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-rw-r--r--examples/highlight_outline.py79
1 files changed, 42 insertions, 37 deletions
diff --git a/examples/highlight_outline.py b/examples/highlight_outline.py
index a73b79b..f2e7f3e 100644
--- a/examples/highlight_outline.py
+++ b/examples/highlight_outline.py
@@ -7,44 +7,47 @@ from gerbonara import LayerStack
from gerbonara.graphic_objects import Line, Arc
from gerbonara.apertures import CircleAperture
from gerbonara.utils import MM
+from gerbonara.utils import rotate_point
def highlight_outline(input_dir, output_dir):
- #stack = LayerStack.from_directory(input_dir)
+ stack = LayerStack.from_directory(input_dir)
- #outline = []
- #for obj in stack.outline.objects:
- # if isinstance(obj, Line):
- # outline.append(obj)
-#
-# elif isinstance(obj, Arc):
-# outline += obj.approximate(0.1, 'mm')
-
- # FIXME test code
- print('<?xml version="1.0" encoding="utf-8"?>')
- print('<svg width="300mm" height="300mm" viewBox="0 0 300 300" xmlns="http://www.w3.org/2000/svg">')
- from gerbonara.utils import rotate_point
outline = []
- for i in range(16):
- for j in range(16):
- cx, cy = i*3, j*3
- w = i/8
- angle = j*2*math.pi/16
- x1, y1 = cx-w/2, cy
- x2, y2 = cx+w/2, cy
-
- x1, y1 = rotate_point(x1, y1, angle, cx, cy)
- x2, y2 = rotate_point(x2, y2, angle, cx, cy)
+ for obj in stack.outline.objects:
+ if isinstance(obj, Line):
+ outline.append(obj.converted('mm'))
- outline.append(Line(x1, y1, x2, y2, aperture=CircleAperture(1.0, unit=MM), unit=MM))
- print(f'<path style="stroke: red; stroke-width: 0.01mm;" d="M {x1} {y1} L {x2} {y2}"/>')
+ elif isinstance(obj, Arc):
+ outline += obj.converted('mm').approximate(0.1, 'mm')
- marker_angle = math.pi/4
- marker_spacing = 0.2
- marker_width = 0.01
+ # FIXME test code
+ #print('<?xml version="1.0" encoding="utf-8"?>')
+ #print('<svg width="300mm" height="300mm" viewBox="0 0 300 300" xmlns="http://www.w3.org/2000/svg">')
+ #outline = []
+ #for i in range(16):
+ # for j in range(16):
+ # cx, cy = i*3, j*3
+ # w = i/8
+ # angle = j*2*math.pi/16
+ # x1, y1 = cx-w/2, cy
+ # x2, y2 = cx+w/2, cy
+ #
+ # x1, y1 = rotate_point(x1, y1, angle, cx, cy)
+ # x2, y2 = rotate_point(x2, y2, angle, cx, cy)
+ #
+ # outline.append(Line(x1, y1, x2, y2, aperture=CircleAperture(1.0, unit=MM), unit=MM))
+ # print(f'<path style="stroke: red; stroke-width: 0.01mm;" d="M {x1} {y1} L {x2} {y2}"/>')
+
+ marker_angle = math.pi/3
+ marker_spacing = 2
+ marker_width = 0.1
marker_dx, marker_dy = math.sin(marker_angle)*marker_spacing, -math.cos(marker_angle)*marker_spacing
marker_nx, marker_ny = math.sin(marker_angle), math.cos(marker_angle)
+ ap = CircleAperture(0.1, unit=MM)
+ stack['top silk'].apertures.append(ap)
+
for line in outline:
cx, cy = (line.x1 + line.x2)/2, (line.y1 + line.y2)/2
dx, dy = line.x1 - cx, line.y1 - cy
@@ -55,7 +58,8 @@ def highlight_outline(input_dir, output_dir):
continue
cr = math.hypot(cx, cy)
- w = line.aperture.equivalent_width('mm')
+ #w = line.aperture.equivalent_width('mm')
+ w = 10
tl_x, tl_y = line.x1 + math.sin(angle)*w/2, line.y1 - math.cos(angle)*w/2
tr_x, tr_y = line.x2 + math.sin(angle)*w/2, line.y2 - math.cos(angle)*w/2
@@ -64,13 +68,11 @@ def highlight_outline(input_dir, output_dir):
tr = math.dist((tl_x, tl_y), (br_x, br_y))/2
- print(f'<path style="stroke: red; stroke-width: 0.01mm; fill: none;" d="M {tl_x} {tl_y} L {tr_x} {tr_y} L {br_x} {br_y} L {bl_x} {bl_y} Z"/>')
+ #print(f'<path style="stroke: red; stroke-width: 0.01mm; fill: none;" d="M {tl_x} {tl_y} L {tr_x} {tr_y} L {br_x} {br_y} L {bl_x} {bl_y} Z"/>')
- rot_cx, rot_cy = rotate_point(cx, cy, -marker_angle)
- offx = (rot_cy % marker_spacing) / marker_spacing
n = math.ceil(tr/marker_spacing)
for i in range(-n, n+1):
- px, py = cx + (i+offx)*marker_dx, cy + (i+offx)*marker_dy
+ px, py = cx + i*marker_dx, cy + i*marker_dy
lx1, ly1 = px + tr*marker_nx, py + tr*marker_ny
lx2, ly2 = px - tr*marker_nx, py - tr*marker_ny
@@ -80,7 +82,7 @@ def highlight_outline(input_dir, output_dir):
#print(f'<circle style="fill: blue; stroke: none;" r="{marker_spacing/2}" cx="{px}" cy="{py}"/>')
def clip_line_point(x1, y1, x2, y2, xabs, yabs):
- print(x1, y1, x2, y2, end=' -> ', file=sys.stderr)
+ #print(x1, y1, x2, y2, end=' -> ', file=sys.stderr)
if x2 != x1:
a = (y2 - y1) / (x2 - x1)
x2 = min(xabs, max(-xabs, x2))
@@ -97,7 +99,7 @@ def highlight_outline(input_dir, output_dir):
elif abs(y1) > yabs:
return None
- print(x1, y1, x2, y2, file=sys.stderr)
+ #print(x1, y1, x2, y2, file=sys.stderr)
return x1, y1, x2, y2
if not (foo := clip_line_point(lx1-cx, ly1-cy, lx2-cx, ly2-cy, r, w/2)):
@@ -113,7 +115,9 @@ def highlight_outline(input_dir, output_dir):
lx1, ly1 = rotate_point(lx1, ly1, -angle, cx, cy)
lx2, ly2 = rotate_point(lx2, ly2, -angle, cx, cy)
- print(f'<path style="stroke: blue; stroke-width: 0.01mm; opacity: 0.2;" d="M {lx1} {ly1} L {lx2} {ly2}"/>')
+ stack['top silk'].objects.append(Line(lx1, ly1, lx2, ly2, unit=MM, aperture=ap, polarity_dark=True))
+
+ #print(f'<path style="stroke: blue; stroke-width: {marker_width}mm; opacity: 0.2;" d="M {lx1} {ly1} L {lx2} {ly2}"/>')
#delta_a = marker_angle - angle
#ex, ey = px, py
@@ -121,7 +125,8 @@ def highlight_outline(input_dir, output_dir):
#print(delta_a, file=sys.stderr)
# delta_a + math.pi/2
- print('</svg>')
+ stack.save_to_directory(output_dir)
+ #print('</svg>')
if __name__ == '__main__':
import argparse