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#!/usr/bin/env python3
# SPDX-FileCopyrightText: 2020 Efabless Corporation
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# SPDX-License-Identifier: Apache-2.0
#
# check_density.py ---
#
# Run density checks on a design (from GDS, after running fill generation).
#
import sys
import os
import re
import select
import subprocess
def usage():
print("Usage:")
print("check_density.py [<gds_file_name>] [-keep]")
print("")
print("where:")
print(" <gds_file_name> is the path to the .gds file to be checked.")
print("")
print(" If '-keep' is specified, then keep the check script.")
return 0
if __name__ == '__main__':
optionlist = []
arguments = []
debugmode = False
keepmode = False
for option in sys.argv[1:]:
if option.find('-', 0) == 0:
optionlist.append(option)
else:
arguments.append(option)
if len(arguments) != 1:
print("Wrong number of arguments given to check_density.py.")
usage()
sys.exit(0)
relative_path=arguments[0]
gdspath = os.getcwd()+'/'+os.path.split(relative_path)[0]+'/'
if gdspath == '':
gdspath = os.getcwd()
gds_filepath = os.path.split(relative_path)[1]
if os.path.splitext(gds_filepath)[1] != '.gds':
if os.path.splitext(gds_filepath)[1] == '':
gds_filepath += '.gds'
else:
print('Error: Project is not a GDS file!')
sys.exit(1)
gdsname = os.path.split(gds_filepath)[1]
gdsroot = os.path.splitext(gdsname)[0]
# Check for valid path to the GDS file
if not os.path.isdir(gdspath):
print('Error: Project path "' + gds_filepath + '" does not exist or is not readable.')
sys.exit(1)
if not os.path.isfile(gdspath+gds_filepath):
print('Error: Project "' + gdspath+gds_filepath + '" does not exist or is not readable.')
sys.exit(1)
if '-debug' in optionlist:
debugmode = True
if '-keep' in optionlist:
keepmode = True
# NOTE: There should be some attempt to find the installed PDK magicrc file
# if there is no mag/ directory.
# Searching for rcfile
rcfile_paths=[gdspath+'/.magicrc','/$PDK_PATH/libs.tech/magic/TECHNAME.magicrc','/usr/share/pdk/TECHNAME/libs.tech/magic/TECHNAME.magicrc']
rcfile=''
for rc_path in rcfile_paths:
if os.path.isfile(rc_path):
rcfile=rc_path
break
if rcfile=='':
print('Error: .magicrc file not found.')
sys.exit(1)
with open(gdspath + '/check_density.tcl', 'w') as ofile:
print('#!/bin/env wish', file=ofile)
print('crashbackups stop', file=ofile)
print('drc off', file=ofile)
print('snap internal', file=ofile)
print('set starttime [orig_clock format [orig_clock seconds] -format "%D %T"]', file=ofile)
print('puts stdout "Started reading GDS: $starttime"', file=ofile)
print('', file=ofile)
print('flush stdout', file=ofile)
print('update idletasks', file=ofile)
# Read GDS file
print('gds readonly true', file=ofile)
print('gds rescale false', file=ofile)
print('gds read ' + gds_filepath, file=ofile)
print('', file=ofile)
# NOTE: This assumes that the name of the GDS file is the name of the
# topmost cell (which should be passed as an option)
print('load ' + gdsroot, file=ofile)
print('', file=ofile)
print('set midtime [orig_clock format [orig_clock seconds] -format "%D %T"]', file=ofile)
print('puts stdout "Starting density checks: $midtime"', file=ofile)
print('', file=ofile)
print('flush stdout', file=ofile)
print('update idletasks', file=ofile)
# Get step box dimensions (700um for size and 70um for step)
print('box values 0 0 0 0', file=ofile)
# print('box size 700um 700um', file=ofile)
# print('set stepbox [box values]', file=ofile)
# print('set stepwidth [lindex $stepbox 2]', file=ofile)
# print('set stepheight [lindex $stepbox 3]', file=ofile)
print('box size 70um 70um', file=ofile)
print('set stepbox [box values]', file=ofile)
print('set stepsizex [lindex $stepbox 2]', file=ofile)
print('set stepsizey [lindex $stepbox 3]', file=ofile)
print('select top cell', file=ofile)
print('expand', file=ofile)
print('set fullbox [box values]', file=ofile)
print('set xmax [lindex $fullbox 2]', file=ofile)
print('set xmin [lindex $fullbox 0]', file=ofile)
print('set fullwidth [expr {$xmax - $xmin}]', file=ofile)
print('set xtiles [expr {int(ceil(($fullwidth + 0.0) / $stepsizex))}]', file=ofile)
print('set ymax [lindex $fullbox 3]', file=ofile)
print('set ymin [lindex $fullbox 1]', file=ofile)
print('set fullheight [expr {$ymax - $ymin}]', file=ofile)
print('set ytiles [expr {int(ceil(($fullheight + 0.0) / $stepsizey))}]', file=ofile)
print('box size $stepsizex $stepsizey', file=ofile)
print('set xbase [lindex $fullbox 0]', file=ofile)
print('set ybase [lindex $fullbox 1]', file=ofile)
print('', file=ofile)
print('puts stdout "XTILES: $xtiles"', file=ofile)
print('puts stdout "YTILES: $ytiles"', file=ofile)
print('', file=ofile)
# Need to know what fraction of a full tile is the last row and column
print('set xfrac [expr {($xtiles * $stepsizex - $fullwidth + 0.0) / $stepsizex}]', file=ofile)
print('set yfrac [expr {($ytiles * $stepsizey - $fullheight + 0.0) / $stepsizey}]', file=ofile)
# If the last row/column fraction is zero, then set to 1
print('if {$xfrac == 0.0} {set xfrac 1.0}', file=ofile)
print('if {$yfrac == 0.0} {set yfrac 1.0}', file=ofile)
print('puts stdout "XFRAC: $xfrac"', file=ofile)
print('puts stdout "YFRAC: $yfrac"', file=ofile)
print('cif ostyle density', file=ofile)
# Process density at steps. For efficiency, this is done in 70x70 um
# areas, dumped to a file, and then aggregated into the 700x700 areas.
print('for {set y 0} {$y < $ytiles} {incr y} {', file=ofile)
print(' for {set x 0} {$x < $xtiles} {incr x} {', file=ofile)
print(' set xlo [expr $xbase + $x * $stepsizex]', file=ofile)
print(' set ylo [expr $ybase + $y * $stepsizey]', file=ofile)
print(' set xhi [expr $xlo + $stepsizex]', file=ofile)
print(' set yhi [expr $ylo + $stepsizey]', file=ofile)
print(' box values $xlo $ylo $xhi $yhi', file=ofile)
# Flatten this area
print(' flatten -dobbox -nolabels tile', file=ofile)
print(' load tile', file=ofile)
print(' select top cell', file=ofile)
# Run density check for each layer
print(' puts stdout "Density results for tile x=$x y=$y"', file=ofile)
print(' set fdens [cif list cover fom_all]', file=ofile)
print(' set pdens [cif list cover poly_all]', file=ofile)
print(' set ldens [cif list cover li_all]', file=ofile)
print(' set m1dens [cif list cover m1_all]', file=ofile)
print(' set m2dens [cif list cover m2_all]', file=ofile)
print(' set m3dens [cif list cover m3_all]', file=ofile)
print(' set m4dens [cif list cover m4_all]', file=ofile)
print(' set m5dens [cif list cover m5_all]', file=ofile)
print(' puts stdout "FOM: $fdens"', file=ofile)
print(' puts stdout "POLY: $pdens"', file=ofile)
print(' puts stdout "LI1: $ldens"', file=ofile)
print(' puts stdout "MET1: $m1dens"', file=ofile)
print(' puts stdout "MET2: $m2dens"', file=ofile)
print(' puts stdout "MET3: $m3dens"', file=ofile)
print(' puts stdout "MET4: $m4dens"', file=ofile)
print(' puts stdout "MET5: $m5dens"', file=ofile)
print(' flush stdout', file=ofile)
print(' update idletasks', file=ofile)
print(' load ' + gdsroot, file=ofile)
print(' cellname delete tile', file=ofile)
print(' }', file=ofile)
print('}', file=ofile)
print('set endtime [orig_clock format [orig_clock seconds] -format "%D %T"]', file=ofile)
print('puts stdout "Ended: $endtime"', file=ofile)
print('quit -noprompt', file=ofile)
print('', file=ofile)
myenv = os.environ.copy()
myenv['MAGTYPE'] = 'mag'
print('Running density checks on file ' + gds_filepath, flush=True)
mproc = subprocess.Popen(['magic', '-dnull', '-noconsole',
'-rcfile', rcfile, gdspath + '/check_density.tcl'],
stdin = subprocess.DEVNULL,
stdout = subprocess.PIPE,
stderr = subprocess.PIPE,
cwd = gdspath,
env = myenv,
universal_newlines = True)
# Use signal to poll the process and generate any output as it arrives
dlines = []
while mproc:
status = mproc.poll()
if status != None:
try:
output = mproc.communicate(timeout=1)
except ValueError:
print('Magic forced stop, status ' + str(status))
sys.exit(1)
else:
outlines = output[0]
errlines = output[1]
for line in outlines.splitlines():
dlines.append(line)
print(line)
for line in errlines.splitlines():
print(line)
print('Magic exited with status ' + str(status))
if int(status) != 0:
sys.exit(int(status))
else:
break
else:
n = 0
while True:
n += 1
if n > 100:
n = 0
status = mproc.poll()
if status != None:
break
sresult = select.select([mproc.stdout, mproc.stderr], [], [], 0)[0]
if mproc.stdout in sresult:
outstring = mproc.stdout.readline().strip()
dlines.append(outstring)
print(outstring)
elif mproc.stderr in sresult:
outstring = mproc.stderr.readline().strip()
print(outstring)
else:
break
fomfill = []
polyfill = []
lifill = []
met1fill = []
met2fill = []
met3fill = []
met4fill = []
met5fill = []
xtiles = 0
ytiles = 0
xfrac = 0.0
yfrac = 0.0
for line in dlines:
dpair = line.split(':')
if len(dpair) == 2:
layer = dpair[0]
try:
density = float(dpair[1].strip())
except:
continue
if layer == 'FOM':
fomfill.append(density)
elif layer == 'POLY':
polyfill.append(density)
elif layer == 'LI1':
lifill.append(density)
elif layer == 'MET1':
met1fill.append(density)
elif layer == 'MET2':
met2fill.append(density)
elif layer == 'MET3':
met3fill.append(density)
elif layer == 'MET4':
met4fill.append(density)
elif layer == 'MET5':
met5fill.append(density)
elif layer == 'XTILES':
xtiles = int(dpair[1].strip())
elif layer == 'YTILES':
ytiles = int(dpair[1].strip())
elif layer == 'XFRAC':
xfrac = float(dpair[1].strip())
elif layer == 'YFRAC':
yfrac = float(dpair[1].strip())
if ytiles == 0 or xtiles == 0:
print('Failed to read XTILES or YTILES from output.')
sys.exit(1)
if xtiles < 10 or ytiles < 10:
print('Layout is < 700um x 700um; cannot run density checks.')
sys.exit(1)
total_tiles = (ytiles - 9) * (xtiles - 9)
print('')
print('Density results (total tiles = ' + str(total_tiles) + '):')
# Full areas are 10 x 10 tiles = 100. But the right and top sides are
# not full tiles, so the full area must be prorated.
sideadjust = 90.0 + (10.0 * xfrac)
topadjust = 90.0 + (10.0 * yfrac)
corneradjust = 81.0 + (9.0 * xfrac) + (9.0 * yfrac) + (xfrac * yfrac)
print('Side adjustment = ' + str(sideadjust))
print('Top adjustment = ' + str(topadjust))
print('Corner adjustment = ' + str(corneradjust))
print('')
print('FOM Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
fomaccum = 0
for w in range(y, y + 10):
base = xtiles * w + x
fomaccum += sum(fomfill[base : base + 10])
fomaccum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(fomaccum))
if fomaccum < 0.33:
print('***Error: FOM Density < 33%')
elif fomaccum > 0.57:
print('***Error: FOM Density > 57%')
print('')
print('POLY Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
polyaccum = 0
for w in range(y, y + 10):
base = xtiles * w + x
polyaccum += sum(polyfill[base : base + 10])
polyaccum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(polyaccum))
print('')
print('LI Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
liaccum = 0
for w in range(y, y + 10):
base = xtiles * w + x
liaccum += sum(lifill[base : base + 10])
liaccum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(liaccum))
if liaccum < 0.35:
print('***Error: LI Density < 35%')
elif liaccum > 0.60:
print('***Error: LI Density > 60%')
print('')
print('MET1 Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
met1accum = 0
for w in range(y, y + 10):
base = xtiles * w + x
met1accum += sum(met1fill[base : base + 10])
met1accum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(met1accum))
if met1accum < 0.35:
print('***Error: MET1 Density < 35%')
elif met1accum > 0.60:
print('***Error: MET1 Density > 60%')
print('')
print('MET2 Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
met2accum = 0
for w in range(y, y + 10):
base = xtiles * w + x
met2accum += sum(met2fill[base : base + 10])
met2accum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(met2accum))
if met2accum < 0.35:
print('***Error: MET2 Density < 35%')
elif met2accum > 0.60:
print('***Error: MET2 Density > 60%')
print('')
print('MET3 Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
met3accum = 0
for w in range(y, y + 10):
base = xtiles * w + x
met3accum += sum(met3fill[base : base + 10])
met3accum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(met3accum))
if met3accum < 0.35:
print('***Error: MET3 Density < 35%')
elif met3accum > 0.60:
print('***Error: MET3 Density > 60%')
print('')
print('MET4 Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
met4accum = 0
for w in range(y, y + 10):
base = xtiles * w + x
met4accum += sum(met4fill[base : base + 10])
met4accum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(met4accum))
if met4accum < 0.35:
print('***Error: MET4 Density < 35%')
elif met4accum > 0.60:
print('***Error: MET4 Density > 60%')
print('')
print('MET5 Density:')
for y in range(0, ytiles - 9):
if y == ytiles - 10:
atotal = topadjust
else:
atotal = 100.0
for x in range(0, xtiles - 9):
if x == xtiles - 10:
if y == ytiles - 10:
atotal = corneradjust
else:
atotal = sideadjust
met5accum = 0
for w in range(y, y + 10):
base = xtiles * w + x
met5accum += sum(met5fill[base : base + 10])
met5accum /= atotal
print('Tile (' + str(x) + ', ' + str(y) + '): ' + str(met5accum))
if met5accum < 0.45:
print('***Error: MET5 Density < 45%')
elif met5accum > 0.76:
print('***Error: MET5 Density > 76%')
print('')
print('Whole-chip density results:')
atotal = ((xtiles - 1.0) * (ytiles - 1.0)) + ((ytiles - 1.0) * xfrac) + ((xtiles - 1.0) * yfrac) + (xfrac * yfrac)
fomaccum = sum(fomfill) / atotal
print('')
print('FOM Density: ' + str(fomaccum))
if fomaccum < 0.33:
print('***Error: FOM Density < 33%')
elif fomaccum > 0.57:
print('***Error: FOM Density > 57%')
polyaccum = sum(polyfill) / atotal
print('')
print('POLY Density: ' + str(polyaccum))
liaccum = sum(lifill) / atotal
print('')
print('LI Density: ' + str(liaccum))
if liaccum < 0.35:
print('***Error: LI Density < 35%')
elif liaccum > 0.60:
print('***Error: LI Density > 60%')
met1accum = sum(met1fill) / atotal
print('')
print('MET1 Density: ' + str(met1accum))
if met1accum < 0.35:
print('***Error: MET1 Density < 35%')
elif met1accum > 0.60:
print('***Error: MET1 Density > 60%')
met2accum = sum(met2fill) / atotal
print('')
print('MET2 Density: ' + str(met2accum))
if met2accum < 0.35:
print('***Error: MET2 Density < 35%')
elif met2accum > 0.60:
print('***Error: MET2 Density > 60%')
met3accum = sum(met3fill) / atotal
print('')
print('MET3 Density: ' + str(met3accum))
if met3accum < 0.35:
print('***Error: MET3 Density < 35%')
elif met3accum > 0.60:
print('***Error: MET3 Density > 60%')
met4accum = sum(met4fill) / atotal
print('')
print('MET4 Density: ' + str(met4accum))
if met4accum < 0.35:
print('***Error: MET4 Density < 35%')
elif met4accum > 0.60:
print('***Error: MET4 Density > 60%')
met5accum = sum(met5fill) / atotal
print('')
print('MET5 Density: ' + str(met5accum))
if met5accum < 0.45:
print('***Error: MET5 Density < 45%')
elif met5accum > 0.76:
print('***Error: MET5 Density > 76%')
if not keepmode:
if os.path.isfile(gdspath + '/check_density.tcl'):
os.remove(gdspath + '/check_density.tcl')
print('')
print('Done!')
sys.exit(0)