcPoly.from_regular_polygon(calc.x, calc.y, calc.diameter/2, calc.n_vertices, rotation,
                        polarity_dark=(bool(calc.exposure) == polarity_dark)) ]

    def dilated(self, offset, unit):
        return replace(self, diameter=self.diameter + UnitExpression(2*offset, unit))

    def scale(self, scale):
        return replace(self,
                       diameter=self.diameter * UnitExpression(scale),
                       x=self.x * UnitExpression(scale),
                       y=self.y * UnitExpression(scale))
            

@dataclass(frozen=True, slots=True)
class Thermal(Primitive):
    code = 7
    # center x/y
    x : UnitExpression
    y : UnitExpression
    d_outer : UnitExpression
    d_inner : UnitExpression
    gap_w : UnitExpression
    rotation : Expression = 0

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            rotation += deg_to_rad(calc.rotation)
            x, y = rotate_point(calc.x, calc.y, -rotation, 0, 0)
            x, y = x+offset[0], y+offset[1]

            dark = (bool(calc.exposure) == polarity_dark)

            return [
                    gp.Circle(x, y, calc.d_outer/2, polarity_dark=dark),
                    gp.Circle(x, y, calc.d_inner/2, polarity_dark=not dark),
                    gp.Rectangle(x, y, d_outer, gap_w, rotation=rotation, polarity_dark=not dark),
                    gp.Rectangle(x, y, gap_w, d_outer, rotation=rotation, polarity_dark=not dark),
                    ]

    def dilate(self, offset, unit):
        # I'd rather print a warning and produce graphically slightly incorrect output in these few cases here than
        # producing macros that may evaluate to primitives with negative values.
        warnings.warn('Attempted dilation of macro aperture thermal primitive. This is not supported.')

    def scale(self, scale):
        return replace(self, 
                       d_outer=self.d_outer * UnitExpression(scale),
                       d_inner=self.d_inner * UnitExpression(scale),
                       gap_w=self.gap_w * UnitExpression(scale),
                       x=self.x * UnitExpression(scale),
                       y=self.y * UnitExpression(scale))


@dataclass(frozen=True, slots=True)
class Outline(Primitive):
    code = 4
    length: Expression
    coords: tuple
    rotation: Expression = 0

    def __post_init__(self):
        if self.length is None:
            object.__setattr__(self, 'length', expr(len(self.coords)//2-1))
        else:
            object.__setattr__(self, 'length', expr(self.length))
        object.__setattr__(self, 'rotation', expr(self.rotation))
        object.__setattr__(self, 'exposure', expr(self.exposure))

        if self.length.calculate() != len(self.coords)//2-1:
            raise ValueError('length must exactly equal number of segments, which is the number of points minus one')

        if self.coords[-2:] != self.coords[:2]:
            raise ValueError('Last point must equal first point')

        object.__setattr__(self, 'coords', tuple(
            UnitExpression(coord, self.unit) for coord in self.coords))

    @property
    def points(self):
        for x, y in zip(self.coords[0::2], self.coords[1::2]):
            yield x, y

    @classmethod
    def from_arglist(kls, arglist):
        if len(arglist[3:]) % 2 == 0:
            return kls(unit=arglist[0], exposure=arglist[1], length=arglist[2], coords=arglist[3:], rotation=0)
        else:
            return kls(unit=arglist[0], exposure=arglist[1], length=arglist[2], coords=arglist[3:-1], rotation=arglist[-1])

    def __str__(self):
        return f'<Outline {len(self.coords)} points>'

    def to_gerber(self, unit=None):
        coords = ','.join(coord.to_gerber(unit) for coord in self.coords)
        return f'{self.code},{self.exposure.to_gerber()},{len(self.coords)-1},{coords},{self.rotation.to_gerber()}'

    def to_graphic_primitives(self, offset, rotation, variable_binding={}, unit=None, polarity_dark=True):
        with self.Calculator(self, variable_binding, unit) as calc:
            rotation += deg_to_rad(calc.rotation)
            bound_coords = [ rotate_point(calc(x), calc(y), -rotation, 0, 0) for x, y in self.points ]
            bound_coords = [ (x+offset[0], y+offset[1]) for x, y in bound_coords ]
            bound_radii = [None] * len(bound_coords)
            return [gp.ArcPoly(bound_coords, bound_radii, polarity_dark=(bool(calc.exposure) == polarity_dark))]

    def dilated(self, offset, unit):
        # we would need a whole polygon offset/clipping library here
        warnings.warn('Attempted dilation of macro aperture outline primitive. This is not supported.')

    def scaled(self, scale):
        return replace(self, coords=tuple(x*scale for x in self.coords))


@dataclass(frozen=True, slots=True)
class Comment:
    code = 0
    comment: str

    def to_gerber(self, unit=None):
        return f'0 {self.comment}'

    def dilated(self, offset, unit):
        return self

    def scaled(self, scale):
        return self


PRIMITIVE_CLASSES = {
    **{cls.code: cls for cls in [
        Comment,
        Circle,
        VectorLine,
        CenterLine,
        Outline,
        Polygon,
        Thermal,
    ]},
    # alternative codes
    2: VectorLine,
}