rules/klayout/drc/rule_decks/esd.drc - globalfoundries-pdk/libs/gf180mcu_fd_pr - Git at Google

 #=============================================================================================================================================================
 #------------------------------------------------------------- GF 0.18um MCU DRC RULE DECK (ESD) -------------------------------------------------------------
 #=============================================================================================================================================================

 require 'time'
 require "logger"

 exec_start_time = Time.now

 logger = Logger.new(STDOUT)

 logger.formatter = proc do |severity, datetime, progname, msg|
   "#{datetime}: Memory Usage (" + `pmap #{Process.pid} | tail -1`[10,40].strip + ") : #{msg}
 "
 end

 #================================================
 #----------------- FILE SETUP -------------------
 #================================================

 # optional for a batch launch :   klayout -b -r gf180mcu.drc -rd input=design.gds -rd report=gf180mcu_main.lyrdb

 logger.info("Starting running GF180MCU Klayout DRC runset on %s" % [$input])

 if $input
     if $topcell
         source($input, $topcell)
     else
         source($input)
     end
 end

 logger.info("Loading database to memory is complete.")

 if $report
     logger.info("GF180MCU Klayout DRC runset output at: %s" % [$report])
     report("DRC Run Report at", $report)
 else
     logger.info("GF180MCU Klayout DRC runset output at default location." % [File.join(File.dirname(RBA::CellView::active.filename), "gf180_drc.lyrdb").path])
     report("DRC Run Report at", File.join(File.dirname(RBA::CellView::active.filename), "gf180_drc.lyrdb"))
 end

 if $thr
     logger.info("Number of threads to use %s" % [$thr])
     threads($thr)
 else
     logger.info("Number of threads to use 16")
     threads(16)
 end

 # === TILING MODE ===
 if $run_mode == "tiling"
   # use a tile size of 1mm - not used in deep mode-
   # tiles(500.um)
   # use a tile border of 10 micron:
   # tile_borders(10.um)
   tiles(1000)
   logger.info("Tiling  mode is enabled.")

 elsif $run_mode == "deep"
   #=== HIER MODE ===
   deep
   logger.info("deep  mode is enabled.")

 elsif $run_mode == "flat"
   #=== FLAT MODE ===
   flat
   logger.info("flat  mode is enabled.")

 else
   #=== FLAT MODE ===
   flat
   logger.info("flat  mode is enabled.")

 end # run_mode

 #================================================
 #------------- LAYERS DEFINITIONS ---------------
 #================================================

 v5_xtor        = polygons(112, 1 )
 dualgate       = polygons(55 , 0 )
 poly2          = polygons(30 , 0 )
 nplus          = polygons(32 , 0 )
 pplus          = polygons(31 , 0 )
 comp           = polygons(22 , 0 )
 esd            = polygons(24 , 0 )
 lvs_io         = polygons(119, 5 )

 logger.info("Starting deriving base layers.")
 #================================================
 #------------- LAYERS DERIVATIONS ---------------
 #================================================

 ncomp      =  comp      & nplus
 pcomp      =  comp      & pplus
 tgate      =  poly2     & comp
 ngate      =  nplus     & tgate
 pgate      =  pplus     & tgate

 #================================================
 #------------------ SWITCHES --------------------
 #================================================
 logger.info("Evaluate switches.")

 # FEOL
 if $feol == "false"
   FEOL = $feol
   logger.info("FEOL is disabled.")
 else
   FEOL = "true"
   logger.info("FEOL is enabled.")
 end # FEOL

 # BEOL
 if $beol == "false"
   BEOL = $beol
   logger.info("BEOL is disabled.")
 else
   BEOL = "true"
   logger.info("BEOL is enabled.")
 end # BEOL

 # connectivity rules
 if $conn_drc == "true"
   CONNECTIVITY_RULES = $conn_drc
   logger.info("connectivity rules are enabled.")
 else
   CONNECTIVITY_RULES = false
   logger.info("connectivity rules are disabled.")
 end # connectivity rules

 # METAL_TOP
 if $metal_top
   METAL_TOP = $metal_top
 else
   METAL_TOP = "9K"
 end # METAL_TOP

 logger.info("METAL_TOP Selected is %s" % [METAL_TOP])

 # METAL_LEVEL
 if $metal_level
   METAL_LEVEL = $metal_level
 else
   METAL_LEVEL = "6LM"
 end # METAL_LEVEL

 logger.info("METAL_STACK Selected is %s" % [METAL_LEVEL])

 # WEDGE
 if $wedge == "false"
   WEDGE = $wedge
 else
   WEDGE = "true"
 end # WEDGE

 logger.info("Wedge enabled  %s" % [WEDGE])

 # BALL
 if $ball == "false"
   BALL = $ball
 else
   BALL = "true"
 end # BALL

 logger.info("Ball enabled  %s" % [BALL])

 # GOLD
 if $gold == "false"
   GOLD = $gold
 else
   GOLD = "true"
 end # GOLD

 logger.info("Gold enabled  %s" % [GOLD])

 if $mim_option
   MIM_OPTION = $mim_option
 else
   MIM_OPTION = "Nan"
 end

 logger.info("MIM Option selected %s" % [MIM_OPTION])

 # OFFGRID
 if $offgrid == "false"
   OFFGRID = false
 else
   OFFGRID = true
 end # OFFGRID

 logger.info("Offgrid enabled  %s" % [OFFGRID])

 #================================================
 #----------------------ESD-----------------------
 #================================================


 if FEOL
 logger.info("FEOL section")

 # Rule ESD.1: Minimum width of an ESD implant area. is 0.6µm
 logger.info("Executing rule ESD.1")
 esd1_l1  = esd.width(0.6.um, euclidian).polygons(0.001)
 esd1_l1.output("ESD.1", "ESD.1 : Minimum width of an ESD implant area. : 0.6µm")
 esd1_l1.forget

 # Rule ESD.2: Minimum space between two ESD implant areas. (Merge if the space is less than 0.6um). is 0.6µm
 logger.info("Executing rule ESD.2")
 esd2_l1  = esd.space(0.6.um, euclidian).polygons(0.001)
 esd2_l1.output("ESD.2", "ESD.2 : Minimum space between two ESD implant areas. (Merge if the space is less than 0.6um). : 0.6µm")
 esd2_l1.forget

 # Rule ESD.3a: Minimum space to NCOMP. is 0.6µm
 logger.info("Executing rule ESD.3a")
 esd3a_l1  = esd.separation(ncomp, 0.6.um, euclidian).polygons(0.001)
 esd3a_l1.output("ESD.3a", "ESD.3a : Minimum space to NCOMP. : 0.6µm")
 esd3a_l1.forget

 # Rule ESD.3b: Min/max space to a butted PCOMP.
 logger.info("Executing rule ESD.3b")
 esd3b_l1 = esd.not_outside(pcomp)
 esd3b_l1.output("ESD.3b", "ESD.3b : Min/max space to a butted PCOMP.")
 esd3b_l1.forget

 # Rule ESD.4a: Extension beyond NCOMP. is 0.24µm
 logger.info("Executing rule ESD.4a")
 esd4a_l1 = esd.edges.not_interacting(pcomp).enclosing(ncomp.edges, 0.24.um, euclidian).polygons(0.001)
 esd4a_l1.output("ESD.4a", "ESD.4a : Extension beyond NCOMP. : 0.24µm")
 esd4a_l1.forget

 # Rule ESD.4b: Minimum overlap of an ESD implant edge to a COMP. is 0.45µm
 logger.info("Executing rule ESD.4b")
 esd4b_l1  = esd.overlap(comp, 0.45.um, euclidian).polygons(0.001)
 esd4b_l1.output("ESD.4b", "ESD.4b : Minimum overlap of an ESD implant edge to a COMP. : 0.45µm")
 esd4b_l1.forget

 # Rule ESD.5a: Minimum ESD area (um2). is 0.49µm²
 logger.info("Executing rule ESD.5a")
 esd5a_l1  = esd.with_area(nil, 0.49.um)
 esd5a_l1.output("ESD.5a", "ESD.5a : Minimum ESD area (um2). : 0.49µm²")
 esd5a_l1.forget
 # Rule ESD.5b: Minimum field area enclosed by ESD implant (um2). is 0.49µm²
 logger.info("Executing rule ESD.5b")
 esd5b_l1  = esd.holes.with_area(nil, 0.49.um)
 esd5b_l1.output("ESD.5b", "ESD.5b : Minimum field area enclosed by ESD implant (um2). : 0.49µm²")
 esd5b_l1.forget
 # Rule ESD.6: Extension perpendicular to Poly2 gate. is 0.45µm
 logger.info("Executing rule ESD.6")
 esd6_l1 = esd.edges.enclosing(poly2.edges.interacting(tgate.edges), 0.45.um, projection).polygons(0.001)
 esd6_l1.output("ESD.6", "ESD.6 : Extension perpendicular to Poly2 gate. : 0.45µm")
 esd6_l1.forget

 # Rule ESD.7: No ESD implant inside PCOMP.
 logger.info("Executing rule ESD.7")
 esd7_l1 = esd.not_outside(pcomp)
 esd7_l1.output("ESD.7", "ESD.7 : No ESD implant inside PCOMP.")
 esd7_l1.forget

 # Rule ESD.8: Minimum space to Nplus/Pplus. is 0.3µm
 logger.info("Executing rule ESD.8")
 esd8_l1 = esd.separation(nplus.or(pplus), 0.3.um).polygons
 esd8_l1.output("ESD.8", "ESD.8 : Minimum space to Nplus/Pplus. : 0.3µm")
 esd8_l1.forget

 # Rule ESD.pl: Minimum gate length of 5V/6V gate NMOS. is 0.8µm
 logger.info("Executing rule ESD.pl")
 esdpl_l1  = poly2.interacting(esd).edges.and(tgate.edges).width(0.8.um, euclidian).polygons(0.001).overlapping(dualgate)
 esdpl_l1.output("ESD.pl", "ESD.pl : Minimum gate length of 5V/6V gate NMOS. : 0.8µm")
 esdpl_l1.forget

 # Rule ESD.9: ESD implant layer must be overlapped by Dualgate layer (as ESD implant option is only for 5V/6V devices).
 logger.info("Executing rule ESD.9")
 esd9_l1 = esd.not_inside(dualgate)
 esd9_l1.output("ESD.9", "ESD.9 : ESD implant layer must be overlapped by Dualgate layer (as ESD implant option is only for 5V/6V devices).")
 esd9_l1.forget

 # Rule ESD.10: LVS_IO shall be drawn covering I/O MOS active area by minimum overlap.
 logger.info("Executing rule ESD.10")
 esd10_l1 = comp.and(esd).not_outside(lvs_io).not(lvs_io)
 esd10_l1.output("ESD.10", "ESD.10 : LVS_IO shall be drawn covering I/O MOS active area by minimum overlap.")
 esd10_l1.forget


 end #FEOL


 exec_end_time = Time.now
 run_time = exec_end_time - exec_start_time
 logger.info("DRC Run time %f seconds" % [run_time])
	#=============================================================================================================================================================
	#------------------------------------------------------------- GF 0.18um MCU DRC RULE DECK (ESD) -------------------------------------------------------------
	#=============================================================================================================================================================

	require 'time'
	require "logger"

	exec_start_time = Time.now

	logger = Logger.new(STDOUT)

	logger.formatter = proc do \|severity, datetime, progname, msg\|
	"#{datetime}: Memory Usage (" + `pmap #{Process.pid} \| tail -1`[10,40].strip + ") : #{msg}
	"
	end

	#================================================
	#----------------- FILE SETUP -------------------
	#================================================

	# optional for a batch launch : klayout -b -r gf180mcu.drc -rd input=design.gds -rd report=gf180mcu_main.lyrdb

	logger.info("Starting running GF180MCU Klayout DRC runset on %s" % [$input])

	if $input
	if $topcell
	source($input, $topcell)
	else
	source($input)
	end
	end

	logger.info("Loading database to memory is complete.")

	if $report
	logger.info("GF180MCU Klayout DRC runset output at: %s" % [$report])
	report("DRC Run Report at", $report)
	else
	logger.info("GF180MCU Klayout DRC runset output at default location." % [File.join(File.dirname(RBA::CellView::active.filename), "gf180_drc.lyrdb").path])
	report("DRC Run Report at", File.join(File.dirname(RBA::CellView::active.filename), "gf180_drc.lyrdb"))
	end

	if $thr
	logger.info("Number of threads to use %s" % [$thr])
	threads($thr)
	else
	logger.info("Number of threads to use 16")
	threads(16)
	end

	# === TILING MODE ===
	if $run_mode == "tiling"
	# use a tile size of 1mm - not used in deep mode-
	# tiles(500.um)
	# use a tile border of 10 micron:
	# tile_borders(10.um)
	tiles(1000)
	logger.info("Tiling mode is enabled.")

	elsif $run_mode == "deep"
	#=== HIER MODE ===
	deep
	logger.info("deep mode is enabled.")

	elsif $run_mode == "flat"
	#=== FLAT MODE ===
	flat
	logger.info("flat mode is enabled.")

	else
	#=== FLAT MODE ===
	flat
	logger.info("flat mode is enabled.")

	end # run_mode

	#================================================
	#------------- LAYERS DEFINITIONS ---------------
	#================================================

	v5_xtor = polygons(112, 1 )
	dualgate = polygons(55 , 0 )
	poly2 = polygons(30 , 0 )
	nplus = polygons(32 , 0 )
	pplus = polygons(31 , 0 )
	comp = polygons(22 , 0 )
	esd = polygons(24 , 0 )
	lvs_io = polygons(119, 5 )

	logger.info("Starting deriving base layers.")
	#================================================
	#------------- LAYERS DERIVATIONS ---------------
	#================================================

	ncomp = comp & nplus
	pcomp = comp & pplus
	tgate = poly2 & comp
	ngate = nplus & tgate
	pgate = pplus & tgate

	#================================================
	#------------------ SWITCHES --------------------
	#================================================
	logger.info("Evaluate switches.")

	# FEOL
	if $feol == "false"
	FEOL = $feol
	logger.info("FEOL is disabled.")
	else
	FEOL = "true"
	logger.info("FEOL is enabled.")
	end # FEOL

	# BEOL
	if $beol == "false"
	BEOL = $beol
	logger.info("BEOL is disabled.")
	else
	BEOL = "true"
	logger.info("BEOL is enabled.")
	end # BEOL

	# connectivity rules
	if $conn_drc == "true"
	CONNECTIVITY_RULES = $conn_drc
	logger.info("connectivity rules are enabled.")
	else
	CONNECTIVITY_RULES = false
	logger.info("connectivity rules are disabled.")
	end # connectivity rules

	# METAL_TOP
	if $metal_top
	METAL_TOP = $metal_top
	else
	METAL_TOP = "9K"
	end # METAL_TOP

	logger.info("METAL_TOP Selected is %s" % [METAL_TOP])

	# METAL_LEVEL
	if $metal_level
	METAL_LEVEL = $metal_level
	else
	METAL_LEVEL = "6LM"
	end # METAL_LEVEL

	logger.info("METAL_STACK Selected is %s" % [METAL_LEVEL])

	# WEDGE
	if $wedge == "false"
	WEDGE = $wedge
	else
	WEDGE = "true"
	end # WEDGE

	logger.info("Wedge enabled %s" % [WEDGE])

	# BALL
	if $ball == "false"
	BALL = $ball
	else
	BALL = "true"
	end # BALL

	logger.info("Ball enabled %s" % [BALL])

	# GOLD
	if $gold == "false"
	GOLD = $gold
	else
	GOLD = "true"
	end # GOLD

	logger.info("Gold enabled %s" % [GOLD])

	if $mim_option
	MIM_OPTION = $mim_option
	else
	MIM_OPTION = "Nan"
	end

	logger.info("MIM Option selected %s" % [MIM_OPTION])

	# OFFGRID
	if $offgrid == "false"
	OFFGRID = false
	else
	OFFGRID = true
	end # OFFGRID

	logger.info("Offgrid enabled %s" % [OFFGRID])

	#================================================
	#----------------------ESD-----------------------
	#================================================


	if FEOL
	logger.info("FEOL section")

	# Rule ESD.1: Minimum width of an ESD implant area. is 0.6µm
	logger.info("Executing rule ESD.1")
	esd1_l1 = esd.width(0.6.um, euclidian).polygons(0.001)
	esd1_l1.output("ESD.1", "ESD.1 : Minimum width of an ESD implant area. : 0.6µm")
	esd1_l1.forget

	# Rule ESD.2: Minimum space between two ESD implant areas. (Merge if the space is less than 0.6um). is 0.6µm
	logger.info("Executing rule ESD.2")
	esd2_l1 = esd.space(0.6.um, euclidian).polygons(0.001)
	esd2_l1.output("ESD.2", "ESD.2 : Minimum space between two ESD implant areas. (Merge if the space is less than 0.6um). : 0.6µm")
	esd2_l1.forget

	# Rule ESD.3a: Minimum space to NCOMP. is 0.6µm
	logger.info("Executing rule ESD.3a")
	esd3a_l1 = esd.separation(ncomp, 0.6.um, euclidian).polygons(0.001)
	esd3a_l1.output("ESD.3a", "ESD.3a : Minimum space to NCOMP. : 0.6µm")
	esd3a_l1.forget

	# Rule ESD.3b: Min/max space to a butted PCOMP.
	logger.info("Executing rule ESD.3b")
	esd3b_l1 = esd.not_outside(pcomp)
	esd3b_l1.output("ESD.3b", "ESD.3b : Min/max space to a butted PCOMP.")
	esd3b_l1.forget

	# Rule ESD.4a: Extension beyond NCOMP. is 0.24µm
	logger.info("Executing rule ESD.4a")
	esd4a_l1 = esd.edges.not_interacting(pcomp).enclosing(ncomp.edges, 0.24.um, euclidian).polygons(0.001)
	esd4a_l1.output("ESD.4a", "ESD.4a : Extension beyond NCOMP. : 0.24µm")
	esd4a_l1.forget

	# Rule ESD.4b: Minimum overlap of an ESD implant edge to a COMP. is 0.45µm
	logger.info("Executing rule ESD.4b")
	esd4b_l1 = esd.overlap(comp, 0.45.um, euclidian).polygons(0.001)
	esd4b_l1.output("ESD.4b", "ESD.4b : Minimum overlap of an ESD implant edge to a COMP. : 0.45µm")
	esd4b_l1.forget

	# Rule ESD.5a: Minimum ESD area (um2). is 0.49µm²
	logger.info("Executing rule ESD.5a")
	esd5a_l1 = esd.with_area(nil, 0.49.um)
	esd5a_l1.output("ESD.5a", "ESD.5a : Minimum ESD area (um2). : 0.49µm²")
	esd5a_l1.forget
	# Rule ESD.5b: Minimum field area enclosed by ESD implant (um2). is 0.49µm²
	logger.info("Executing rule ESD.5b")
	esd5b_l1 = esd.holes.with_area(nil, 0.49.um)
	esd5b_l1.output("ESD.5b", "ESD.5b : Minimum field area enclosed by ESD implant (um2). : 0.49µm²")
	esd5b_l1.forget
	# Rule ESD.6: Extension perpendicular to Poly2 gate. is 0.45µm
	logger.info("Executing rule ESD.6")
	esd6_l1 = esd.edges.enclosing(poly2.edges.interacting(tgate.edges), 0.45.um, projection).polygons(0.001)
	esd6_l1.output("ESD.6", "ESD.6 : Extension perpendicular to Poly2 gate. : 0.45µm")
	esd6_l1.forget

	# Rule ESD.7: No ESD implant inside PCOMP.
	logger.info("Executing rule ESD.7")
	esd7_l1 = esd.not_outside(pcomp)
	esd7_l1.output("ESD.7", "ESD.7 : No ESD implant inside PCOMP.")
	esd7_l1.forget

	# Rule ESD.8: Minimum space to Nplus/Pplus. is 0.3µm
	logger.info("Executing rule ESD.8")
	esd8_l1 = esd.separation(nplus.or(pplus), 0.3.um).polygons
	esd8_l1.output("ESD.8", "ESD.8 : Minimum space to Nplus/Pplus. : 0.3µm")
	esd8_l1.forget

	# Rule ESD.pl: Minimum gate length of 5V/6V gate NMOS. is 0.8µm
	logger.info("Executing rule ESD.pl")
	esdpl_l1 = poly2.interacting(esd).edges.and(tgate.edges).width(0.8.um, euclidian).polygons(0.001).overlapping(dualgate)
	esdpl_l1.output("ESD.pl", "ESD.pl : Minimum gate length of 5V/6V gate NMOS. : 0.8µm")
	esdpl_l1.forget

	# Rule ESD.9: ESD implant layer must be overlapped by Dualgate layer (as ESD implant option is only for 5V/6V devices).
	logger.info("Executing rule ESD.9")
	esd9_l1 = esd.not_inside(dualgate)
	esd9_l1.output("ESD.9", "ESD.9 : ESD implant layer must be overlapped by Dualgate layer (as ESD implant option is only for 5V/6V devices).")
	esd9_l1.forget

	# Rule ESD.10: LVS_IO shall be drawn covering I/O MOS active area by minimum overlap.
	logger.info("Executing rule ESD.10")
	esd10_l1 = comp.and(esd).not_outside(lvs_io).not(lvs_io)
	esd10_l1.output("ESD.10", "ESD.10 : LVS_IO shall be drawn covering I/O MOS active area by minimum overlap.")
	esd10_l1.forget


	end #FEOL


	exec_end_time = Time.now
	run_time = exec_end_time - exec_start_time
	logger.info("DRC Run time %f seconds" % [run_time])