import tempfile
import os.path as path
from pathlib import Path
import textwrap
import subprocess
import functools
import os
import base64
import re
import sys
import warnings
import shutil
from zipfile import ZipFile, is_zipfile
from pathlib import Path
from lxml import etree
import numpy as np
import click
import gerbonara as gn
@click.group()
def cli():
pass
@cli.command()
@click.argument('input_gerbers', type=click.Path(exists=True, path_type=Path))
@click.argument('input_svg', type=click.Path(exists=True, dir_okay=False, file_okay=True, allow_dash=True, path_type=Path))
@click.argument('output_gerbers', type=click.Path(allow_dash=True, path_type=Path))
@click.option('--dilate', default=0.1, type=float, help='Default dilation for subtraction operations in mm')
@click.option('--zip/--no-zip', 'is_zip', default=None, help='zip output files. Default: zip if output path ends with ".zip" or when outputting to stdout.')
@click.option('--curve-tolerance', type=float, help='Tolerance for curve flattening in mm')
@click.option('--no-subtract', 'no_subtract', flag_value=True, help='Disable subtraction')
@click.option('--subtract', help='Use user subtraction script from argument')
@click.option('--trace-space', type=float, default=0.1, help='passed through to svg-flatten')
@click.option('--vectorizer', help='passed through to svg-flatten')
@click.option('--vectorizer-map', help='passed through to svg-flatten')
@click.option('--preserve-aspect-ratio', help='PNG/JPG files only: passed through to svg-flatten')
@click.option('--exclude-groups', help='passed through to svg-flatten')
def paste(input_gerbers, input_svg, output_gerbers, is_zip,
dilate, curve_tolerance, no_subtract, subtract,
preserve_aspect_ratio,
trace_space, vectorizer, vectorizer_map, exclude_groups):
""" Render vector data and raster images from SVG file into gerbers. """
subtract_map = parse_subtract_script('' if no_subtract else subtract, dilate)
stack = gn.LayerStack.open(input_gerbers, lazy=True)
(bb_min_x, bb_min_y), (bb_max_x, bb_max_y) = bounds = stack.board_bounds()
output_is_zip = output_gerbers.name.lower().endswith('.zip') if is_zip is None else is_zip
# Create output dir if it does not exist yet. Do this now so we fail early
if not output_is_zip:
output_gerbers.mkdir(exist_ok=True)
@functools.lru_cache()
def do_dilate(layer, amount):
return dilate_gerber(layer, bounds, amount, curve_tolerance)
for (side, use), layer in stack.graphic_layers.items():
overlay_grb = svg_to_gerber(input_svg,
trace_space=trace_space, vectorizer=vectorizer, vectorizer_map=vectorizer_map,
exclude_groups=exclude_groups, curve_tolerance=curve_tolerance,
preserve_aspect_ratio=preserve_aspect_ratio,
outline_mode=(use == 'outline'),
only_groups=f'g-{side}-{use}')
if not overlay_grb:
print(f'Overlay {side} {use} layer is empty. Skipping.')
continue
# only open lazily loaded layer if we need it. Replace lazy wrapper in stack with loaded layer.
stack.graphic_layers[(side, use)] = layer = layer.instance
# move overlay from svg origin to gerber origin
overlay_grb.offset(bb_min_x, bb_min_y)
# dilated subtract layers on top of overlay
if side in ('top', 'bottom'): # do not process subtraction scripts for inner layers
dilations = subtract_map.get(use, [])
for d_layer, amount in dilations:
dilated = do_dilate(stack[(side, d_layer)], amount)
layer.merge(dilated, mode='below', keep_settings=True)
# overlay on bottom
layer.merge(overlay_grb, mode='below', keep_settings=True)
if output_is_zip:
stack.save_to_zipfile(output_gerbers)
else:
stack.save_to_directory(output_gerbers)
@cli.command()
@click.argument('input_gerbers', type=click.Path(exists=True))
@click.argument('output_svg', required=False)
@click.option('-t' ,'--top', help='Render board top side.', is_flag=True)
@click.option('-b' ,'--bottom', help='Render board bottom side.', is_flag=True)
@click.option('-f' ,'--force', help='Overwrite existing output file when autogenerating file name.', is_flag=True)
@click.option('--vector/--raster', help='Embed preview renders into output file as SVG vector graphics instead of rendering them to PNG bitmaps. The resulting preview may slow down your SVG editor.')
@click.option('--raster-dpi', type=float, default=300.0, help='DPI for rastering preview')
def template(input_gerbers, output_svg, top, bottom, force, vector, raster_dpi):
''' Generate SVG template for gerbolyze paste from gerber files.
INPUT may be a gerber file, directory of gerber files or zip file with gerber files
'''
source = Path(input_gerbers)
ttype = 'top' if top else 'bottom'
if (bool(top) + bool(bottom)) != 1:
raise click.UsageError('Excactly one of --top or --bottom must be given.')
if output_svg is None:
# autogenerate output file name if none is given:
# /path/to/gerber/dir -> /path/to/gerber/dir.preview-{top|bottom}.svg
# /path/to/gerbers.zip -> /path/to/gerbers.zip.preview-{top|bottom}.svg
# /path/to/single/file.grb -> /path/to/single/file.grb.preview-{top|bottom}.svg
output_svg = source.parent / f'{source.name}.template-{ttype}.svg'
click.echo(f'Writing output to {output_svg}')
if output_svg.exists() and not force:
raise UsageError(f'Autogenerated output file already exists. Please remote first, or use --force, or '
'explicitly give an output path.')
else:
output_svg = Path(output_svg)
stack = gn.LayerStack.open(source, lazy=True)
svg = stack.to_pretty_svg(side=('top' if top else 'bottom'), inkscape=True)
template_layers = [ f'{ttype}-{use}' for use in [ 'copper', 'mask', 'silk' ] ] + ['mechanical outline']
silk = template_layers[-2]
if vector:
output_svg.write_text(create_template_from_svg(svg, template_layers, current_layer=silk))
else:
with tempfile.NamedTemporaryFile(suffix='.svg') as temp_svg, \
tempfile.NamedTemporaryFile(suffix='.png') as temp_png:
Path(temp_svg.name).write_text(str(svg))
run_resvg(temp_svg.name, temp_png.name, dpi=f'{raster_dpi:.0f}')
output_svg.write_text(template_svg_for_png(stack.board_bounds(), Path(temp_png.name).read_bytes(),
template_layers, current_layer=silk))
class ClickSizeParam(click.ParamType):
name = 'Size'
def convert(self, value, param, ctx):
if isinstance(value, tuple):
return value
if not (m := re.match(r'([0-9]+\.?[0-9]*)(mm|cm|in)?[xX*/,×]([0-9]+\.?[0-9]*)(mm|cm|in)?', value)):
self.fail('Size must have format [width]x[height][unit]. The unit can be mm, cm or in. The unit is optional and defaults to mm.', param=param, ctx=ctx)
w, unit1, h, unit2 = m.groups()
if unit1 and unit2 and unit1 != unit2:
self.fail('Width and height must use the same unit. Two different units given for width and height: width is in {unit1}, and height is in {unit2}.', param=param, ctx=ctx)
unit = (unit1 or unit2) or 'mm'
return float(w), float(h), unit
@cli.command()
@click.argument('output_svg', type=click.Path(dir_okay=False, writable=True, allow_dash=True))
@click.option('--size', type=ClickSizeParam(), default='100x100mm', help='PCB size in [width]x[height][unit] format. Units can be cm, mm or in, when no unit is given, defaults to mm. When no size is given, defaults to 100x100mm.')
@click.option('--force', is_flag=True, help='Overwrite output file without asking if it exists.')
@click.option('-n', '--copper-layers', default=2, type=int, help='Number of copper layers to generate.')
@click.option('--no-default-layers', is_flag=True, help='Do not generate default layers.')
@click.option('-l', '--layer', multiple=True, help='Add given layer to the top of the output layer stack. Can be given multiple times.')
def empty_template(output_svg, size, force, copper_layers, no_default_layers, layer):
if output_svg == '-':
out = sys.stdout
else:
out = Path(output_svg)
if out.exists():
if not force and not click.confirm(f'Output file "{out}" already exists. Do you want to overwrite it?'):
raise click.ClickException(f'Output file "{out}" already exists, exiting.')
out = out.open('w')
layers = layer or []
current_layer = None
if not no_default_layers:
layers += ['top paste', 'top silk', 'top mask']
if copper_layers > 0:
current_layer = 'top copper'
inner = [ 'inner{i} copper' for i in range(max(0, copper_layers-2)) ]
layers += ['top copper', *inner, 'bottom copper'][:copper_layers]
layers += ['bottom mask', 'bottom silk', 'bottom paste']
layers += ['outline', 'plated drill', 'nonplated drill', 'comments']
if layers and current_layer is None:
current_layer = layers[0]
out.write(empty_pcb_template(size, layers, current_layer))
out.flush()
if output_svg != '-':
out.close()
@cli.command()
@click.argument('input_svg', type=click.Path(exists=True, path_type=Path))
@click.argument('output_gerbers', type=click.Path(path_type=Path))
@click.option('-n', '--naming-scheme', default='kicad', type=click.Choice(['kicad', 'altium']), help='Naming scheme for gerber output file names.')
@click.option('--zip/--no-zip', 'is_zip', default=None, help='zip output files. Default: zip if output path ends with ".zip" or when outputting to stdout.')
@click.option('--separate-drill-file/--composite-drill-file', 'separate_drill', help='Use Altium composite Excellon drill file format (default)')
@click.option('--dilate', default=0.1, type=float, help='Default dilation for subtraction operations in mm')
@click.option('--curve-tolerance', type=float, help='Tolerance for curve flattening in mm')
@click.option('--no-subtract', 'no_subtract', flag_value=True, help='Disable subtraction')
@click.option('--subtract', help='Use user subtraction script from argument (see description above)')
@click.option('--trace-space', type=float, default=0.1, help='passed through to svg-flatten')
@click.option('--vectorizer', help='passed through to svg-flatten')
@click.option('--vectorizer-map', help='passed through to svg-flatten')
@click.option('--exclude-groups', help='passed through to svg-flatten')
@click.option('--pattern-complete-tiles-only', is_flag=True, help='passed through to svg-flatten')
@click.option('--use-apertures-for-patterns', is_flag=True, help='passed through to svg-flatten')
def convert(input_svg, output_gerbers, is_zip, dilate, curve_tolerance, no_subtract, subtract, trace_space, vectorizer,
vectorizer_map, exclude_groups, separate_drill, naming_scheme,
pattern_complete_tiles_only, use_apertures_for_patterns):
''' Convert SVG file directly to gerbers.
Unlike `gerbolyze paste`, this does not add the SVG's contents to existing gerbers. It allows you to directly create
PCBs using Inkscape similar to PCBModE.
'''
subtract_map = parse_subtract_script('' if no_subtract else subtract, dilate, default_script=DEFAULT_CONVERT_SUB_SCRIPT)
output_is_zip = output_gerbers.name.lower().endswith('.zip') if is_zip is None else is_zip
stack = gn.LayerStack({}, [], board_name=input_svg.stem, original_path=input_svg)
for group_id, label in get_layers_from_svg(input_svg.read_text()):
if not group_id or not label or 'no export' in label:
continue
if label == 'outline':
side, use = 'mechanical', 'outline'
elif label == 'comments':
side, use = 'other', 'comments'
elif len(label.split()) != 2:
warnings.warn('Unknown layer {label}')
continue
else:
side, use = label.split()
grb = svg_to_gerber(input_svg,
trace_space=trace_space, vectorizer=vectorizer, vectorizer_map=vectorizer_map,
exclude_groups=exclude_groups, curve_tolerance=curve_tolerance, only_groups=group_id,
pattern_complete_tiles_only=pattern_complete_tiles_only,
use_apertures_for_patterns=(use_apertures_for_patterns and use not in ('outline', 'drill')),
outline_mode=(use == 'outline' or use == 'drill'))
grb.original_path = Path()
if use == 'drill':
if side == 'plated':
stack.drill_pth = grb.to_excellon(plated=True)
elif side == 'nonplated':
stack.drill_npth = grb.to_excellon(plated=False)
else:
warnings.warn(f'Invalid drill layer type "{side}". Must be one of "plated" or "nonplated"')
else:
stack.graphic_layers[(side, use)] = grb
bounds = stack.board_bounds()
@functools.lru_cache()
def do_dilate(layer, amount):
return dilate_gerber(layer, bounds, amount, curve_tolerance)
for (side, use), layer in stack.graphic_layers.items():
# dilated subtract layers on top of overlay
if side in ('top', 'bottom'): # do not process subtraction scripts for inner layers
dilations = subtract_map.get(use, [])
for d_layer, amount in dilations:
d_layer = stack.graphic_layers[(side, d_layer)]
dilated = do_dilate(d_layer, amount)
layer.merge(dilated, mode='above', keep_settings=True)
if not separate_drill:
print('Merging drill layers...')
stack.merge_drill_layers()
naming_scheme = getattr(gn.layers.NamingScheme, naming_scheme)
if output_is_zip:
stack.save_to_zipfile(output_gerbers, naming_scheme=naming_scheme)
else:
stack.save_to_directory(output_gerbers, naming_scheme=naming_scheme)
# Subtraction script handling
#============================
DEFAULT_SUB_SCRIPT = '''
out.silk -= in.mask
out.silk -= in.silk+0.5
out.mask -= in.mask+0.5
out.copper -= in.copper+0.5
'''
DEFAULT_CONVERT_SUB_SCRIPT = '''
out.silk -= in.mask
'''
def parse_subtract_script(script, default_dilation=0.1, default_script=DEFAULT_SUB_SCRIPT):
if script is None:
script = default_script
subtract_script = {}
lines = script.replace(';', '\n').splitlines()
for line in lines:
line = line.strip()
if not line or line.startswith('#'):
continue
line = line.lower()
line = re.sub(r'\s', '', line)
# out.copper -= in.copper+0.1
varname = r'([a-z]+\.[a-z]+)'
floatnum = r'([+-][.0-9]+)'
match = re.fullmatch(fr'{varname}-={varname}{floatnum}?', line)
if not match:
raise ValueError(f'Cannot parse line: {line}')
out_var, in_var, dilation = match.groups()
if not out_var.startswith('out.') or not in_var.startswith('in.'):
raise ValueError('All left-hand side values must be outputs, right-hand side values must be inputs.')
_out, _, out_layer = out_var.partition('.')
_in, _, in_layer = in_var.partition('.')
dilation = float(dilation) if dilation else default_dilation
subtract_script[out_layer] = subtract_script.get(out_layer, []) + [(in_layer, dilation)]
return subtract_script
# Parameter parsing foo
#======================
def parse_bbox(bbox):
if not bbox:
return None
elems = [ int(elem) for elem in re.split('[,/ ]', bbox) ]
if len(elems) not in (2, 4):
raise click.BadParameter(
'--bbox must be either two floating-point values like: w,h or four like: x,y,w,h')
elems = [ float(e) for e in elems ]
if len(elems) == 2:
bounds = [0, 0, *elems]
else:
bounds = elems
# now transform bounds to the format pcb-tools uses. Instead of (x, y, w, h) or even (x1, y1, x2, y2), that
# is ((x1, x2), (y1, y2)
x, y, w, h = bounds
return ((x, x+w), (y, y+h))
# Utility foo
# ===========
def run_resvg(input_file, output_file, **resvg_args):
args = []
for key, value in resvg_args.items():
if value is not None:
if value is False:
continue
args.append(f'--{key.replace("_", "-")}')
if value is not True:
args.append(value)
args += [input_file, output_file]
# By default, try a number of options:
candidates = [
# somewhere in $PATH
'resvg',
'wasi-resvg',
# in user-local cargo installation
Path.home() / '.cargo' / 'bin' / 'resvg',
# wasi-resvg in user-local pip installation
Path.home() / '.local' / 'bin' / 'wasi-resvg',
# next to our current python interpreter (e.g. in virtualenv)
str(Path(sys.executable).parent / 'wasi-resvg')
]
# if RESVG envvar is set, try that first.
if 'RESVG' in os.environ:
candidates = [os.environ['RESVG'], *candidates]
for candidate in candidates:
try:
res = subprocess.run([candidate, *args], check=True)
print('used resvg:', candidate)
break
except FileNotFoundError:
continue
else:
raise SystemError('resvg executable not found')
def calculate_apertureless_bounding_box(cam):
''' pcb-tools'es default bounding box function returns the bounding box of the primitives including apertures (i.e.
line widths). For determining a board's size from the outline layer, we want the bounding box disregarding
apertures.
'''
min_x = min_y = 1000000
max_x = max_y = -1000000
for prim in cam.primitives:
bounds = prim.bounding_box_no_aperture
min_x = min(bounds[0][0], min_x)
max_x = max(bounds[0][1], max_x)
min_y = min(bounds[1][0], min_y)
max_y = max(bounds[1][1], max_y)
return ((min_x, max_x), (min_y, max_y))
# SVG export
#===========
def template_layer(name):
return f''
def template_svg_for_png(bounds, png_data, extra_layers, current_layer):
(x1, y1), (x2, y2) = bounds
w_mm, h_mm = (x2 - x1), (y2 - y1)
extra_layers = "\n ".join(template_layer(name) for name in extra_layers)
# we set up the viewport such that document dimensions = document units = mm
template = f'''
'''
return textwrap.dedent(template)
def empty_pcb_template(size, extra_layers, current_layer):
w, h, unit = size
extra_layers = "\n ".join(template_layer(name) for name in extra_layers)
current_layer = f'' if current_layer else ''
# we set up the viewport such that document dimensions = document units = [unit]
template = f'''
'''
return textwrap.dedent(template)
MM_PER_INCH = 25.4
def create_template_from_svg(svg, extra_layers, current_layer):
view, *layers = svg.children
view.attrs['inkscape__current_layer'] = f'g-{current_layer.lower().replace(" ", "-")}'
extra_layers = [ template_layer(name) for name in extra_layers ]
svg.children = [ view, *extra_layers, gn.utils.Tag('g', layers, inkscape__label='Preview', sodipodi__insensitive='true',
inkscape__groupmode='layer', style='opacity:0.5') ]
return str(svg)
# SVG/gerber import
#==================
def dilate_gerber(layer, bounds, dilation, curve_tolerance):
with tempfile.NamedTemporaryFile(suffix='.svg') as temp_svg:
Path(temp_svg.name).write_text(str(layer.instance.to_svg(force_bounds=bounds, fg='white')))
# dilate & render back to gerber
# NOTE: Maybe reconsider or nicely document dilation semantics ; It is weird that negative dilations affect
# clear color and positive affects dark colors
out = svg_to_gerber(temp_svg.name, dilate=-dilation, curve_tolerance=curve_tolerance)
return out
def svg_to_gerber(infile, outline_mode=False, **kwargs):
infile = Path(infile)
args = [ '--format', ('gerber-outline' if outline_mode else 'gerber'),
'--precision', '6', # intermediate file, use higher than necessary precision
]
for k, v in kwargs.items():
if v:
args.append('--' + k.replace('_', '-'))
if not isinstance(v, bool):
args.append(str(v))
with tempfile.NamedTemporaryFile(suffix='.gbr') as temp_gbr:
args += [str(infile), str(temp_gbr.name)]
print(' '.join(args))
if 'SVG_FLATTEN' in os.environ:
subprocess.run([os.environ['SVG_FLATTEN'], *args], check=True)
print('used svg-flatten at $SVG_FLATTEN')
else:
# By default, try four options:
for candidate in [
# somewhere in $PATH
'svg-flatten',
None, # direct WASI import
'wasi-svg-flatten',
# in user-local pip installation
Path.home() / '.local' / 'bin' / 'svg-flatten',
Path.home() / '.local' / 'bin' / 'wasi-svg-flatten',
# next to our current python interpreter (e.g. in virtualenv)
str(Path(sys.executable).parent / 'svg-flatten'),
str(Path(sys.executable).parent / 'wasi-svg-flatten'),
# next to this python source file in the development repo
str(Path(__file__).parent.parent / 'svg-flatten' / 'build' / 'svg-flatten') ]:
try:
if candidate is None:
import svg_flatten_wasi
svg_flatten_wasi.run_svg_flatten.callback(args[-2], args[-1], args[:-2], no_usvg=False)
print('used svg_flatten_wasi python package')
else:
subprocess.run([candidate, *args], check=True)
print('used svg-flatten at', candidate)
break
except (FileNotFoundError, ModuleNotFoundError):
continue
else:
raise SystemError('svg-flatten executable not found')
return gn.rs274x.GerberFile.open(temp_gbr.name)
def get_layers_from_svg(svg_data):
svg = etree.fromstring(svg_data.encode('utf-8'))
SVG_NS = '{http://www.w3.org/2000/svg}'
INKSCAPE_NS = '{http://www.inkscape.org/namespaces/inkscape}'
# find groups
for group in svg.findall(SVG_NS+'g'):
yield group.get('id'), group.get(INKSCAPE_NS+'label')
if __name__ == '__main__':
cli()