# See LICENSE for licensing information. # # Copyright (c) 2016-2019 Regents of the University of California and The Board # of Regents for the Oklahoma Agricultural and Mechanical College # (acting for and on behalf of Oklahoma State University) # All rights reserved. # import debug import design import math from sram_factory import factory from vector import vector from globals import OPTS class hierarchical_decoder(design.design): """ Dynamically generated hierarchical decoder. """ def __init__(self, name, num_outputs): design.design.__init__(self, name) self.AND_FORMAT = "DEC_AND_{0}" self.pre2x4_inst = [] self.pre3x8_inst = [] b = factory.create(module_type="bitcell") self.cell_height = b.height self.num_outputs = num_outputs self.num_inputs = math.ceil(math.log(self.num_outputs, 2)) (self.no_of_pre2x4, self.no_of_pre3x8)=self.determine_predecodes(self.num_inputs) self.create_netlist() if not OPTS.netlist_only: self.create_layout() def create_netlist(self): self.add_modules() self.setup_netlist_constants() self.add_pins() self.create_pre_decoder() self.create_row_decoder() def create_layout(self): self.setup_layout_constants() self.place_pre_decoder() self.place_row_decoder() self.height = max(self.predecoder_height, self.row_decoder_height) + self.bus_space self.route_inputs() self.route_outputs() self.route_decoder_bus() self.route_vdd_gnd() self.offset_all_coordinates() self.width = self.and_inst[0].rx() + self.m1_space self.add_boundary() self.DRC_LVS() def add_modules(self): self.and2 = factory.create(module_type="and2_dec", height=self.cell_height) self.add_mod(self.and2) self.and3 = factory.create(module_type="and3_dec", height=self.cell_height) self.add_mod(self.and3) # TBD # self.and4 = factory.create(module_type="and4_dec") # self.add_mod(self.and4) self.add_decoders() def add_decoders(self): """ Create the decoders based on the number of pre-decodes """ self.pre2_4 = factory.create(module_type="hierarchical_predecode2x4", height=self.cell_height) self.add_mod(self.pre2_4) self.pre3_8 = factory.create(module_type="hierarchical_predecode3x8", height=self.cell_height) self.add_mod(self.pre3_8) def determine_predecodes(self, num_inputs): """ Determines the number of 2:4 pre-decoder and 3:8 pre-decoder needed based on the number of inputs """ if (num_inputs == 2): return (1, 0) elif (num_inputs == 3): return(0, 1) elif (num_inputs == 4): return(2, 0) elif (num_inputs == 5): return(1, 1) elif (num_inputs == 6): return(3, 0) elif (num_inputs == 7): return(2, 1) elif (num_inputs == 8): return(1, 2) elif (num_inputs == 9): return(0, 3) else: debug.error("Invalid number of inputs for hierarchical decoder", -1) def setup_netlist_constants(self): self.predec_groups = [] # This array is a 2D array. # Distributing vertical bus to different groups. One group belongs to one pre-decoder. # For example, for two 2:4 pre-decoder and one 3:8 pre-decoder, we will # have total 16 output lines out of these 3 pre-decoders and they will # be distributed as [ [0,1,2,3] ,[4,5,6,7], [8,9,10,11,12,13,14,15] ] # in self.predec_groups index = 0 for i in range(self.no_of_pre2x4): lines = [] for j in range(4): lines.append(index) index = index + 1 self.predec_groups.append(lines) for i in range(self.no_of_pre3x8): lines = [] for j in range(8): lines.append(index) index = index + 1 self.predec_groups.append(lines) def setup_layout_constants(self): """ Calculate the overall dimensions of the hierarchical decoder """ # If we have 4 or fewer rows, the predecoder is the decoder itself if self.num_inputs>=4: self.total_number_of_predecoder_outputs = 4 * self.no_of_pre2x4 + 8 * self.no_of_pre3x8 else: self.total_number_of_predecoder_outputs = 0 debug.error("Not enough rows ({}) for a hierarchical decoder. Non-hierarchical not supported yet.".format(self.num_inputs), -1) # Calculates height and width of pre-decoder, # FIXME: Update with 4x16 if self.no_of_pre3x8 > 0 and self.no_of_pre2x4 > 0: self.predecoder_width = max(self.pre3_8.width, self.pre2_4.width) elif self.no_of_pre3x8 > 0: self.predecoder_width = self.pre3_8.width else: self.predecoder_width = self.pre2_4.width # How much space between each predecoder self.predecoder_spacing = 2 * self.and2.height self.predecoder_height = self.pre2_4.height * self.no_of_pre2x4 + self.pre3_8.height * self.no_of_pre3x8 \ + (self.no_of_pre2x4 + self.no_of_pre3x8 - 1) * self.predecoder_spacing # Inputs to cells are on input layer # Outputs from cells are on output layer if OPTS.tech_name == "sky130": self.bus_layer = "m1" self.bus_directions = "nonpref" self.bus_pitch = self.m1_pitch self.bus_space = self.m2_space self.input_layer = "m2" self.output_layer = "li" self.output_layer_pitch = self.li_pitch else: self.bus_layer = "m2" self.bus_directions = "pref" self.bus_pitch = self.m2_pitch self.bus_space = self.m2_space # These two layers being the same requires a special jog # to ensure to conflicts with the output layers self.input_layer = "m1" self.output_layer = "m3" self.output_layer_pitch = self.m3_pitch # Two extra pitches between modules on left and right self.internal_routing_width = self.total_number_of_predecoder_outputs * self.bus_pitch + self.bus_pitch self.row_decoder_height = self.and2.height * self.num_outputs # Extra bus space for supply contacts self.input_routing_width = self.num_inputs * self.bus_pitch + self.bus_space def route_inputs(self): """ Create input bus for the predecoders """ # Find the left-most predecoder min_x = 0 if self.no_of_pre2x4 > 0: min_x = min(min_x, self.pre2x4_inst[0].lx()) if self.no_of_pre3x8 > 0: min_x = min(min_x, self.pre3x8_inst[0].lx()) input_offset=vector(min_x - self.input_routing_width, 0) input_bus_names = ["addr_{0}".format(i) for i in range(self.num_inputs)] self.input_bus = self.create_vertical_pin_bus(layer=self.bus_layer, offset=input_offset, names=input_bus_names, length=self.predecoder_height) self.route_input_to_predecodes() def route_input_to_predecodes(self): """ Route the vertical input rail to the predecoders """ for pre_num in range(self.no_of_pre2x4): for i in range(2): index = pre_num * 2 + i input_pos = self.input_bus["addr_{}".format(index)].center() in_name = "in_{}".format(i) decoder_pin = self.pre2x4_inst[pre_num].get_pin(in_name) decoder_offset = decoder_pin.center() input_offset = input_pos.scale(1, 0) + decoder_offset.scale(0, 1) self.route_input_bus(decoder_offset, input_offset) for pre_num in range(self.no_of_pre3x8): for i in range(3): index = pre_num * 3 + i + self.no_of_pre2x4 * 2 input_pos = self.input_bus["addr_{}".format(index)].center() in_name = "in_{}".format(i) decoder_pin = self.pre3x8_inst[pre_num].get_pin(in_name) decoder_offset = decoder_pin.center() input_offset = input_pos.scale(1, 0) + decoder_offset.scale(0, 1) self.route_input_bus(decoder_offset, input_offset) def route_input_bus(self, input_offset, output_offset): """ Route a vertical M2 coordinate to another vertical M2 coordinate to the predecode inputs """ self.add_via_stack_center(from_layer=self.bus_layer, to_layer=self.input_layer, offset=input_offset) self.add_via_stack_center(from_layer=self.bus_layer, to_layer=self.input_layer, offset=output_offset, directions=self.bus_directions) self.add_path(self.input_layer, [input_offset, output_offset]) def add_pins(self): """ Add the module pins """ for i in range(self.num_inputs): self.add_pin("addr_{0}".format(i), "INPUT") for j in range(self.num_outputs): self.add_pin("decode_{0}".format(j), "OUTPUT") self.add_pin("vdd", "POWER") self.add_pin("gnd", "GROUND") def create_pre_decoder(self): """ Creates pre-decoder and places labels input address [A] """ for i in range(self.no_of_pre2x4): self.create_pre2x4(i) for i in range(self.no_of_pre3x8): self.create_pre3x8(i) def create_pre2x4(self, num): """ Add a 2x4 predecoder to the left of the origin """ if (self.num_inputs == 2): index_off1 = index_off2 = 0 else: index_off1 = num * 2 index_off2 = num * 4 pins = [] for input_index in range(2): pins.append("addr_{0}".format(input_index + index_off1)) for output_index in range(4): pins.append("out_{0}".format(output_index + index_off2)) pins.extend(["vdd", "gnd"]) self.pre2x4_inst.append(self.add_inst(name="pre_{0}".format(num), mod=self.pre2_4)) self.connect_inst(pins) def create_pre3x8(self, num): """ Add 3x8 predecoder to the left of the origin and above any 2x4 decoders """ # If we had 2x4 predecodes, those are used as the lower # decode output bits in_index_offset = num * 3 + self.no_of_pre2x4 * 2 out_index_offset = num * 8 + self.no_of_pre2x4 * 4 pins = [] for input_index in range(3): pins.append("addr_{0}".format(input_index + in_index_offset)) for output_index in range(8): pins.append("out_{0}".format(output_index + out_index_offset)) pins.extend(["vdd", "gnd"]) self.pre3x8_inst.append(self.add_inst(name="pre3x8_{0}".format(num), mod=self.pre3_8)) self.connect_inst(pins) def place_pre_decoder(self): """ Creates pre-decoder and places labels input address [A] """ for i in range(self.no_of_pre2x4): self.place_pre2x4(i) for i in range(self.no_of_pre3x8): self.place_pre3x8(i) def place_pre2x4(self, num): """ Place 2x4 predecoder to the left of the origin """ if (self.num_inputs == 2): base = vector(-self.pre2_4.width, 0) else: base= vector(-self.pre2_4.width, num * (self.pre2_4.height + self.predecoder_spacing)) self.pre2x4_inst[num].place(base) def place_pre3x8(self, num): """ Place 3x8 predecoder to the left of the origin and above any 2x4 decoders """ if (self.num_inputs == 3): offset = vector(-self.pre_3_8.width, 0) else: height = self.no_of_pre2x4 * (self.pre2_4.height + self.predecoder_spacing) + num * (self.pre3_8.height + self.predecoder_spacing) offset = vector(-self.pre3_8.width, height) self.pre3x8_inst[num].place(offset) def create_row_decoder(self): """ Create the row-decoder by placing AND2/AND3 and Inverters and add the primary decoder output pins. """ if (self.num_inputs >= 4): self.create_decoder_and_array() def create_decoder_and_array(self): """ Add a column of AND gates for final decode """ self.and_inst = [] # Row Decoder AND GATE array for address inputs <5. if (self.num_inputs == 4 or self.num_inputs == 5): for i in range(len(self.predec_groups[0])): for j in range(len(self.predec_groups[1])): output = len(self.predec_groups[0]) * j + i if (output < self.num_outputs): name = self.AND_FORMAT.format(output) self.and_inst.append(self.add_inst(name=name, mod=self.and2)) pins =["out_{0}".format(i), "out_{0}".format(j + len(self.predec_groups[0])), "decode_{0}".format(output), "vdd", "gnd"] self.connect_inst(pins) # Row Decoder AND GATE array for address inputs >5. elif (self.num_inputs > 5): for i in range(len(self.predec_groups[0])): for j in range(len(self.predec_groups[1])): for k in range(len(self.predec_groups[2])): output = (len(self.predec_groups[0]) * len(self.predec_groups[1])) * k \ + len(self.predec_groups[0]) * j + i if (output < self.num_outputs): name = self.AND_FORMAT.format(output) self.and_inst.append(self.add_inst(name=name, mod=self.and3)) pins = ["out_{0}".format(i), "out_{0}".format(j + len(self.predec_groups[0])), "out_{0}".format(k + len(self.predec_groups[0]) + len(self.predec_groups[1])), "decode_{0}".format(output), "vdd", "gnd"] self.connect_inst(pins) def place_row_decoder(self): """ Place the row-decoder by placing AND2/AND3 and Inverters and add the primary decoder output pins. """ if (self.num_inputs >= 4): self.place_decoder_and_array() def place_decoder_and_array(self): """ Add a column of AND gates for final decode. This may have more than one decoder per row to match the bitcell height. """ # Row Decoder AND GATE array for address inputs <5. if (self.num_inputs == 4 or self.num_inputs == 5): self.place_and_array(and_mod=self.and2) # Row Decoder AND GATE array for address inputs >5. # FIXME: why this correct offset?) elif (self.num_inputs > 5): self.place_and_array(and_mod=self.and3) def place_and_array(self, and_mod): """ Add a column of AND gates for the decoder above the predecoders. """ for row in range(self.num_outputs): if ((row % 2) == 0): y_off = and_mod.height * row mirror = "R0" else: y_off = and_mod.height * (row + 1) mirror = "MX" x_off = self.internal_routing_width self.and_inst[row].place(offset=vector(x_off, y_off), mirror=mirror) def route_outputs(self): """ Add the pins. """ for row in range(self.num_outputs): and_inst = self.and_inst[row] self.copy_layout_pin(and_inst, "Z", "decode_{0}".format(row)) def route_decoder_bus(self): """ Creates vertical metal 2 bus to connect predecoder and decoder stages. """ # This is not needed for inputs <4 since they have no pre/decode stages. if (self.num_inputs >= 4): # This leaves an offset for the predecoder output jogs input_bus_names = ["predecode_{0}".format(i) for i in range(self.total_number_of_predecoder_outputs)] self.predecode_bus = self.create_vertical_pin_bus(layer=self.bus_layer, pitch=self.bus_pitch, offset=vector(self.bus_pitch, 0), names=input_bus_names, length=self.height) self.route_predecodes_to_bus() self.route_bus_to_decoder() def route_predecodes_to_bus(self): """ Iterates through all of the predecodes and connects to the rails including the offsets """ # FIXME: convert to connect_bus for pre_num in range(self.no_of_pre2x4): for i in range(4): predecode_name = "predecode_{}".format(pre_num * 4 + i) out_name = "out_{}".format(i) pin = self.pre2x4_inst[pre_num].get_pin(out_name) x_offset = self.pre2x4_inst[pre_num].rx() + self.output_layer_pitch y_offset = self.pre2x4_inst[pre_num].by() + i * self.cell_height self.route_predecode_bus_inputs(predecode_name, pin, x_offset, y_offset) # FIXME: convert to connect_bus for pre_num in range(self.no_of_pre3x8): for i in range(8): predecode_name = "predecode_{}".format(pre_num * 8 + i + self.no_of_pre2x4 * 4) out_name = "out_{}".format(i) pin = self.pre3x8_inst[pre_num].get_pin(out_name) x_offset = self.pre3x8_inst[pre_num].rx() + self.output_layer_pitch y_offset = self.pre3x8_inst[pre_num].by() + i * self.cell_height self.route_predecode_bus_inputs(predecode_name, pin, x_offset, y_offset) def route_bus_to_decoder(self): """ Use the self.predec_groups to determine the connections to the decoder AND gates. Inputs of AND2/AND3 gates come from different groups. For example for these groups [ [0,1,2,3] ,[4,5,6,7], [8,9,10,11,12,13,14,15] ] the first AND3 inputs are connected to [0,4,8], second AND3 is connected to [0,4,9], ... and the 128th AND3 is connected to [3,7,15] """ output_index = 0 if (self.num_inputs == 4 or self.num_inputs == 5): for index_B in self.predec_groups[1]: for index_A in self.predec_groups[0]: # FIXME: convert to connect_bus? if (output_index < self.num_outputs): predecode_name = "predecode_{}".format(index_A) self.route_predecode_bus_outputs(predecode_name, self.and_inst[output_index].get_pin("A"), output_index) predecode_name = "predecode_{}".format(index_B) self.route_predecode_bus_outputs(predecode_name, self.and_inst[output_index].get_pin("B"), output_index) output_index = output_index + 1 elif (self.num_inputs > 5): for index_C in self.predec_groups[2]: for index_B in self.predec_groups[1]: for index_A in self.predec_groups[0]: # FIXME: convert to connect_bus? if (output_index < self.num_outputs): predecode_name = "predecode_{}".format(index_A) self.route_predecode_bus_outputs(predecode_name, self.and_inst[output_index].get_pin("A"), output_index) predecode_name = "predecode_{}".format(index_B) self.route_predecode_bus_outputs(predecode_name, self.and_inst[output_index].get_pin("B"), output_index) predecode_name = "predecode_{}".format(index_C) self.route_predecode_bus_outputs(predecode_name, self.and_inst[output_index].get_pin("C"), output_index) output_index = output_index + 1 def route_vdd_gnd(self): """ Add a pin for each row of vdd/gnd which are must-connects next level up. """ if OPTS.tech_name == "sky130": for n in ["vdd", "gnd"]: pins = self.and_inst[0].get_pins(n) for pin in pins: self.add_rect(layer=pin.layer, offset=pin.ll() + vector(0, self.bus_space), width=pin.width(), height=self.height - 2 * self.bus_space) # This adds power vias at the top of each cell # (except the last to keep them inside the boundary) for i in self.and_inst[:-1]: pins = i.get_pins(n) for pin in pins: self.add_power_pin(name=n, loc=pin.uc(), start_layer=pin.layer) self.add_power_pin(name=n, loc=pin.uc(), start_layer=pin.layer) for i in self.pre2x4_inst + self.pre3x8_inst: self.copy_layout_pin(i, n) else: # The vias will be placed at the right of the cells. xoffset = max(x.rx() for x in self.and_inst) + 0.5 * self.m1_space for row in range(0, self.num_outputs): for pin_name in ["vdd", "gnd"]: # The nand and inv are the same height rows... supply_pin = self.and_inst[row].get_pin(pin_name) pin_pos = vector(xoffset, supply_pin.cy()) self.add_power_pin(name=pin_name, loc=pin_pos, start_layer=supply_pin.layer) # Copy the pins from the predecoders for pre in self.pre2x4_inst + self.pre3x8_inst: for pin_name in ["vdd", "gnd"]: self.copy_layout_pin(pre, pin_name) def route_predecode_bus_outputs(self, rail_name, pin, row): """ Connect the routing rail to the given metal1 pin using a routing track at the given y_offset """ pin_pos = pin.center() rail_pos = vector(self.predecode_bus[rail_name].cx(), pin_pos.y) self.add_path(self.input_layer, [rail_pos, pin_pos]) self.add_via_stack_center(from_layer=self.bus_layer, to_layer=self.input_layer, offset=rail_pos, directions=self.bus_directions) self.add_via_stack_center(from_layer=pin.layer, to_layer=self.input_layer, offset=pin_pos, directions=("H", "H")) def route_predecode_bus_inputs(self, rail_name, pin, x_offset, y_offset): """ Connect the routing rail to the given metal1 pin using a jog to the right of the cell at the given x_offset. """ # This routes the pin up to the rail, basically, to avoid conflicts. # It would be fixed with a channel router. pin_pos = pin.rc() mid_point1 = vector(x_offset, pin_pos.y) mid_point2 = vector(x_offset, y_offset) rail_pos = vector(self.predecode_bus[rail_name].cx(), mid_point2.y) self.add_path(self.output_layer, [pin_pos, mid_point1, mid_point2, rail_pos]) # pin_pos = pin.center() # rail_pos = vector(self.predecode_bus[rail_name].cx(), pin_pos.y) # self.add_path(self.output_layer, [pin_pos, rail_pos]) self.add_via_stack_center(from_layer=pin.layer, to_layer=self.output_layer, offset=pin_pos) self.add_via_stack_center(from_layer=self.bus_layer, to_layer=self.output_layer, offset=rail_pos, directions=self.bus_directions) def input_load(self): if self.determine_predecodes(self.num_inputs)[1]==0: pre = self.pre2_4 else: pre = self.pre3_8 return pre.input_load()