Ejemplo n.º 1
0
def createmodel():
    m = ila.Abstraction('alu')
    m.enable_parameterized_synthesis = 1

    regs = [m.reg('r%d' % i, 8) for i in xrange(4)]
    opcode = m.inp('opcode', 7)

    rs_index = opcode[1:0]
    rt_index = opcode[3:2]
    rd_index = opcode[5:4]
    op = opcode[6:6]

    def sel(regs, idx):
        return ila.ite(
            idx == 0, regs[0],
            ila.ite(idx == 1, regs[1], ila.ite(idx == 2, regs[2], regs[3])))

    rs = sel(regs, rs_index)
    rt = sel(regs, rt_index)
    res = ila.choice('op', rs + rt, rs - rt)
    for i in xrange(4):
        ri_next = ila.ite(rd_index == i, res, regs[i])
        m.set_next('r%d' % i, ri_next)

    m.fetch_expr = opcode
    m.decode_exprs = [opcode == i for i in xrange(0, 128)]
    m.synthesize(alusim)
    for i, di in enumerate(m.decode_exprs):
        for reg in xrange(4):
            exp_i = m.get_next('r%d' % reg, i)
            si = ila.simplify(di, exp_i)
            if not m.areEqual(di, exp_i, si):
                print 'decode:', di
                print 'exp:', exp_i
Ejemplo n.º 2
0
Archivo: syn.py Proyecto: emzha/IMDb
    def synToFile(m, filePath):
        if not os.path.exists(filePath):
            os.makedirs(filePath)

        sim = lambda s: RSA().simulate(s)
        for s in all_states:
            st = time.clock()
            m.synthesize(s, sim)
            dt = time.clock() - st
            print s + ' synthesized: %.2f' % dt
            fileName = filePath + '/' + s
            nxt = m.get_next(s)
            si = ila.simplify(m.bool(True), nxt)
            m.exportOne(si, fileName)
Ejemplo n.º 3
0
def get_cfg(uclid5, rom, pc, pc_next, inst_next, init_states, romconst,
            next_exprs):
    stack = init_states
    visited = set()
    state_map = {}
    state_edges = {}
    ret_set = set()
    state_to_nexts = {}

    while len(stack):
        top_pc, call_stack = stack.pop()
        # keep track of visited states.
        state = (top_pc, call_stack)
        if state in visited: continue
        else: visited.add(state)

        state_name = state_to_name(top_pc, call_stack)
        assert state_name not in state_map
        state_map[state_name] = (top_pc, call_stack)

        # set the current PC value.
        uclid5.setVar('PC', top_pc)
        # get current opcode.
        thisInst = uclid5.getExprValues(rom[pc])
        thisInst1 = uclid5.getExprValues(rom[pc + 1])
        thisInst2 = uclid5.getExprValues(rom[pc + 2])
        assert len(thisInst) == 1
        assert len(thisInst1) == 1
        assert len(thisInst2) == 1
        opcode = thisInst[0]
        opcode1, opcode2 = thisInst1[0], thisInst2[0]
        # if it is a call, we have to add it to the stack.
        if iscall(opcode):
            call_stack_new = tuple(list(call_stack) + [nextpc(top_pc, opcode)])
            nextPCs = uclid5.getExprValues(pc_next)
        # if it is a return, don't symbolically execute, instead pop off the stack.
        elif isret(opcode):
            call_stack_new_list = list(call_stack)
            ret_pc = call_stack_new_list.pop()
            call_stack_new = tuple(call_stack_new_list)
            nextPCs = [ret_pc]
            ret_set.add(state_name)
        # else symbolic execution rules.
        else:
            call_stack_new = call_stack
            nextPCs = uclid5.getExprValues(pc_next)

        # add new states to be visited to the stack.
        next_states = [(n, call_stack_new) for n in nextPCs]
        stack += next_states

        # add edges to state graph.
        next_state_names = [
            state_to_name(next_pc, call_stack_new)
            for (next_pc, call_stack_new) in next_states
        ]
        assert state_name not in state_edges
        state_edges[state_name] = next_state_names

        # now print out where we are.
        assert len(nextPCs) <= 16
        next_string = ' '.join('%04X' % nextPC_i for nextPC_i in nextPCs)
        call_stack_string = ' '.join('%04X' % pc for pc in call_stack)

        simp_nexts = {}
        # TODO: Parallelize this loop, too slow on one core
        for s in next_exprs.keys():
            simp_nexts[s] = ila.simplify(
                (rom[pc] == opcode) & (rom[pc + 1] == opcode1) &
                (rom[pc + 2] == opcode2) & (pc == top_pc), next_exprs[s])
        state_to_nexts[state_name] = simp_nexts
        pc_next_simplified = ila.simplify(
            (rom[pc] == opcode) & (rom[pc + 1] == opcode1) &
            (rom[pc + 2] == opcode2) & (pc == top_pc), pc_next)
        print 'PC: %04X [%20s]; OP: %02X -> NEXT: %s; PC_NEXT_EXPR: %s' % (
            top_pc, call_stack_string, opcode, next_string,
            str(pc_next_simplified))

    return state_map, state_edges, ret_set, state_to_nexts
Ejemplo n.º 4
0
def model(num_regs, reg_size, paramsyn):
    reg_field_width = int(math.log(num_regs, 2))
    assert (1 << reg_field_width) == num_regs

    # create the alu.
    alu = alu_sim(reg_field_width, reg_size)

    sys = ila.Abstraction("alu")
    sys.enable_parameterized_synthesis = paramsyn

    # state elements.
    rom = sys.mem('rom', alu.ROM_ADDR_WIDTH, alu.OPCODE_WIDTH)
    pc = sys.reg('pc', alu.ROM_ADDR_WIDTH)
    opcode = rom[pc]
    regs = [sys.reg('r%d' % i, alu.REG_SIZE) for i in xrange(alu.NUM_REGS)]
    # get the two sources.
    rs = ila.choice('rs', regs)
    rt = ila.choice('rt', regs)
    rs = [rs+rt, rs-rt, rs&rt, rs|rt, ~rs, -rs, ~rt, -rt]
    # set next.
    sys.set_next('pc', ila.choice('pc', pc+1, pc+2))

    # set rom next.
    sys.set_next('rom', rom)

    regs_next = []
    for i in xrange(alu.NUM_REGS):
        ri_next = ila.choice('result%d' % i, rs+[regs[i]])
        sys.set_next('r%d' % i, ri_next)
    # set the fetch expressions.
    sys.fetch_expr = opcode
    # now set the decode expressions.
    sys.decode_exprs = [opcode == i for i in xrange(alu.NUM_OPCODES)]

    # synthesize pc first.
    sys.synthesize('pc', lambda s: alu.alusim(s))
    pc_next = sys.get_next('pc')
    assert sys.areEqual(pc_next, pc+1)

    # now synthesize.
    st = time.clock()
    sys.synthesize(lambda s: alu.alusim(s))
    et = time.clock()
    print 'time for synthesis: %.3f' % (et-st)

    regs_next = aluexpr(rom, pc, regs)
    for i in xrange(alu.NUM_REGS):
        rn1 = sys.get_next('r%d' % i)
        rn2 = regs_next[i]
        print '(a) r%d: %s' % (i, str(rn1))
        print '(b) r%d: %s' % (i, str(rn2))
        assert sys.areEqual(rn1, rn2)

    print '--> PC_NEXT:', sys.get_next('pc')
    #sys.add_assumption(opcode == 0x80)
    #print sys.syn_elem("r0", sys.get_next('r0'), alusim)

    # simplify PC.
    pc_next_p = ila.simplify(sys.bool(True), sys.get_next('pc'))
    sys.set_next('pc', pc_next_p)
    print '--> PC_NEXT:', sys.get_next('pc')

    expFile  = "tmp/alu.txt"
    sys.exportAll(expFile);
    verilogFile = "tmp/alu.v"
    ila.setloglevel(3, "")
    ila.enablelog("VerilogExport")
    sys.generateVerilog(verilogFile)

    # now import into a new abstraction and check.
    sysp = ila.Abstraction("alu")
    sysp.importAll(expFile);
    romp = sysp.getmem('rom')
    pcp = sysp.getreg('pc')
    regsp = [sysp.getreg('r%d' % i) for i in xrange(alu.NUM_REGS)]
    regs_next = aluexpr(romp, pcp, regsp)
    for i in xrange(alu.NUM_REGS):
        rn1 = sysp.get_next('r%d' % i)
        rn2 = regs_next[i]
        assert sysp.areEqual(rn1, rn2)