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Implemented multiplier circuits, verilog and cgp export generation and changed generator's structure. Prone to error! Needs proper testing. TBD

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honzastor 2021-03-01 21:32:29 +01:00
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commit e4722c662d
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314
arithmetic_circuits.py Normal file
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from logic_gates import logic_gate, and_gate, nand_gate, or_gate, nor_gate, xor_gate, xnor_gate, not_gate
from wire_components import wire, bus
import itertools
""" ARITHMETIC CIRCUITS """
class arithmetic_circuit():
def __init__(self):
self.components = []
self.circuit_wires = []
self.circuit_gates = []
self.c_data_type = "uint64_t"
self.N = 1
# TODO delete?
self.carry_out_gate = None
self.sum_out_gates = []
def add_component(self, component):
self.components.append(component)
def get_previous_component(self, number: int = 1):
return self.components[-number]
def get_component_types(self):
return list({type(c): c for c in self.components}.values())
def get_unique_types(self):
hier_components = self.components_gates + self.component_types
return list({type(c): c for c in hier_components}.values())
def get_gate_types(self):
return list({type(g): g for g in self.components_gates}.values())
def get_previous_partial_product(self, a_index: int, b_index: int):
index = ((b_index-2) * (self.N*2)) + ((self.N-1)+2*(a_index+2))
if a_index == self.N-1:
index = index-2
return self.components[index].get_carry_wire()
else:
return self.components[index].get_sum_wire()
def get_sum_wire(self):
return self.out.get_wire(0)
def get_carry_wire(self):
return self.out.get_wire(1)
def get_circuit_wires(self):
for component in self.components:
if not [item for item in self.circuit_wires if item[1] == component.a.name]:
self.circuit_wires.append((component.a, component.a.name, len(self.circuit_wires)))
if not [item for item in self.circuit_wires if item[1] == component.b.name]:
self.circuit_wires.append((component.b, component.b.name, len(self.circuit_wires)))
if not [item for item in self.circuit_wires if item[1] == component.out.name]:
self.circuit_wires.append((component.out, component.out.name, len(self.circuit_wires)))
# Search for circuit's wire unique index for cgp chromosome generation
def get_circuit_wire_index(self, wire: wire):
for w in self.circuit_wires:
if wire.name.endswith(w[1]):
return w[2]
# Get list of all gates present in circuit
def get_circuit_gates(self):
gates = []
# TODO CHANGE SIGNED MULTIPLIER IMPLEMENTATION (REPLACE CONSTANT WIRE FOR EXTRA GATES) FOR THIS TO BE DELETED
if hasattr(self, 'constant_wire'):
gates.append(xor_gate(a=self.a.get_wire(), b=self.b.get_wire(), prefix=self.prefix+"_xor_constant_wire"))
gates.append(xnor_gate(a=self.a.get_wire(), b=self.b.get_wire(), prefix=self.prefix+"_xnor_constant_wire"))
gates.append(or_gate(a=gates[0].out, b=gates[1].out, prefix=self.prefix+"_or_constant_wire"))
gates[2].out.name = "constant_wire"
for c in self.components:
if isinstance(c, logic_gate):
gates.append(c)
else:
gates.extend((c.get_circuit_gates()))
return gates
# Get list of all wires in circuit along with their index position for cgp chromosome generation
def get_cgp_wires(self):
if isinstance(self.a, bus):
[self.circuit_wires.append((w, f"_{w.name}", len(self.circuit_wires))) for w in self.a.bus]
[self.circuit_wires.append((w, f"_{w.name}", len(self.circuit_wires))) for w in self.b.bus]
else:
self.circuit_wires.append((self.a, f"_{self.a.name}", len(self.circuit_wires)))
self.circuit_wires.append((self.b, f"_{self.b.name}", len(self.circuit_wires)))
if hasattr(self, 'c'):
self.circuit_wires.append((self.c, f"_{self.c.name}", len(self.circuit_wires)))
for gate in self.circuit_gates:
if not [item for item in self.circuit_wires if gate.a.name.endswith(item[1])]:
self.circuit_wires.append((gate.a, gate.a.name, len(self.circuit_wires)))
if not [item for item in self.circuit_wires if gate.b.name.endswith(item[1])]:
self.circuit_wires.append((gate.b, gate.b.name, len(self.circuit_wires)))
if not [item for item in self.circuit_wires if gate.out.name.endswith(item[1])]:
self.circuit_wires.append((gate.out, gate.out.name, len(self.circuit_wires)))
""" C CODE GENERATION """
# FLAT C #
@staticmethod
def get_includes_c():
return f"#include <stdio.h>\n#include <stdint.h>\n\n"
def get_prototype_c(self):
return f"{self.c_data_type} {self.prefix}({self.c_data_type} {self.a.prefix}, {self.c_data_type} {self.b.prefix})" + "{" + "\n"
def get_declaration_c_flat(self):
return f"".join([c.get_declaration_c_flat() for c in self.components])
def get_init_c_flat(self):
return "".join([c.get_assign_c_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix) if isinstance(c, logic_gate) else c.get_init_c_flat() for c in self.components])
def get_function_out_c_flat(self):
return "".join([f" {self.out.prefix} |= {o.return_wire_value_c(offset=self.out.bus.index(o))};\n" for o in self.out.bus])
# Generating flat C code representation of circuit
def get_c_code_flat(self, file_object):
file_object.write(self.get_includes_c())
file_object.write(self.get_prototype_c())
file_object.write(self.out.get_declaration_c())
file_object.write(self.get_declaration_c_flat()+"\n")
file_object.write(self.get_init_c_flat()+"\n")
file_object.write(self.get_function_out_c_flat())
file_object.write(f" return {self.out.prefix}"+";\n}")
file_object.close()
# HIERARCHICAL C #
def get_function_blocks_c(self):
# Add unique 1-bit adder components (ha, fa)
self.component_types = self.get_component_types()
# Add unique logic gates composing subcomponents
self.components_gates = list(itertools.chain.from_iterable([c.get_component_types() for c in self.component_types]))
self.component_types = self.get_unique_types()
return "".join([c.get_function_block_c() for c in self.component_types])
def get_declaration_c_hier(self):
return "".join(self.a.get_wire_declaration_c()) + \
"".join(self.b.get_wire_declaration_c()) + \
"".join([c.out.get_declaration_c() if isinstance(c, logic_gate) else c.out.get_wire_declaration_c() for c in self.components])
def get_init_c_hier(self):
return ";\n".join([f" {w.name} = " + w.get_wire_value_c(offset=w.index, prefix=w.prefix) for w in self.a.bus]) + ";\n" + \
";\n".join([f" {w.name} = " + w.get_wire_value_c(offset=w.index, prefix=w.prefix) for w in self.b.bus]) + ";\n" + \
"\n".join([f" {c.out.name} = {c.get_gate_invocation_c(a=c.a, b=c.b, get_index=True)}" if isinstance(c, logic_gate) else c.get_out_invocation_c() for c in self.components])
def get_function_out_c_hier(self):
return "".join([f" {self.out.prefix} |= {o.return_wire_value_c(offset=self.out.bus.index(o))};\n" for o in self.out.bus])
def get_circuit_c(self):
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}" + \
f"{self.get_declaration_c_hier()}\n" + \
f"{self.get_init_c_hier()}\n\n" + \
f"{self.get_function_out_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
# Generating hierarchical C code representation of circuit
def get_c_code_hier(self, file_object):
file_object.write(self.get_includes_c())
file_object.write(self.get_function_blocks_c())
file_object.write(self.get_circuit_c())
file_object.close()
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input [{self.N-1}:0] {self.a.prefix}, input [{self.N-1}:0] {self.b.prefix}, output [{self.out.N-1}:0] {self.out.prefix});\n"
def get_declaration_v_flat(self):
return f"".join([c.get_declaration_v_flat() for c in self.components])
def get_init_v_flat(self, offset: int = 0, array: bool = False):
return "\n".join([c.get_assign_v_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix, offset=offset, array=True) if isinstance(c, logic_gate) else c.get_init_v_flat(offset=self.components.index(c), array=array) for c in self.components]) + "\n"
def get_function_out_v_flat(self):
return "".join([f" assign {self.out.prefix}[{self.out.bus.index(o)}] = {o.prefix};\n" for o in self.out.bus])
# Generating flat V code representation of circuit
def get_v_code_flat(self, file_object):
file_object.write(self.get_prototype_v())
file_object.write(self.get_declaration_v_flat()+"\n")
file_object.write(self.get_init_v_flat(array=False)+"\n")
file_object.write(self.get_function_out_v_flat())
file_object.write(f"endmodule")
file_object.close()
# HIERARCHICAL VERILOG #
def get_function_blocks_v(self):
# Add unique 1-bit adder components (ha, fa)
self.component_types = self.get_component_types()
# Add unique logic gates composing subcomponents
self.components_gates = list(itertools.chain.from_iterable([c.get_component_types() for c in self.component_types]))
self.component_types = self.get_unique_types()
return "".join([c.get_function_block_v() for c in self.component_types])
def get_declaration_v_hier(self):
return "".join(self.a.get_wire_declaration_v()) + \
"".join(self.b.get_wire_declaration_v()) + \
"".join([c.out.get_declaration_v() if isinstance(c, logic_gate) else c.out.get_wire_declaration_v() for c in self.components])
def get_init_v_hier(self):
return ";\n".join([f" assign {w.name} = " + w.get_wire_value_v(offset=w.index, prefix=w.prefix, array=True) for w in self.a.bus]) + ";\n" + \
";\n".join([f" assign {w.name} = " + w.get_wire_value_v(offset=w.index, prefix=w.prefix, array=True) for w in self.b.bus]) + ";\n" + \
"\n".join([f"{c.get_gate_invocation_v(a=c.a, b=c.b, out=c.out, get_index=True)}" if isinstance(c, logic_gate) else c.get_invocation_v() for c in self.components]) + "\n"
def get_function_out_v_hier(self):
return "".join([f" assign {self.out.prefix}[{self.out.bus.index(o)}] = {o.name};\n" for o in self.out.bus])
def get_circuit_v(self):
return f"{self.get_prototype_v()}" + \
f"{self.get_declaration_v_hier()}\n" + \
f"{self.get_init_v_hier()}\n" + \
f"{self.get_function_out_v_hier()}" + \
f"endmodule"
# Generating hierarchical C code representation of circuit
def get_v_code_hier(self, file_object):
file_object.write(self.get_function_blocks_v())
file_object.write(self.get_circuit_v())
file_object.close()
""" CGP CODE GENERATION """
# FLAT CGP #
def get_parameters_cgp(self):
self.circuit_gates = self.get_circuit_gates()
return f"{{1,{len(self.circuit_gates)},2,1,0}}"
def get_triplet_cgp(self):
self.get_cgp_wires()
return "".join([g.get_triplet_cgp(a_index=self.get_circuit_wire_index(g.a), b_index=self.get_circuit_wire_index(g.b)) for g in self.circuit_gates])
def get_output_cgp(self):
return "(" + ",".join([str(self.get_circuit_wire_index(o)) for o in self.out.bus[::-1]]) + ")"
def get_cgp_code(self, file_object):
file_object.write(self.get_parameters_cgp())
file_object.write(self.get_triplet_cgp())
file_object.write(self.get_output_cgp())
file_object.close()
""" SIGNED ARITHMETIC CIRCUITS """
class signed_adder_circuit(arithmetic_circuit):
def __init__(self):
super().__init__()
# TODO TRY TO THINK ABOUT A WAY TO MORE EFFICIENTLY GENERATE OUTPUT FORMATS FOR EXTRA SIGN XOR INVOCATIONS
""" C CODE GENERATION """
# FLAT C #
# Initialization of 1-bit adders and sign extension XOR gates
def get_init_c_flat(self):
return "".join([c.get_init_c_flat() for c in self.components if isinstance(c, arithmetic_circuit)]) + \
f"{self.get_previous_component(number=2).get_assign_c_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix, offset=self.N-1)}" + \
f"{self.get_previous_component().get_assign_c_flat(prefix_a=self.get_previous_component(number=2).out.prefix, prefix_b=self.get_previous_component(number=3).get_carry_wire().prefix)}"
# HIERARCHICAL C #
def get_init_c_hier(self):
return ";\n".join([f" {w.name} = " + w.get_wire_value_c(offset=w.index, prefix=w.prefix) for w in self.a.bus]) + ";\n" + \
";\n".join([f" {w.name} = " + w.get_wire_value_c(offset=w.index, prefix=w.prefix) for w in self.b.bus]) + ";\n" + \
"\n".join([f" {c.out.name} = {c.get_gate_invocation_c(a=c.a, b=c.b, get_index=True)}" if isinstance(c, logic_gate) else c.get_out_invocation_c() for c in self.components[:-1]]) + "\n" + \
f" {self.get_previous_component().out.name} = {self.get_previous_component().get_gate_invocation_c(a=self.get_previous_component(number=2).out, b=self.get_previous_component(number=3).get_carry_wire())}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
# Initialization of 1-bit adders and sign extension XOR gates
def get_init_v_flat(self, offset: int = 0, array: bool = False):
return f"\n".join([c.get_init_v_flat(offset=self.components.index(c), array=True) for c in self.components[:-2]]) + "\n" + \
f"{self.get_previous_component(number=2).get_assign_v_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix, offset=self.N-1, array=True)}" + \
f"{self.get_previous_component().get_assign_v_flat(prefix_a=self.get_previous_component(number=2).out.name, prefix_b=self.get_previous_component(number=3).get_carry_wire().name, offset=offset, array=array)}"
# HIERARCHICAL VERILOG #
def get_init_v_hier(self):
return ";\n".join([f" assign {w.name} = " + w.get_wire_value_v(offset=w.index, prefix=w.prefix, array=True) for w in self.a.bus]) + ";\n" + \
";\n".join([f" assign {w.name} = " + w.get_wire_value_v(offset=w.index, prefix=w.prefix, array=True) for w in self.b.bus]) + ";\n" + \
"\n".join([f"{c.get_gate_invocation_v(a=c.a, b=c.b, out=c.out, get_index=True)}" if isinstance(c, logic_gate) else c.get_invocation_v() for c in self.components[:-1]]) + "\n" + \
f"{self.get_previous_component().get_gate_invocation_v(a=self.get_previous_component(number=2).out, b=self.get_previous_component(number=3).get_carry_wire(), out=self.get_previous_component().out)}\n"
class signed_multiplier_circuit(arithmetic_circuit):
def __init__(self):
super().__init__()
# TODO CHANGE SIGNED MULTIPLIER CIRCUIT (REPLACE CONSTANT WIRE WITH LOGIC GATES)
# C CODE GENERATION
# FLAT C #
def get_declaration_c_flat(self):
return super().get_declaration_c_flat() + \
f"{self.constant_wire.get_declaration_c()}"
# HIERARCHICAL C #
def get_declaration_c_hier(self):
return super().get_declaration_c_hier() + \
f"{self.constant_wire.get_declaration_c()}"
# VERILOG CODE GENERATION
# FLAT VERILOG #
def get_declaration_v_flat(self):
return super().get_declaration_v_flat() + \
f"{self.constant_wire.get_declaration_init_v()}"
# HIERARCHICAL V #
def get_declaration_v_hier(self):
return super().get_declaration_v_hier() + \
f"{self.constant_wire.get_declaration_init_v()}"

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arithmetic_circuits_generator.py
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@ -1,580 +1,125 @@
from wire_components import wire, bus
from logic_gates_generator import not_gate, and_gate, xor_gate, or_gate, nand_gate, xnor_gate, nor_gate
from logic_gates import logic_gate, and_gate, nand_gate, or_gate, nor_gate, xor_gate, xnor_gate, not_gate
from one_bit_circuits import half_adder, full_adder
from multi_bit_circuits import unsigned_ripple_carry_adder, signed_ripple_carry_adder, unsigned_array_multiplier, signed_array_multiplier
import sys
import itertools
""" ARITHMETIC CIRCUITS """
class arithmetic_circuit():
def __init__(self):
self.components = []
self.circuit_wires = []
self.c_data_type = "uint64_t"
self.N = 1
# TODO delete?
self.carry_out_gate = None
self.sum_out_gates = []
def add_component(self, component):
self.components.append(component)
def get_previous_component(self):
return self.components[-1]
def get_component_types(self):
return list({type(c): c for c in self.components}.values())
def get_unique_types(self):
hier_components = self.all_gates + self.component_types
return list({type(c): c for c in hier_components}.values())
def get_gate_types(self):
return list({type(g): g for g in self.all_gates}.values())
def get_sum_wire(self):
return self.out.get_wire(0)
def get_carry_wire(self):
return self.out.get_wire(1)
def get_circuit_wires(self):
for component in self.components:
if not [item for item in self.circuit_wires if item[1] == component.a.name]:
self.circuit_wires.append((component.a, component.a.name))
if not [item for item in self.circuit_wires if item[1] == component.b.name]:
self.circuit_wires.append((component.b, component.b.name))
if not [item for item in self.circuit_wires if item[1] == component.output.name]:
self.circuit_wires.append((component.output, component.output.name))
""" C CODE GENERATION """
# FLAT C #
@staticmethod
def get_includes_c():
return f"#include <stdio.h>\n#include <stdint.h>\n\n"
def get_prototype_c(self):
return f"uint64_t {self.prefix}({self.c_data_type} {self.a.prefix}, {self.c_data_type} {self.b.prefix})" + "{" + "\n"
def get_declaration_c_flat(self):
return f"".join([c.get_declaration_c_flat() for c in self.components])
def get_init_c_flat(self):
return "".join([c.get_init_c_flat() for c in self.components])
def get_function_sum_c_flat(self):
return "".join([c.get_function_sum_c_flat(offset=self.components.index(c)) for c in self.components])
def get_function_carry_c_flat(self):
return f"{self.get_previous_component().get_function_carry_c_flat(offset=self.out.N-1)}"
# Generating flat C code representation of circuit
def get_c_code_flat(self, file_object):
file_object.write(self.get_includes_c())
file_object.write(self.get_prototype_c())
file_object.write(self.out.get_declaration_c())
file_object.write(self.get_declaration_c_flat()+"\n")
file_object.write(self.get_init_c_flat()+"\n")
file_object.write(self.get_function_sum_c_flat())
file_object.write(self.get_function_carry_c_flat())
file_object.write(f" return {self.out.prefix}"+";\n}")
file_object.close()
# HIERARCHICAL C #
def get_function_blocks_c(self):
# Add unique 1-bit adder components (ha, fa)
self.component_types = self.get_component_types()
# Add unique logic gates composing subcomponents
self.all_gates = list(itertools.chain.from_iterable([c.get_component_types() for c in self.component_types]))
self.component_types = self.get_unique_types()
return "".join([c.get_function_block_c() for c in self.component_types])
def get_declaration_c_hier(self):
self.cout = bus(N=self.N-1, prefix="cout")
return "".join(self.a.get_wire_declaration_c()) + \
"".join(self.b.get_wire_declaration_c()) + \
"".join(self.cout.get_wire_declaration_c())
def get_init_sum_c_hier(self):
self.in_wires = self.a.bus + self.b.bus
return ";\n".join([f" {w.name} = " + w.get_wire_value_c(offset=int(w.name[2:])) for w in self.in_wires])
def get_init_cout_c_hier(self):
return "\n".join([c.get_invocation_c(wire_n=self.cout.get_wire(self.components.index(c)).name, offset=self.components.index(c)) for c in self.components[:-1]])
def get_function_sum_c_hier(self):
return ";\n".join([c.get_adder_sum(offset=self.components.index(c)) for c in self.components])+";\n"
def get_function_carry_c_hier(self):
return f"{self.get_previous_component().get_adder_cout(offset=self.out.N-1)};\n"
def get_circuit_c(self):
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}" + \
f"{self.get_declaration_c_hier()}\n" + \
f"{self.get_init_sum_c_hier()};\n" + \
f"{self.get_init_cout_c_hier()}\n\n" + \
f"{self.get_function_sum_c_hier()}" + \
f"{self.get_function_carry_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
# Generating hierarchical C code representation of circuit
def get_c_code_hier(self, file_object):
file_object.write(self.get_includes_c())
file_object.write(self.get_function_blocks_c())
file_object.write(self.get_circuit_c())
file_object.close()
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input [{self.N-1}:0] {self.a.prefix}, input [{self.N-1}:0] {self.b.prefix}, output [{self.N}:0] {self.out.prefix});\n"
def get_declaration_v_flat(self):
return f"".join([c.get_declaration_v_flat() for c in self.components])
def get_init_v_flat(self, offset: int = 0, array: bool = False):
return "".join([c.get_init_v_flat(offset=self.components.index(c), array=True) for c in self.components])
def get_function_sum_cout_v_flat(self):
return "".join([c.get_function_sum_cout_v_flat(offset=self.components.index(c)) for c in self.components])
def get_function_sum_v_flat(self):
return "".join([c.get_function_sum_v_flat(offset=self.components.index(c)) for c in self.components])
def get_function_carry_v_flat(self):
return f"{self.get_previous_component().get_function_carry_v_flat(offset=self.out.N-1)}"
# Generating flat V code representation of circuit
def get_v_code_flat(self, file_object):
file_object.write(self.get_prototype_v())
file_object.write(self.get_declaration_v_flat()+"\n")
file_object.write(self.get_init_v_flat(array=False)+"\n")
file_object.write(self.get_function_sum_v_flat())
file_object.write(self.get_function_carry_v_flat())
file_object.write(f"endmodule")
file_object.close()
class half_adder(arithmetic_circuit):
def __init__(self, a: wire, b: wire, prefix: str = "ha"):
super().__init__()
self.c_data_type = "uint8_t"
self.prefix = prefix
self.a = a
self.b = b
# 2 wires for component's bus output (sum, cout)
self.out = bus("out", self.N+1)
# Sum
# XOR gate for calculation of 1-bit sum
obj_xor_gate = xor_gate(a, b, prefix, outid=0)
self.add_component(obj_xor_gate)
self.out.connect(0, obj_xor_gate.output)
# Cout
# AND gate for calculation of 1-bit cout
obj_and_gate = and_gate(a, b, prefix, outid=1)
self.add_component(obj_and_gate)
self.out.connect(1, obj_and_gate.output)
""" C CODE GENERATION """
# FLAT C #
# Half adder function prototype with two inputs
def get_prototype_c(self):
return f"{self.c_data_type} {self.prefix}({self.c_data_type} {self.a.name}, {self.c_data_type} {self.b.name})" + "{" + "\n"
# Obtaining list of all the unique circuit wires from all contained logic gates
# to ensure non-recurring declaration of same wires
def get_declaration_c_flat(self):
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_c() for c in self.circuit_wires])
# Half adder wires values initialization
def get_init_c_flat(self):
# self.a.prefix = self.a.name if self.a.prefix == "" else self.a.prefix
# self.b.prefix = self.b.name if self.b.prefix == "" else self.b.prefix
return f" {self.components[0].a.name} = {self.a.get_wire_value_c(offset=self.a.index)};\n" + \
f" {self.components[0].b.name} = {self.b.get_wire_value_c(offset=self.b.index)};\n" + \
f" {self.components[0].output.name} = {self.components[0].get_init_c_flat()};\n" + \
f" {self.components[1].output.name} = {self.components[1].get_init_c_flat()};\n"
def get_function_sum_c_flat(self, offset: int = 0):
return f" {self.out.prefix} |= {self.components[0].output.return_wire_value_c(offset=offset)};\n"
def get_function_carry_c_flat(self, offset: int = 1):
return f" {self.out.prefix} |= {self.components[1].output.return_wire_value_c(offset=offset)};\n"
# HIERARCHICAL C #
def get_function_block_c(self):
self.component_types = self.get_component_types()
self.prefix = "ha"
return f"{self.get_circuit_c()}\n\n"
def get_function_blocks_c(self):
self.component_types = self.get_component_types()
return "".join([c.get_function_block_c() for c in self.component_types])
def get_invocation_c(self, wire_n: str, offset: int = 0):
self.prefix = "ha" if (offset == 0) else "fa"
return f" {wire_n} = ({self.prefix}({self.a.name}, {self.b.name}) >> 1) & 0x01;"
def get_adder_sum(self, offset: int = 0):
return f" {self.out.prefix} |= (({self.prefix}({self.a.name}, {self.b.name}) >> 0) & 0x01) << {offset}"
def get_adder_cout(self, offset: int = 1):
return f" {self.out.prefix} |= (({self.prefix}({self.a.name}, {self.b.name}) >> 1) & 0x01) << {offset}"
def get_function_sum_c_hier(self, offset: int = 0):
return f" {self.out.prefix} |= {self.component_types[0].get_gate_output_c(a=self.a ,b=self.b, offset=offset)};\n"
def get_function_carry_c_hier(self, offset: int = 1):
return f" {self.out.prefix} |= {self.component_types[1].get_gate_output_c(a=self.a ,b=self.b, offset=offset)};\n"
def get_circuit_c(self):
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}\n" + \
f"{self.get_function_sum_c_hier()}" + \
f"{self.get_function_carry_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input {self.a.name}, input {self.b.name}, output [{self.N}:0]{self.out.prefix});\n"
def get_declaration_v_flat(self):
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_v() for c in self.circuit_wires])
# Half adder wires values initialization
def get_init_v_flat(self, offset: int = 0, array: bool = False, ):
self.a.prefix = self.a.name if self.a.prefix == "" else self.a.prefix
self.b.prefix = self.b.name if self.b.prefix == "" else self.b.prefix
return f" assign {self.components[0].a.name} = {self.a.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[0].b.name} = {self.b.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[0].output.name} = {self.components[0].get_init_v_flat()};\n" + \
f" assign {self.components[1].output.name} = {self.components[1].get_init_v_flat()};\n"
def get_function_sum_v_flat(self, offset: int = 0):
return f" assign {self.out.prefix}[{offset}] = {self.components[0].output.name};\n"
def get_function_carry_v_flat(self, offset: int = 1):
return f" assign {self.out.prefix}[{offset}] = {self.components[1].output.name};\n"
class full_adder(arithmetic_circuit):
def __init__(self, a: wire, b: wire, c: wire, prefix: str = "fa"):
super().__init__()
self.c_data_type = "uint8_t"
self.prefix = prefix
self.a = a
self.b = b
self.c = c
# 2 wires for component's bus output (sum, cout)
self.out = bus("out", self.N+1)
# PG logic
propagate_xor_gate1 = xor_gate(a, b, prefix, outid=0)
self.add_component(propagate_xor_gate1)
generate_and_gate1 = and_gate(a, b, prefix, outid=1)
self.add_component(generate_and_gate1)
# Sum
# XOR gate for calculation of 1-bit sum
obj_xor_gate2 = xor_gate(propagate_xor_gate1.output, c, prefix, outid=2)
self.add_component(obj_xor_gate2)
self.out.connect(0, obj_xor_gate2.output)
# Cout
# AND gate for calculation of 1-bit cout
obj_and_gate2 = and_gate(propagate_xor_gate1.output, c, prefix, outid=3)
self.add_component(obj_and_gate2)
obj_or_gate = or_gate(generate_and_gate1.output, obj_and_gate2.output, prefix, outid=4)
self.add_component(obj_or_gate)
self.out.connect(1, obj_or_gate.output)
# TODO delete or leave?
self.propagate = propagate_xor_gate1.output
self.generate = generate_and_gate1.output
""" C CODE GENERATION """
# FLAT C #
# Full adder function prototype with three inputs
def get_prototype_c(self):
return f"{self.c_data_type} {self.prefix}({self.c_data_type} {self.a.name}, {self.c_data_type} {self.b.name}, {self.c_data_type} {self.c.name})" + "{" + "\n"
# Obtaining list of all the unique circuit wires from all contained logic gates
# to ensure non-recurring declaration of same wires
def get_declaration_c_flat(self):
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_c() for c in self.circuit_wires])
# Full adder wires values initialization
def get_init_c_flat(self):
self.a.prefix = self.a.name if self.a.prefix == "" else self.a.prefix
self.b.prefix = self.b.name if self.b.prefix == "" else self.b.prefix
self.c.prefix = self.c.name
return f" {self.components[0].a.name} = {self.a.get_wire_value_c(offset=self.a.index)};\n" + \
f" {self.components[0].b.name} = {self.b.get_wire_value_c(offset=self.b.index)};\n" + \
f" {self.components[2].b.name} = {self.c.get_wire_value_c()};\n" + \
f" {self.components[0].output.name} = {self.components[0].get_init_c_flat()};\n" + \
f" {self.components[1].output.name} = {self.components[1].get_init_c_flat()};\n" + \
f" {self.components[2].output.name} = {self.components[2].get_init_c_flat()};\n" + \
f" {self.components[3].output.name} = {self.components[3].get_init_c_flat()};\n" + \
f" {self.components[4].output.name} = {self.components[4].get_init_c_flat()};\n"
def get_function_sum_c_flat(self, offset: int = 0):
return f" {self.out.prefix} |= {self.components[2].output.return_wire_value_c(offset=offset)};\n"
def get_function_carry_c_flat(self, offset: int = 1):
return f" {self.out.prefix} |= {self.components[4].output.return_wire_value_c(offset=offset)};\n"
# HIERARCHICAL C #
def get_function_block_c(self):
self.component_types = self.get_component_types()
self.prefix = "fa"
self.c.name = "cin"
return f"{self.get_circuit_c()}\n\n"
def get_function_blocks_c(self):
self.component_types = self.get_component_types()
return "".join([c.get_function_block_c() for c in self.component_types])
def get_declaration_c_hier(self):
self.component_types[0].a.name = "xor_1"
self.component_types[2].a.name = "and_1"
self.component_types[2].b.name = "and_2"
return f"{self.component_types[0].a.get_declaration_c()}" + \
f"{self.component_types[2].a.get_declaration_c()}" + \
f"{self.component_types[2].b.get_declaration_c()}"
def get_init_c_hier(self):
return f" {self.component_types[0].a.name} = {self.component_types[0].get_invocation_c(self.a, self.b)}\n" + \
f" {self.component_types[2].a.name} = {self.component_types[1].get_invocation_c(self.a, self.b)}\n" + \
f" {self.component_types[2].b.name} = {self.component_types[1].get_invocation_c(self.component_types[0].a, self.c)}\n"
def get_invocation_c(self, wire_n: str, offset: int = 0):
self.prefix = "ha" if (offset == 0) else "fa"
self.c.name = "cout_"+str(offset-1)
return f" {wire_n} = ({self.prefix}({self.a.name}, {self.b.name}, {self.c.name}) >> 1) & 0x01;"
def get_adder_sum(self, offset: int = 0):
self.c.name = "cout_"+str(offset-1)
return f" {self.out.prefix} |= (({self.prefix}({self.a.name}, {self.b.name}, {self.c.name}) >> 0) & 0x01) << {offset}"
def get_adder_cout(self, offset: int = 1):
self.c.name = "cout_"+str(offset-2)
return f" {self.out.prefix} |= (({self.prefix}({self.a.name}, {self.b.name}, {self.c.name}) >> 1) & 0x01) << {offset}"
def get_function_sum_c_hier(self, offset: int = 0):
return f" {self.out.prefix} |= {self.component_types[0].get_gate_output_c(a=self.component_types[0].a, b=self.c, offset=offset)};\n"
def get_function_carry_c_hier(self, offset: int = 1):
return f" {self.out.prefix} |= {self.component_types[-1].get_gate_output_c(a=self.component_types[2].a, b=self.component_types[2].b, offset=offset)};\n"
def get_circuit_c(self):
self.component_types = self.component_types
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}" + \
f"{self.get_declaration_c_hier()}\n" + \
f"{self.get_init_c_hier()}\n" + \
f"{self.get_function_sum_c_hier()}" + \
f"{self.get_function_carry_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input {self.a.name}, input {self.b.name}, input {self.c.name}, output [{self.N}:0]{self.out.prefix});\n"
def get_declaration_v_flat(self):
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_v() for c in self.circuit_wires])
# Full adder wires values initialization
def get_init_v_flat(self, offset: int = 0, array: bool = False):
self.a.prefix = self.a.name if self.a.prefix == "" else self.a.prefix
self.b.prefix = self.b.name if self.b.prefix == "" else self.b.prefix
self.c.prefix = self.c.name
return f" assign {self.components[0].a.name} = {self.a.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[0].b.name} = {self.b.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[2].b.name} = {self.c.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[0].output.name} = {self.components[0].get_init_v_flat()};\n" + \
f" assign {self.components[1].output.name} = {self.components[1].get_init_v_flat()};\n" + \
f" assign {self.components[2].output.name} = {self.components[2].get_init_v_flat()};\n" + \
f" assign {self.components[3].output.name} = {self.components[3].get_init_v_flat()};\n" + \
f" assign {self.components[4].output.name} = {self.components[4].get_init_v_flat()};\n"
def get_function_sum_v_flat(self, offset: int = 0):
return f" assign {self.out.prefix}[{offset}] = {self.components[2].output.name};\n"
def get_function_carry_v_flat(self, offset: int = 1):
return f" assign {self.out.prefix}[{offset}] = {self.components[4].output.name};\n"
class signed_ripple_carry_adder(arithmetic_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "s_rca"):
super().__init__()
self.N = max(a.N, b.N)
self.c_data_type = "int64_t"
# Bus sign extension in case buses have different lengths
a.bus_extend(N=self.N, prefix=a.prefix)
b.bus_extend(N=self.N, prefix=b.prefix)
self.a = a
self.b = b
if prefix == "s_rca":
self.prefix = prefix+str(self.N)
else:
self.prefix = prefix
# Output wires for N sum bits and additional cout bit
self.out = bus("out", self.N+1)
# Gradual addition of 1-bit adder components
for input_index in range(self.N):
# First one is a half adder
if input_index == 0:
obj_ha = half_adder(a.get_wire(input_index), b.get_wire(input_index), prefix=self.prefix+"_ha")
self.add_component(obj_ha)
self.out.connect(input_index, obj_ha)
# Rest are full adders
else:
obj_fa = full_adder(a.get_wire(input_index), b.get_wire(input_index), self.get_previous_component().get_carry_wire(), prefix=self.prefix+"_fa"+str(input_index))
self.add_component(obj_fa)
self.out.connect(input_index, obj_fa.get_sum_wire())
if input_index == (self.N-1):
self.out.connect(self.N, obj_fa.get_carry_wire())
# Additional XOR gates to ensure correct sign extension in case of sign addition
sign_xor_1 = xor_gate(self.get_previous_component().a, self.get_previous_component().b, prefix=self.prefix+"_xor_1")
sign_xor_2 = xor_gate(sign_xor_1.output, self.get_previous_component().get_carry_wire(), prefix=self.prefix+"_xor_2")
self.add_component(sign_xor_1)
self.add_component(sign_xor_2)
""" VERILOG CODE GENERATION """
# FLAT C #
# Initialization of 1-bit adders and sign extension XOR gates
def get_init_c_flat(self):
self.components[-2].output.prefix = self.components[-2].output.name
self.components[-3].get_carry_wire().prefix = self.components[-3].get_carry_wire().name
return f"".join([c.get_init_c_flat() for c in self.components[:-2]]) + \
f" {self.components[-2].a.name} = {self.a.get_wire_value_c(offset=self.N-1)};\n" + \
f" {self.components[-2].b.name} = {self.b.get_wire_value_c(offset=self.N-1)};\n" + \
f" {self.components[-2].output.name} = {self.components[-2].get_init_c_flat()};\n" + \
f" {self.components[-1].a.name} = {self.components[-2].output.get_wire_value_c()};\n" + \
f" {self.components[-1].b.name} = {self.components[-3].get_carry_wire().get_wire_value_c()};\n" + \
f" {self.components[-1].output.name} = {self.components[-1].get_init_c_flat()};\n"
def get_function_sum_c_flat(self):
return "".join([c.get_function_sum_c_flat(offset=self.components.index(c)) for c in self.components[:-2]])
def get_function_carry_c_flat(self):
return f" {self.out.prefix} |= {self.get_previous_component().output.return_wire_value_c(offset = self.N)};\n"
# HIERARCHICAL C #
def get_declaration_c_hier(self):
self.cout = bus(N=self.N, prefix="cout")
return "".join(self.a.get_wire_declaration_c()) + \
"".join(self.b.get_wire_declaration_c()) + \
"".join(self.cout.get_wire_declaration_c()) + \
f"{self.components[-2].output.get_declaration_c()}"
def get_init_cout_c_hier(self):
return "\n".join([c.get_invocation_c(wire_n=self.cout.get_wire(self.components.index(c)).name, offset=self.components.index(c)) for c in self.components[:-2]]) + \
f"\n {self.components[-2].output.name} = {self.components[-2].get_invocation_c(a=self.a.bus[-1], b=self.b.bus[-1])}"
def get_function_sum_c_hier(self):
return ";\n".join([c.get_adder_sum(offset=self.components.index(c)) for c in self.components[:-2]])+";\n"
def get_function_carry_c_hier(self):
return f" {self.out.prefix} |= {self.get_previous_component().get_gate_output_c(a=self.components[-2].output, b=self.cout.bus[-1], offset=self.out.N-1)};\n"
""" VERILOG CODE GENERATION """
# FLAT C #
# Initialization of 1-bit adders and sign extension XOR gates
def get_init_v_flat(self, offset: int = 0, array: bool = False):
self.components[-2].output.prefix = self.components[-2].output.name
self.components[-3].get_carry_wire().prefix = self.components[-3].get_carry_wire().name
return f"".join([c.get_init_v_flat(offset=self.components.index(c), array=True) for c in self.components[:-2]]) + \
f" assign {self.components[-2].a.name} = {self.a.get_wire_value_v(offset=self.N-1, array=True)};\n" + \
f" assign {self.components[-2].b.name} = {self.b.get_wire_value_v(offset=self.N-1, array=True)};\n" + \
f" assign {self.components[-2].output.name} = {self.components[-2].get_init_v_flat()};\n" + \
f" assign {self.components[-1].a.name} = {self.components[-2].output.get_wire_value_v(offset=offset, array=array)};\n" + \
f" assign {self.components[-1].b.name} = {self.components[-3].get_carry_wire().get_wire_value_v()};\n" + \
f" assign {self.components[-1].output.name} = {self.components[-1].get_init_v_flat()};\n"
def get_function_sum_v_flat(self, offset: int = 0):
return "".join([c.get_function_sum_v_flat(offset=self.components.index(c)) for c in self.components[:-2]])
def get_function_carry_v_flat(self):
return f" assign {self.out.prefix}[{self.N}] = {self.get_previous_component().output.return_wire_value_v(offset=self.N)};\n"
class unsigned_ripple_carry_adder(arithmetic_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "u_rca"):
super().__init__()
self.N = max(a.N, b.N)
# Bus sign extension in ase buses have different lengths
a.bus_extend(N=self.N, prefix=a.prefix)
b.bus_extend(N=self.N, prefix=b.prefix)
self.a = a
self.b = b
if prefix == "u_rca":
self.prefix = prefix+str(self.N)
else:
self.prefix = prefix
# Output wires for N sum bits and additional cout bit
self.out = bus("out", self.N+1)
# Gradual addition of 1-bit adder components
for input_index in range(self.N):
# First one is a half adder
if input_index == 0:
obj_ha = half_adder(a.get_wire(input_index), b.get_wire(input_index), prefix=self.prefix+"_ha")
self.add_component(obj_ha)
self.out.connect(input_index, obj_ha)
# Rest are full adders
else:
obj_fa = full_adder(a.get_wire(input_index), b.get_wire(input_index), self.get_previous_component().get_carry_wire(), prefix=self.prefix+"_fa"+str(input_index))
self.add_component(obj_fa)
self.out.connect(input_index, obj_fa.get_sum_wire())
if input_index == (self.N-1):
self.out.connect(self.N, obj_fa.get_carry_wire())
""" TESTING """
if __name__ == "__main__":
a = bus(N=8, prefix="a")
b = bus(N=8, prefix="b")
rca = unsigned_ripple_carry_adder(a, b, prefix="u_rca8")
# rca.get_c_code_hier(open("h_u_rca4.c", "w"))
# rca.get_c_code_flat(open("f_u_rca8.c", "w"))
rca.get_v_code_flat(open("f_u_rca8.v", "w"))
a = bus(N=20, prefix="a")
b = bus(N=1, prefix="b")
rca = signed_ripple_carry_adder(a, b, prefix="f_s_rca2")
rca.get_cgp_code(open("s_rca2.chr","w"))
#rca.get_v_code_hier(open("h_s_rca6.v", "w"))
#rca.get_v_code_flat(open("FLATTEST_u_rca3.v", "w"))
"""
rca.get_c_code_hier(open("h_s_rca8.c", "w"))
rca.get_c_code_flat(open("f_s_rca8.c", "w"))
rca.get_c_code_hier(open("h_s_rca8.c", "w"))
rca.get_c_code_flat(open("f_s_rca8.c", "w"))
rca.get_c_code_hier(open("h_s_rca8.c", "w"))
rca.get_v_code_hier(open("h_s_rca8.v", "w"))
rca.get_c_code_flat(open("f_s_rca8.c", "w"))
rca.get_v_code_flat(open("f_s_rca8.v", "w"))
"""
#arrmul = signed_array_multiplier(a, b, prefix="f_s_arr_mul3")
u_arrmul = unsigned_array_multiplier(a, b, prefix="h_u_arr_mul5")
#u_arrmul.get_cgp_code(open("u_arr_mul5.chr","w"))
s_arrmul = signed_array_multiplier(a, b)
s_arrmul.get_v_code_hier(open("testhier4.v","w"))
s_arrmul.get_v_code_flat(open("testflat4.v","w"))
s_arrmul.get_cgp_code(open("s_arr_mul20.chr","w"))
#s_arrmul.get_v_code_hier(open("h_s_arr_mul3.v","w"))
s_arrmul.get_c_code_hier(open("h_s_arr_mul5.c","w"))
s_arrmul.get_c_code_flat(open("f_s_arr_mul5.c","w"))
s_arrmul.get_v_code_hier(open("h_s_arr_mul5.v","w"))
s_arrmul.get_v_code_flat(open("f_s_arr_mul5.v","w"))
s_arrmul.get_c_code_hier(open("h_s_arr_mul5.c","w"))
s_arrmul.get_c_code_flat(open("f_s_arr_mul5.c","w"))
s_arrmul.get_v_code_hier(open("h_s_arr_mul5.v","w"))
s_arrmul.get_v_code_flat(open("f_s_arr_mul5.v","w"))
#u_arrmul.get_v_code_hier(open("h_u_arr_mul3.v","w"))
#s_arrmul.get_v_code_hier(open("h_s_arr_mul3.v","w"))
"""
arrmul.get_c_code_hier(open("h_s_arr_mul6.c","w"))
arrmul.get_c_code_flat(open("ff_s_arr_mul6.c","w"))
arrmul.get_c_code_hier(open("h_s_arr_mul6.c","w"))
arrmul.get_c_code_flat(open("ff_s_arr_mul6.c","w"))
"""
"""
rca.get_v_code_hier(open("h_s_rca8.v", "w"))
rca.get_v_code_flat(open("f_s_rca8.v", "w"))
rca.get_c_code_hier(open("h_s_rca2.c", "w"))
rca.get_v_code_hier(open("h_s_rca2.v", "w"))
rca.get_c_code_flat(open("f_s_rca2.c", "w"))
rca.get_v_code_flat(open("f_s_rca2.v", "w"))
"""
#rca.get_v_code_hier(open("h_u_rca3.v", "w"))
#rca.get_c_code_flat(open("f_u_rca3.c", "w"))
#rca.get_c_code_hier(open("hier_srca8.c", "w"))
#rca.get_c_code_flat(open("flat_srca8.c", "w"))
w1 = wire(name="a")
w2 = wire(name="b")
w3 = wire(name="cout")
fa = full_adder(w1, w2, w3, prefix="f_fa")
w3 = wire(name="cin")
ha = half_adder(w1, w2, prefix="f_ha")
fa = full_adder(w1, w2, w3, prefix="f_fa")
# ha.get_c_code_flat(open("f_ha.c","w"))
# ha.get_v_code_flat(open("f_ha.v","w"))
# fa.get_c_code_flat(open("f_fa.c","w"))
# fa.get_v_code_flat(open("f_fa.v","w"))
#ha.get_cgp_code(open("ha.chr","w"))
#fa.get_cgp_code(open("fa.chr","w"))
gate = not_gate(w1)
# gate.get_c_code(open("not_gate.c","w"))
# gate.get_v_code(open("not_gate.v","w"))
"""
ha.get_c_code_flat(open("f_ha.c","w"))
ha.get_v_code_flat(open("f_ha.v","w"))
fa.get_c_code_flat(open("f_fa.c","w"))
fa.get_v_code_hier(open("f_fa.v","w"))
"""
ha.get_v_code_hier(open("h_ha.v","w"))
fa.get_v_code_hier(open("h_fa.v","w"))
"""
ha.get_c_code_hier(open("h_ha.c","w"))
ha.get_c_code_flat(open("f_ha.c","w"))
ha.get_c_code_hier(open("h_ha.c","w"))
ha.get_c_code_flat(open("f_ha.c","w"))
fa.get_c_code_hier(open("h_fa.c","w"))
fa.get_c_code_flat(open("f_fa.c","w"))
fa.get_c_code_hier(open("h_fa.c","w"))
fa.get_c_code_flat(open("f_fa.c","w"))
ha.get_v_code_hier(open("h_ha.v","w"))
ha.get_v_code_flat(open("f_ha.v","w"))
ha.get_v_code_hier(open("h_ha.v","w"))
ha.get_v_code_flat(open("f_ha.v","w"))
fa.get_v_code_hier(open("h_fa.v","w"))
fa.get_v_code_flat(open("f_fa.v","w"))
fa.get_v_code_hier(open("h_fa.v","w"))
fa.get_v_code_flat(open("f_fa.v","w"))
"""
gate = and_gate(w1, w2)
#gate.get_cgp_code(open("and_gate.chr","w"))
#gate.get_c_code(open("and_gate.c","w"))
#gate.get_v_code(open("and_gate.v","w"))

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from wire_components import wire
""" LOGIC GATE COMPONENTS """
# Two-input #
class logic_gate():
def __init__(self, a: wire, b: wire, prefix: str = "gate"):
self.a = wire(name=prefix+"_"+a.name.replace(prefix+"_", ""), value=a.value)
self.b = wire(name=prefix+"_"+b.name.replace(prefix+"_", ""), value=b.value)
self.prefix = prefix
def get_component_types(self):
return list([self])
""" C CODE GENERATION """
# FLAT C #
@staticmethod
def get_includes_c():
return f"#include <stdio.h>\n#include <stdint.h>\n\n"
def get_prototype_c(self):
return f"uint8_t {self.gate_type}(uint8_t {self.a.name}, uint8_t {self.b.name})" + "{" + "\n"
def get_function_c(self):
return f"{self.a.get_wire_value_c()} {self.operator} {self.b.get_wire_value_c()}"
def get_declaration_c_flat(self):
return f"{self.a.get_declaration_c()}{self.b.get_declaration_c()}{self.out.get_declaration_c()}"
def get_init_c_flat(self):
return f"{self.a.name} {self.operator} {self.b.name}"
def get_assign_c_flat(self, prefix_a: str = "a", prefix_b: str = "b", offset: int = 0):
return f" {self.a.name} = {self.a.get_wire_value_c(prefix=prefix_a, offset=offset)};\n" + \
f" {self.b.name} = {self.b.get_wire_value_c(prefix=prefix_b, offset=offset)};\n" + \
f" {self.out.prefix} = {self.a.name} {self.operator} {self.b.name};\n"
# Generating flat C code representation of the logic gate itself
# (i.e. not as a component of bigger circuit)
def get_c_code(self, file_object):
file_object.write(self.get_includes_c())
file_object.write(self.get_prototype_c())
file_object.write(" return "+(self.get_function_c())+";\n}")
file_object.close()
# HIERARCHICAL C #
def get_function_block_c(self):
return f"{self.get_prototype_c()}" + \
f" return "+(self.get_function_c())+";\n}\n\n"
def get_gate_invocation_c(self, a: wire, b: wire, sign: bool = False, get_index: bool = False):
a_name = a.prefix if sign is False else a.name
b_name = b.prefix if sign is False else b.name
a_name = a_name if get_index is False else "a" + a.name[a.name.rfind("_"):]
b_name = b_name if get_index is False else "b" + b.name[b.name.rfind("_"):]
return f"{self.gate_type}({a_name}, {b_name});"
def get_gate_output_c(self, a: wire, b: wire, offset: int = 0, sign: bool = False):
a_name = a.prefix if sign is False else a.name
b_name = b.prefix if sign is False else b.name
return f"({self.gate_type}({a_name}, {b_name}) & 0x01) << {offset}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.gate_type}(input {self.a.name}, input {self.b.name}, output {self.out.name});\n"
def get_declaration_v_flat(self):
return f"{self.a.get_declaration_v()}{self.b.get_declaration_v()}{self.out.get_declaration_v()}"
def get_init_v_flat(self):
return f"{self.a.name} {self.operator} {self.b.name}"
def get_assign_v_flat(self, prefix_a: str = "a", prefix_b: str = "b", offset: int = 0, array: bool = False):
return f" assign {self.a.name} = {self.a.get_wire_value_v(prefix=prefix_a, offset=offset, array=array)};\n" + \
f" assign {self.b.name} = {self.b.get_wire_value_v(prefix=prefix_b, offset=offset, array=array)};\n" + \
f" assign {self.out.prefix} = {self.a.name} {self.operator} {self.b.name};"
# Generating flat Verilog code representation of the logic gate itself
# (i.e. not as a component of bigger circuit)
def get_v_code(self, file_object):
file_object.write(self.get_prototype_v())
file_object.write(f" assign {self.out.name} = {self.get_init_v_flat()};\n")
file_object.write(f"endmodule")
file_object.close()
# HIERARCHICAL VERILOG #
def get_function_block_v(self):
return f"{self.get_prototype_v()}" + \
f" assign {self.out.name} = {self.get_init_v_flat()};\n" + \
f"endmodule\n\n"
def get_gate_invocation_v(self, a: wire, b: wire, out: wire, sign: bool = False, get_index: bool = False, out_array: bool = False, offset: int = 0):
a_name = a.prefix if sign is False else a.name
b_name = b.prefix if sign is False else b.name
a_name = a_name if get_index is False else "a" + a.name[a.name.rfind("_"):]
b_name = b_name if get_index is False else "b" + b.name[b.name.rfind("_"):]
return f" {self.gate_type} {self.gate_type}_{out.name}({a_name}, {b_name}, {out.get_wire_value_v(offset=offset, array=out_array)});"
""" CGP CODE GENERATION """
# FLAT CGP #
@staticmethod
def get_parameters_cgp():
return "{1,1,2,1,0}"
def get_triplet_cgp(self, a_index: int = 0, b_index: int = 1):
return f"({a_index},{b_index},{self.cgp_function})"
@staticmethod
def get_output_cgp(out_index: int = 2):
return f"({out_index})"
def get_cgp_code(self, file_object):
file_object.write(self.get_parameters_cgp())
file_object.write(self.get_triplet_cgp())
file_object.write(self.get_output_cgp())
file_object.close()
class inverted_logic_gate(logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "gate"):
super().__init__(a, b, prefix)
""" C CODE GENERATION """
# FLAT C #
def get_function_c(self):
return "~("+(super().get_function_c())+") & 0x01 << 0"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_init_v_flat(self):
return "~("+(super().get_init_v_flat())+")"
class and_gate(logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "and_gate"
self.cgp_function = 2
self.operator = "&"
self.out = wire(name=prefix+"_y"+str(outid))
""" C CODE GENERATION """
# FLAT C #
def get_assign_c_flat(self, prefix_a: str = "a", prefix_b: str = "b"):
indexes = self.prefix[self.prefix.rfind("_", 0, self.prefix.rfind("_"))+1:]
offset_a = indexes[:indexes.rfind("_")]
offset_b = indexes[indexes.rfind("_")+1:]
return f" {self.a.name} = {self.a.get_wire_value_c(prefix=prefix_a, offset=offset_a)};\n" + \
f" {self.b.name} = {self.b.get_wire_value_c(prefix=prefix_b, offset=offset_b)};\n" + \
f" {self.out.prefix} = {self.a.name} {self.operator} {self.b.name};\n"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_assign_v_flat(self, prefix_a: str = "a", prefix_b: str = "b", offset: int = 0, array: bool = False):
indexes = self.prefix[self.prefix.rfind("_", 0, self.prefix.rfind("_"))+1:]
offset_a = indexes[:indexes.rfind("_")]
offset_b = indexes[indexes.rfind("_")+1:]
return f" assign {self.a.name} = {self.a.get_wire_value_v(prefix=prefix_a, offset=offset_a, array=array)};\n" + \
f" assign {self.b.name} = {self.b.get_wire_value_v(prefix=prefix_b, offset=offset_b, array=array)};\n" + \
f" assign {self.out.prefix} = {self.a.name} {self.operator} {self.b.name};"
class nand_gate(inverted_logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "nand_gate"
self.cgp_function = 5
self.operator = "&"
self.out = wire(name=prefix+"_y"+str(outid))
""" C CODE GENERATION """
# FLAT C #
def get_assign_c_flat(self, prefix_a: str = "a", prefix_b: str = "b"):
indexes = self.prefix[self.prefix.rfind("_", 0, self.prefix.rfind("_"))+1:]
offset_a = indexes[:indexes.rfind("_")]
offset_b = indexes[indexes.rfind("_")+1:]
return f" {self.a.name} = {self.a.get_wire_value_c(prefix=prefix_a, offset=offset_a)};\n" + \
f" {self.b.name} = {self.b.get_wire_value_c(prefix=prefix_b, offset=offset_b)};\n" + \
f" {self.out.prefix} = ~({self.a.name} {self.operator} {self.b.name});\n"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_assign_v_flat(self, prefix_a: str = "a", prefix_b: str = "b", offset: int = 0, array: bool = False):
indexes = self.prefix[self.prefix.rfind("_", 0, self.prefix.rfind("_"))+1:]
offset_a = indexes[:indexes.rfind("_")]
offset_b = indexes[indexes.rfind("_")+1:]
return f" assign {self.a.name} = {self.a.get_wire_value_v(prefix=prefix_a, offset=offset_a, array=array)};\n" + \
f" assign {self.b.name} = {self.b.get_wire_value_v(prefix=prefix_b, offset=offset_b, array=array)};\n" + \
f" assign {self.out.prefix} = ~({self.a.name} {self.operator} {self.b.name});"
class or_gate(logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "or_gate"
self.cgp_function = 3
self.operator = "|"
self.out = wire(name=prefix+"_y"+str(outid))
class nor_gate(inverted_logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "nor_gate"
self.cgp_function = 6
self.operator = "|"
self.out = wire(name=prefix+"_y"+str(outid))
class xor_gate(logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "xor_gate"
self.cgp_function = 4
self.operator = "^"
self.out = wire(name=prefix+"_y"+str(outid))
class xnor_gate(inverted_logic_gate):
def __init__(self, a: wire, b: wire, prefix: str = "", outid: int = 0):
super().__init__(a, b, prefix)
self.gate_type = "xnor_gate"
self.cgp_function = 7
self.operator = "^"
self.out = wire(name=prefix+"_y"+str(outid))
# Single-input #
class not_gate(inverted_logic_gate):
def __init__(self, a: wire, prefix: str = "", outid: int = 0):
self.gate_type = "not_gate"
self.cgp_function = 1
self.operator = "~"
self.a = wire(name=prefix+"_"+a.name.replace(prefix+"_", ""), value=a.value)
self.prefix = prefix
self.out = wire(name=prefix+"_y"+str(outid))
""" C CODE GENERATION """
# FLAT C #
def get_prototype_c(self):
return f"uint8_t {self.gate_type}(uint8_t {self.a.name})" + "{" + "\n"
def get_function_c(self):
return f"{self.operator}{self.a.get_wire_value_c()} & 0x01 << 0"
def get_declaration_c(self):
return f"{self.a.get_declaration_c()}{self.out.get_declaration_c()}"
def get_init_c_flat(self):
return f"{self.operator}{self.a.name}"
def get_assign_c_flat(self, prefix_a: str = "a", offset: int = 0):
return f" {self.a.name} = {self.a.get_wire_value_c(prefix=prefix_a, offset=offset)};\n" + \
f" {self.out.prefix} = {self.operator}{self.a.name};\n"
# HIERARCHICAL C #
def get_gate_invocation_c(self, a: wire, sign: bool = False, get_index: bool = False):
a_name = a.prefix if sign is False else a.name
a_name = a_name if get_index is False else "a" + a.name[a.name.rfind("_"):]
return f"{self.gate_type}({a_name});"
def get_gate_output_c(self, a: wire, offset: int = 0, sign: bool = False):
a_name = a.prefix if sign is False else a.name
return f"({self.gate_type}({a_name}) & 0x01) << {offset}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.gate_type}(input {self.a.name}, output {self.out.name});\n"
def get_declaration_v_flat(self):
return f"{self.a.get_declaration_v()}{self.out.get_declaration_v()}"
def get_init_v_flat(self):
return f"{self.operator}{self.a.name}"
def get_assign_v_flat(self, prefix_a: str = "a", offset: int = 0, array: bool = False):
return f" assign {self.a.name} = {self.a.get_wire_value_v(prefix=prefix_a, offset=offset, array=array)};\n" + \
f" assign {self.out.prefix} = {self.operator}{self.a.name};"
# HIERARCHICAL VERILOG #
def get_gate_invocation_v(self, a: wire, out: wire, sign: bool = False, get_index: bool = False, out_array: bool = False, offset: int = 0):
a_name = a.prefix if sign is False else a.name
a_name = a_name if get_index is False else "a" + a.name[a.name.rfind("_"):]
return f" {self.gate_type} {self.gate_type}_{out.name}({a_name}, {out.get_wire_value_v(offset=offset, array=out_array)});"
""" CGP CODE GENERATION """
# FLAT CGP #
@staticmethod
def get_parameters_cgp():
return "{1,1,1,1,0}"
def get_triplet_cgp(self, a_index: int = 0):
return f"({a_index},{self.cgp_function})"
@staticmethod
def get_output_cgp(out_index: int = 1):
return f"({out_index})"

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from arithmetic_circuits import arithmetic_circuit, signed_adder_circuit, signed_multiplier_circuit
from one_bit_circuits import half_adder, full_adder
from logic_gates import logic_gate, and_gate, nand_gate, or_gate, nor_gate, xor_gate, xnor_gate, not_gate
from wire_components import wire, bus
""" MULTI BIT CIRCUITS """
# ADDERS
class unsigned_ripple_carry_adder(arithmetic_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "u_rca"):
super().__init__()
self.N = max(a.N, b.N)
# Bus sign extension in case buses have different lengths
a.bus_extend(N=self.N, prefix=a.prefix)
b.bus_extend(N=self.N, prefix=b.prefix)
self.a = a
self.b = b
if prefix == "u_rca" or prefix == "s_rca":
self.prefix = prefix+str(self.N)
else:
self.prefix = prefix
# Output wires for N sum bits and additional cout bit
self.out = bus("out", self.N+1)
# Gradual addition of 1-bit adder components
for input_index in range(self.N):
# First one is a half adder
if input_index == 0:
obj_ha = half_adder(a.get_wire(input_index), b.get_wire(input_index), prefix=self.prefix+"_ha")
self.add_component(obj_ha)
self.out.connect(input_index, obj_ha.get_sum_wire())
# Rest are full adders
else:
obj_fa = full_adder(a.get_wire(input_index), b.get_wire(input_index), self.get_previous_component().get_carry_wire(), prefix=self.prefix+"_fa"+str(input_index))
self.add_component(obj_fa)
self.out.connect(input_index, obj_fa.get_sum_wire())
if input_index == (self.N-1):
self.out.connect(self.N, obj_fa.get_carry_wire())
class signed_ripple_carry_adder(unsigned_ripple_carry_adder, signed_adder_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "s_rca"):
super().__init__(a=a, b=b, prefix=prefix)
self.c_data_type = "int64_t"
# Additional XOR gates to ensure correct sign extension in case of sign addition
sign_xor_1 = xor_gate(self.get_previous_component().a, self.get_previous_component().b, prefix=self.prefix+"_xor_1")
sign_xor_2 = xor_gate(sign_xor_1.out, self.get_previous_component().get_carry_wire(), prefix=self.prefix+"_xor_2")
self.add_component(sign_xor_1)
self.add_component(sign_xor_2)
self.out.connect(self.N, sign_xor_2.out)
# MULTIPLIERS
class unsigned_array_multiplier(arithmetic_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "u_arr_mul"):
super().__init__()
self.N = max(a.N, b.N)
# Bus sign extension in case buses have different lengths
a.bus_extend(N=self.N, prefix=a.prefix)
b.bus_extend(N=self.N, prefix=b.prefix)
self.a = a
self.b = b
if prefix == "u_arr_mul":
self.prefix = prefix+str(self.N)
else:
self.prefix = prefix
# Output wires for multiplication product
self.out = bus("out", self.N*2) if self.N > 1 else bus("out", self.N)
# Gradual generation of partial products
for b_multiplier_index in range(self.N):
for a_multiplicand_index in range(self.N):
# AND gates generation for calculation of partial products
obj_and = and_gate(a.get_wire(a_multiplicand_index), b.get_wire(b_multiplier_index), prefix=self.prefix+"_and_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_and)
if b_multiplier_index != 0:
previous_product = self.components[a_multiplicand_index + b_multiplier_index].out if b_multiplier_index == 1 else self.get_previous_partial_product(a_index=a_multiplicand_index, b_index=b_multiplier_index)
# HA generation for first 1-bit adder in each row starting from the second one
if a_multiplicand_index == 0:
obj_adder = half_adder(self.get_previous_component().out, previous_product, prefix=self.prefix+"_ha_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
# Product generation
self.out.connect(b_multiplier_index, obj_adder.get_sum_wire())
# HA generation, last 1-bit adder in second row
elif a_multiplicand_index == self.N-1 and b_multiplier_index == 1:
obj_adder = half_adder(self.get_previous_component().out, self.get_previous_component(number=2).get_carry_wire(), prefix=self.prefix+"_ha_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
# FA generation
else:
obj_adder = full_adder(self.get_previous_component().out, previous_product, self.get_previous_component(number=2).get_carry_wire(), prefix=self.prefix+"_fa_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
# PRODUCT GENERATION
if a_multiplicand_index == 0 and b_multiplier_index == 0:
self.out.connect(a_multiplicand_index, obj_and.out)
elif b_multiplier_index == self.N-1:
self.out.connect(b_multiplier_index + a_multiplicand_index, obj_adder.get_sum_wire())
if a_multiplicand_index == self.N-1:
self.out.connect(self.out.N-1, obj_adder.get_carry_wire())
class signed_array_multiplier(signed_multiplier_circuit):
def __init__(self, a: bus, b: bus, prefix: str = "s_arr_mul"):
super().__init__()
self.c_data_type = "int64_t"
self.N = max(a.N, b.N)
# Bus sign extension in case buses have different lengths
a.bus_extend(N=self.N, prefix=a.prefix)
b.bus_extend(N=self.N, prefix=b.prefix)
self.a = a
self.b = b
if prefix == "s_arr_mul":
self.prefix = prefix+str(self.N)
else:
self.prefix = prefix
# TODO CHANGE SIGNED MULTIPLIER CIRCUIT (REPLACE CONSTANT WIRE WITH LOGIC GATES)
self.constant_wire = wire(name="constant_wire", value=1)
# Output wires for multiplication product
self.out = bus("out", self.N*2) if self.N > 1 else bus("out", self.N)
# Gradual generation of partial products
for b_multiplier_index in range(self.N):
for a_multiplicand_index in range(self.N):
# AND and NAND gates generation for calculation of partial products and sign extension
if (b_multiplier_index == self.N-1 and a_multiplicand_index != self.N-1) or (b_multiplier_index != self.N-1 and a_multiplicand_index == self.N-1):
obj_nand = nand_gate(a.get_wire(a_multiplicand_index), b.get_wire(b_multiplier_index), prefix=self.prefix+"_nand_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_nand)
else:
obj_and = and_gate(a.get_wire(a_multiplicand_index), b.get_wire(b_multiplier_index), prefix=self.prefix+"_and_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_and)
if b_multiplier_index != 0:
previous_product = self.components[a_multiplicand_index + b_multiplier_index].out if b_multiplier_index == 1 else self.get_previous_partial_product(a_index=a_multiplicand_index, b_index=b_multiplier_index)
# HA generation for first 1-bit adder in each row starting from the second one
if a_multiplicand_index == 0:
obj_adder = half_adder(self.get_previous_component().out, previous_product, prefix=self.prefix+"_ha_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
# Product generation
self.out.connect(b_multiplier_index, obj_adder.get_sum_wire())
# FA generation
else:
if a_multiplicand_index == self.N-1 and b_multiplier_index == 1:
previous_product = self.constant_wire
obj_adder = full_adder(self.get_previous_component().out, previous_product, self.get_previous_component(number=2).get_carry_wire(), prefix=self.prefix+"_fa_"+str(a_multiplicand_index)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
# PRODUCT GENERATION
if a_multiplicand_index == 0 and b_multiplier_index == 0:
self.out.connect(a_multiplicand_index, obj_and.out)
elif b_multiplier_index == self.N-1:
self.out.connect(b_multiplier_index + a_multiplicand_index, obj_adder.get_sum_wire())
if a_multiplicand_index == self.N-1:
obj_adder = half_adder(self.get_previous_component().get_carry_wire(), self.constant_wire, prefix=self.prefix+"_ha_"+str(a_multiplicand_index+1)+"_"+str(b_multiplier_index))
self.add_component(obj_adder)
self.out.connect(self.out.N-1, obj_adder.get_sum_wire())

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from arithmetic_circuits import arithmetic_circuit
from logic_gates import logic_gate, and_gate, nand_gate, or_gate, nor_gate, xor_gate, xnor_gate, not_gate
from wire_components import wire, bus
""" ONE BIT CIRCUITS """
class one_bit_circuit(arithmetic_circuit):
def __init__(self):
super().__init__()
""" C CODE GENERATION """
# FLAT C #
# Obtaining list of all the unique circuit wires from all contained logic gates
# to ensure non-recurring declaration of same wires
def get_declaration_c_flat(self):
self.circuit_wires = []
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_c() for c in self.circuit_wires])
# 2 bit input adder wire values initialization
def get_init_c_flat(self):
return f"{self.components[0].get_assign_c_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix)}" + \
f" {self.components[1].out.name} = {self.components[1].get_init_c_flat()};\n"
# HIERARCHICAL C #
def get_function_block_c(self):
self.component_types = self.get_component_types()
self.prefix = "ha" if isinstance(self, half_adder) else "fa"
return f"{self.get_circuit_c()}\n\n"
def get_declaration_c_hier(self):
return f"{self.component_types[0].a.get_declaration_c()}" + \
f"{self.component_types[2].a.get_declaration_c()}" + \
f"{self.component_types[2].b.get_declaration_c()}"
def get_init_c_hier(self):
return f" {self.component_types[0].a.name} = {self.component_types[0].get_gate_invocation_c(self.a, self.b)}\n" + \
f" {self.component_types[2].a.name} = {self.component_types[1].get_gate_invocation_c(self.a, self.b)}\n" + \
f" {self.component_types[2].b.name} = {self.component_types[1].get_gate_invocation_c(self.component_types[0].a, self.c)}\n"
def get_out_invocation_c(self):
return self.get_sum_invocation_c()+"\n" + \
self.get_cout_invocation_c()
def get_sum_invocation_c(self):
return f" {self.get_sum_wire().name} = ({self.prefix}({self.a.name}, {self.b.name}) >> 0) & 0x01;"
def get_cout_invocation_c(self):
return f" {self.get_carry_wire().name} = ({self.prefix}({self.a.name}, {self.b.name}) >> 1) & 0x01;"
def get_function_sum_c_hier(self, offset: int = 0):
return f" {self.out.prefix} |= {self.component_types[0].get_gate_output_c(a=self.a ,b=self.b, offset=offset)};\n"
def get_function_carry_c_hier(self, offset: int = 1):
return f" {self.out.prefix} |= {self.component_types[1].get_gate_output_c(a=self.a ,b=self.b, offset=offset)};\n"
def get_circuit_c(self):
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}" + \
f"{self.get_function_sum_c_hier()}" + \
f"{self.get_function_carry_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input {self.a.name}, input {self.b.name}, output {self.out.get_wire(0).name}, output {self.out.get_wire(1).name});\n"
def get_declaration_v_flat(self):
self.circuit_wires = []
self.get_circuit_wires()
# Unique declaration of all circuit's interconnections
return "".join([c[0].get_declaration_v() for c in self.circuit_wires])
# Half adder wires values initialization
def get_init_v_flat(self, offset: int = 0, array: bool = False):
return f"{self.components[0].get_assign_v_flat(prefix_a=self.a.prefix, prefix_b=self.b.prefix, offset=offset, array=array)}\n" + \
f" assign {self.components[1].out.name} = {self.components[1].get_init_v_flat()};"
def get_function_out_v_flat(self):
return ""
# HIERARCHICAL VERILOG #
def get_function_block_v(self):
self.component_types = self.get_component_types()
self.prefix = "ha" if isinstance(self, half_adder) else "fa"
return f"{self.get_circuit_v()}\n\n"
def get_declaration_v_hier(self):
return f"{self.component_types[0].a.get_declaration_v()}" + \
f"{self.component_types[2].a.get_declaration_v()}" + \
f"{self.component_types[2].b.get_declaration_v()}"
def get_init_v_hier(self):
return f" {self.component_types[0].gate_type} {self.component_types[0].gate_type}_{self.component_types[0].a.name}({self.a.name}, {self.b.name}, {self.component_types[0].a.name});\n" + \
f" {self.component_types[1].gate_type} {self.component_types[1].gate_type}_{self.component_types[2].a.name}({self.a.name}, {self.b.name}, {self.component_types[2].a.name});\n" + \
f" {self.component_types[1].gate_type} {self.component_types[1].gate_type}_{self.component_types[2].b.name}({self.component_types[0].a.name}, {self.c.name}, {self.component_types[2].b.name});\n"
def get_invocation_v(self):
return f" ha ha_{self.get_carry_wire().name}({self.a.name}, {self.b.name}, {self.get_sum_wire().name}, {self.get_carry_wire().name});"
def get_function_sum_v_hier(self):
return f"{self.components[0].get_gate_invocation_v(a=self.a, b=self.b, out=self.components[0].out, sign=True)}\n"
def get_function_carry_v_hier(self):
return f"{self.components[1].get_gate_invocation_v(a=self.a, b=self.b, out=self.components[1].out, sign=True)}\n"
def get_circuit_v(self):
return f"{self.get_prototype_v()}" + \
f"{self.get_function_sum_v_hier()}" + \
f"{self.get_function_carry_v_hier()}" + \
f"endmodule"
class half_adder(one_bit_circuit):
def __init__(self, a: wire, b: wire, prefix: str = "ha"):
super().__init__()
self.c_data_type = "uint8_t"
self.prefix = prefix
self.a = a
self.b = b
# 2 wires for component's bus output (sum, cout)
self.out = bus("out", self.N+1)
# Sum
# XOR gate for calculation of 1-bit sum
obj_xor_gate = xor_gate(a, b, prefix, outid=0)
self.add_component(obj_xor_gate)
self.out.connect(0, obj_xor_gate.out)
# Cout
# AND gate for calculation of 1-bit cout
obj_and_gate = and_gate(a, b, prefix, outid=1)
self.add_component(obj_and_gate)
self.out.connect(1, obj_and_gate.out)
class full_adder(one_bit_circuit):
def __init__(self, a: wire, b: wire, c: wire, prefix: str = "fa"):
super().__init__()
self.c_data_type = "uint8_t"
self.prefix = prefix
self.a = a
self.b = b
self.c = c
# 2 wires for component's bus output (sum, cout)
self.out = bus("out", self.N+1)
# PG logic
propagate_xor_gate1 = xor_gate(a, b, prefix, outid=0)
self.add_component(propagate_xor_gate1)
generate_and_gate1 = and_gate(a, b, prefix, outid=1)
self.add_component(generate_and_gate1)
# Sum
# XOR gate for calculation of 1-bit sum
obj_xor_gate2 = xor_gate(propagate_xor_gate1.out, c, prefix, outid=2)
self.add_component(obj_xor_gate2)
self.out.connect(0, obj_xor_gate2.out)
# Cout
# AND gate for calculation of 1-bit cout
obj_and_gate2 = and_gate(propagate_xor_gate1.out, c, prefix, outid=3)
self.add_component(obj_and_gate2)
obj_or_gate = or_gate(generate_and_gate1.out, obj_and_gate2.out, prefix, outid=4)
self.add_component(obj_or_gate)
self.out.connect(1, obj_or_gate.out)
# TODO delete or leave?
self.propagate = propagate_xor_gate1.out
self.generate = generate_and_gate1.out
""" C CODE GENERATION """
# FLAT C #
# Full adder function prototype with three inputs
def get_prototype_c(self):
return f"{self.c_data_type} {self.prefix}({self.c_data_type} {self.a.prefix}, {self.c_data_type} {self.b.prefix}, {self.c_data_type} {self.c.prefix})" + "{" + "\n"
# Full adder wires values initialization
def get_init_c_flat(self):
return f" {self.components[0].a.name} = {self.a.get_wire_value_c(offset=self.a.index, prefix=self.a.prefix)};\n" + \
f" {self.components[0].b.name} = {self.b.get_wire_value_c(offset=self.b.index, prefix=self.b.prefix)};\n" + \
f" {self.components[2].b.name} = {self.c.get_wire_value_c()};\n" + \
f" {self.components[0].out.name} = {self.components[0].get_init_c_flat()};\n" + \
f" {self.components[1].out.name} = {self.components[1].get_init_c_flat()};\n" + \
f" {self.components[2].out.name} = {self.components[2].get_init_c_flat()};\n" + \
f" {self.components[3].out.name} = {self.components[3].get_init_c_flat()};\n" + \
f" {self.components[4].out.name} = {self.components[4].get_init_c_flat()};\n"
# HIERARCHICAL C #
def get_sum_invocation_c(self):
return f" {self.get_sum_wire().name} = ({self.prefix}({self.a.name}, {self.b.name}, {self.c.name}) >> 0) & 0x01;"
def get_cout_invocation_c(self):
return f" {self.get_carry_wire().name} = ({self.prefix}({self.a.name}, {self.b.name}, {self.c.name}) >> 1) & 0x01;"
def get_function_sum_c_hier(self, offset: int = 0):
return f" {self.out.prefix} |= {self.component_types[0].get_gate_output_c(a=self.component_types[0].a, b=self.c, offset=offset)};\n"
def get_function_carry_c_hier(self, offset: int = 1):
return f" {self.out.prefix} |= {self.get_previous_component().get_gate_output_c(a=self.component_types[2].a, b=self.component_types[2].b, offset=offset)};\n"
def get_circuit_c(self):
return f"{self.get_prototype_c()}" + \
f"{self.out.get_declaration_c()}" + \
f"{self.get_declaration_c_hier()}\n" + \
f"{self.get_init_c_hier()}\n" + \
f"{self.get_function_sum_c_hier()}" + \
f"{self.get_function_carry_c_hier()}" + \
f" return {self.out.prefix}"+";\n}"
""" VERILOG CODE GENERATION """
# FLAT VERILOG #
def get_prototype_v(self):
return f"module {self.prefix}(input {self.a.name}, input {self.b.name}, input {self.c.name}, output {self.out.get_wire(0).name}, output {self.out.get_wire(1).name});\n"
# Full adder wires values initialization
def get_init_v_flat(self, offset: int = 0, array: bool = False):
return f" assign {self.components[0].a.name} = {self.a.get_wire_value_v(offset=offset, prefix=self.a.prefix, array=array)};\n" + \
f" assign {self.components[0].b.name} = {self.b.get_wire_value_v(offset=offset, prefix=self.b.prefix, array=array)};\n" + \
f" assign {self.components[2].b.name} = {self.c.get_wire_value_v(offset=offset)};\n" + \
f" assign {self.components[0].out.name} = {self.components[0].get_init_v_flat()};\n" + \
f" assign {self.components[1].out.name} = {self.components[1].get_init_v_flat()};\n" + \
f" assign {self.components[2].out.name} = {self.components[2].get_init_v_flat()};\n" + \
f" assign {self.components[3].out.name} = {self.components[3].get_init_v_flat()};\n" + \
f" assign {self.components[4].out.name} = {self.components[4].get_init_v_flat()};\n"
# HIERARCHICAL VERILOG #
def get_invocation_v(self):
return f" fa fa_{self.get_carry_wire().name}({self.a.name}, {self.b.name}, {self.c.name}, {self.get_sum_wire().name}, {self.get_carry_wire().name});"
def get_function_sum_v_hier(self):
return f"{self.components[0].get_gate_invocation_v(a=self.component_types[0].a, b=self.c, out=self.out.get_wire(0))}\n"
def get_function_carry_v_hier(self):
return f"{self.components[-1].get_gate_invocation_v(a=self.component_types[2].a, b=self.component_types[2].b, out=self.out.get_wire(1))}\n"
def get_circuit_v(self):
return f"{self.get_prototype_v()}" + \
f"{self.get_declaration_v_hier()}\n" + \
f"{self.get_init_v_hier()}\n" + \
f"{self.get_function_sum_v_hier()}" + \
f"{self.get_function_carry_v_hier()}" + \
f"endmodule"