yosys/tests/functional/smt_vcd.py

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import sys
import argparse
import os
import smtio
import re
class SExprParserError(Exception):
pass
class SExprParser:
def __init__(self):
self.peekbuf = None
self.stack = [[]]
self.atom_pattern = re.compile(r'[a-zA-Z0-9~!@$%^&*_\-+=<>.?/#]+')
def parse_line(self, line):
ptr = 0
while ptr < len(line):
if line[ptr].isspace():
ptr += 1
elif line[ptr] == ';':
break
elif line[ptr] == '(':
ptr += 1
self.stack.append([])
elif line[ptr] == ')':
ptr += 1
assert len(self.stack) > 1, "too many closed parentheses"
v = self.stack.pop()
self.stack[-1].append(v)
else:
match = self.atom_pattern.match(line, ptr)
if match is None:
raise SExprParserError(f"invalid character '{line[ptr]}' in line '{line}'")
start, ptr = match.span()
self.stack[-1].append(line[start:ptr])
def finish(self):
assert len(self.stack) == 1, "too many open parentheses"
def retrieve(self):
rv, self.stack[0] = self.stack[0], []
return rv
def simulate_smt_with_smtio(smt_file_path, vcd_path, smt_io, num_steps, rnd):
inputs = {}
outputs = {}
states = {}
def handle_datatype(lst):
print(lst)
datatype_name = lst[1]
declarations = lst[2][0][1:] # Skip the first item (e.g., 'mk_inputs')
if datatype_name.endswith("_Inputs"):
for declaration in declarations:
input_name = declaration[0]
bitvec_size = declaration[1][2]
assert input_name.startswith("gold_Inputs_")
inputs[input_name[len("gold_Inputs_"):]] = int(bitvec_size)
elif datatype_name.endswith("_Outputs"):
for declaration in declarations:
output_name = declaration[0]
bitvec_size = declaration[1][2]
assert output_name.startswith("gold_Outputs_")
outputs[output_name[len("gold_Outputs_"):]] = int(bitvec_size)
elif datatype_name.endswith("_State"):
for declaration in declarations:
state_name = declaration[0]
assert state_name.startswith("gold_State_")
if declaration[1][0] == "_":
states[state_name[len("gold_State_"):]] = int(declaration[1][2])
else:
states[state_name[len("gold_State_"):]] = (declaration[1][1][2], declaration[1][2][2])
parser = SExprParser()
with open(smt_file_path, 'r') as smt_file:
for line in smt_file:
parser.parse_line(line)
for expr in parser.retrieve():
smt_io.write(smt_io.unparse(expr))
if expr[0] == "declare-datatype":
handle_datatype(expr)
parser.finish()
assert smt_io.check_sat() == 'sat'
def set_step(inputs, step):
# This function assumes 'inputs' is a dictionary like {"A": 5, "B": 4}
# and 'input_values' is a dictionary like {"A": 5, "B": 13} specifying the concrete values for each input.
mk_inputs_parts = []
for input_name, width in inputs.items():
value = rnd.getrandbits(width) # Generate a random number up to the maximum value for the bit size
binary_string = format(value, '0{}b'.format(width)) # Convert value to binary with leading zeros
mk_inputs_parts.append(f"#b{binary_string}")
mk_inputs_call = "gold_Inputs " + " ".join(mk_inputs_parts)
return [
f"(define-const test_inputs_step_n{step} gold_Inputs ({mk_inputs_call}))\n",
f"(define-const test_results_step_n{step} (Pair gold_Outputs gold_State) (gold test_inputs_step_n{step} test_state_step_n{step}))\n",
f"(define-const test_outputs_step_n{step} gold_Outputs (first test_results_step_n{step}))\n",
f"(define-const test_state_step_n{step+1} gold_State (second test_results_step_n{step}))\n",
]
smt_commands = [f"(define-const test_state_step_n0 gold_State gold-initial)\n"]
for step in range(num_steps):
for step_command in set_step(inputs, step):
smt_commands.append(step_command)
for command in smt_commands:
smt_io.write(command)
assert smt_io.check_sat() == 'sat'
# Store signal values
signals = {name: [] for name in list(inputs.keys()) + list(outputs.keys())}
# Retrieve and print values for each state
def hex_to_bin(value):
if value.startswith('x'):
hex_value = value[1:] # Remove the 'x' prefix
bin_value = bin(int(hex_value, 16))[2:] # Convert to binary and remove the '0b' prefix
return f'b{bin_value.zfill(len(hex_value) * 4)}' # Add 'b' prefix and pad with zeros
return value
combined_assertions = []
for step in range(num_steps):
print(f"Values for step {step + 1}:")
for input_name, width in inputs.items():
value = smt_io.get(f'(gold_Inputs_{input_name} test_inputs_step_n{step})')
value = hex_to_bin(value[1:])
print(f" {input_name}: {value}")
signals[input_name].append((step, value))
for output_name, width in outputs.items():
value = smt_io.get(f'(gold_Outputs_{output_name} test_outputs_step_n{step})')
value = hex_to_bin(value[1:])
print(f" {output_name}: {value}")
signals[output_name].append((step, value))
combined_assertions.append(f'(= (gold_Outputs_{output_name} test_outputs_step_n{step}) #{value})')
# Create a single assertion covering all timesteps
combined_condition = " ".join(combined_assertions)
smt_io.write(f'(assert (not (and {combined_condition})))')
# Check the combined assertion
assert smt_io.check_sat(["unsat"]) == "unsat"
def write_vcd(filename, signals, timescale='1 ns', date='today'):
with open(filename, 'w') as f:
# Write the header
f.write(f"$date\n {date}\n$end\n")
f.write(f"$timescale {timescale} $end\n")
# Declare signals
f.write("$scope module gold $end\n")
for signal_name, changes in signals.items():
signal_size = len(changes[0][1])
f.write(f"$var wire {signal_size - 1} {signal_name} {signal_name} $end\n")
f.write("$upscope $end\n")
f.write("$enddefinitions $end\n")
# Collect all unique timestamps
timestamps = sorted(set(time for changes in signals.values() for time, _ in changes))
# Write initial values
f.write("#0\n")
for signal_name, changes in signals.items():
for time, value in changes:
if time == 0:
f.write(f"{value} {signal_name}\n")
# Write value changes
for time in timestamps:
if time != 0:
f.write(f"#{time}\n")
for signal_name, changes in signals.items():
for change_time, value in changes:
if change_time == time:
f.write(f"{value} {signal_name}\n")
write_vcd(vcd_path, signals)
def simulate_smt(smt_file_path, vcd_path, num_steps, rnd):
so = smtio.SmtOpts()
so.solver = "z3"
so.logic = "ABV"
so.debug_print = True
smt_io = smtio.SmtIo(opts=so)
try:
simulate_smt_with_smtio(smt_file_path, vcd_path, smt_io, num_steps, rnd)
finally:
smt_io.p_close()