Esempio n. 1
0
def generate_test(Circuit, func):
    #nfuncargs = check(circuit, func)
    sig = signature(func)
    nfuncargs = len(sig.parameters)
    assert nfuncargs + 1 < 8

    rom = testvectors(func)

    romb = ROMB(rom)
    counter = Counter(9)
    wire(1, romb.RE)
    wire(1, romb.RCLKE)
    wire(counter.O, romb.RADDR)

    circuit = Circuit(nfuncargs)

    circuit(*[romb.RDATA[i] for i in range(nfuncargs)])

    orr = Or(2)
    finished = DFF()
    f = finished(orr(counter.COUT, finished.O))

    xor = XOr(2)
    xor(circuit.O, romb.RDATA[nfuncargs])
    orr = Or(2)
    error = DFF()
    e = error(orr(xor.O, error.O))

    return f, e
Esempio n. 2
0
 def f(y):
     or_ = uncurry(Or(n // 2))
     os = []
     for i in range(n):
         if i & (1 << y): os.append(Enc.I[i])
     wire(array(os), or_)
     return AnonymousCircuit("O", or_.O)
Esempio n. 3
0
    class CounterModM(Circuit):
        name = name_
        io = IO(**dict(zip(args[::2], args[1::2])))

        counter = Counter(n,
                          cin=cin,
                          cout=False,
                          incr=incr,
                          has_ce=has_ce,
                          has_reset=True)
        reset = Decode(m - 1, n)(counter.O)

        if has_reset:
            reset = Or(2)(reset, io.RESET)

        if has_ce:
            CE = io.CE
            reset = And(2)(reset, CE)
            # reset is sometimes called rollover or RO
            # note that we don't return RO in Counter

            # should also handle r in the definition

        wire(magma.reset(reset), counter.RESET)  # synchronous reset

        if has_ce:
            wire(CE, counter.CE)

        if cin:
            wire(io.CIN, counter.CIN)

        wire(counter.O, io.O)

        if cout:
            wire(reset, io.COUT)
Esempio n. 4
0
 def definition(io):
     # Generate the sum
     m.wire(XOr(3)(io.I0, io.I1, io.CIN), io.O)
     # Generate the carry
     m.wire(
         Or(3)(And(2)(io.I0, io.I1), And(2)(io.I1, io.CIN),
               And(2)(io.I0, io.CIN)), io.COUT)
Esempio n. 5
0
def DefineCounterModM(m,
                      n,
                      cin=False,
                      cout=True,
                      incr=1,
                      has_ce=False,
                      has_reset=False):

    name = _CounterName(f'Counter{n}_Mod{m}', incr, has_ce, has_reset, cin,
                        cout)
    args = []
    if cin:
        args += ['CIN', In(Bit)]

    args += ["O", Out(UInt(n))]
    if cout:
        args += ["COUT", Out(Bit)]

    args += ClockInterface(has_ce, has_reset)

    CounterModM = DefineCircuit(name, *args)

    counter = Counter(n,
                      cin=cin,
                      cout=False,
                      incr=incr,
                      has_ce=has_ce,
                      has_reset=True)
    reset = Decode(m - 1, n)(counter.O)

    if has_reset:
        reset = Or(2)(reset, CounterModM.RESET)

    if has_ce:
        CE = CounterModM.CE
        reset = And(2)(reset, CE)
        # reset is sometimes called rollover or RO
        # note that we don't return RO in Counter

        # should also handle r in the definition

    wire(reset, counter.RESET)  # synchronous reset

    if has_ce:
        wire(CE, counter.CE)

    if cin:
        wire(CounterModM.CIN, counter.CIN)

    wire(counter.O, CounterModM.O)

    if cout:
        wire(reset, CounterModM.COUT)

    EndCircuit()

    return CounterModM
Esempio n. 6
0
 def Define3to2Op():
     Op = DefineCircuit("Op", "I0", In(Bit), "I1", In(Bit), "I2", In(Bit), "O", Out(Bit))
     a = And(2)(Op.I0, Op.I1)
     b = And(2)(Op.I1, Op.I2)
     c = And(2)(Op.I2, Op.I0)
     d = Or(3)(a, b, c)
     wire(d, Op.O)
     EndDefine()
     return Op
Esempio n. 7
0
class FullAdder(m.Circuit):
    io = m.IO(I0=m.In(m.Bit),
              I1=m.In(m.Bit),
              CIN=m.In(m.Bit),
              O=m.Out(m.Bit),
              COUT=m.Out(m.Bit))

    # Generate the sum
    m.wire(XOr(3)(io.I0, io.I1, io.CIN), io.O)
    # Generate the carry
    m.wire(
        Or(3)(And(2)(io.I0, io.I1), And(2)(io.I1, io.CIN),
              And(2)(io.I0, io.CIN)), io.COUT)
Esempio n. 8
0
def test_bitwise():
    check_unary_operator(invert, "Invert", wrapped=False)
    check_unary_overloaded_operator(operator.invert, Invert(4))
    binary_bits_ops = [
        (and_, operator.and_, And(2, 4)),
        (or_, operator.or_, Or(2, 4)),
        (xor, operator.xor, XOr(2, 4)),
    ]
    for args in binary_bits_ops:
        print("Testing {}".format(args))
        check_binary_operator(args[0], args[2])
        check_binary_overloaded_operator(args[1], args[2])

    check_unary_operator(neg, "Negate", wrapped=False)
    check_unary_overloaded_operator(operator.neg, Negate(4), T=SInt)

    binary_arith_ops = [
        (add, operator.add, Add(4, cin=False)),
        (sub, operator.sub, Sub(4)),
    ]
    for args in binary_arith_ops:
        print("Testing {}".format(args))
        check_binary_operator(args[0], args[2], T=Bits)
        check_binary_overloaded_operator(args[1], args[2], T=UInt)
        check_binary_overloaded_operator(args[1], args[2], T=SInt)

    compare_ops = [
        # (eq, operator.eq, EQ(4) ),
        (lt, operator.lt, ULT(4), SLT(4)),
        (le, operator.le, ULE(4), SLE(4)),
        (gt, operator.gt, UGT(4), SGT(4)),
        (ge, operator.ge, UGE(4), SGE(4))
    ]
    for args in compare_ops:
        print("Testing {}".format(args))
        check_binary_operator(args[0], args[2], out_type=Bit)
        if args[0] == eq:
            check_binary_overloaded_operator(args[1], args[2], out_type=Bit)
        else:
            check_binary_overloaded_operator(args[1],
                                             args[2],
                                             T=UInt,
                                             out_type=Bit)
            check_binary_overloaded_operator(args[1],
                                             args[3],
                                             T=SInt,
                                             out_type=Bit)
Esempio n. 9
0
 def definition(io):
     swap = uncurry(fork(And(2), Or(2)), prefix="I")
     #swap = uncurry( fork( And(2), Or(2) ) , prefix="in")
     wire(swap(io.I), io.O)
Esempio n. 10
0
def or_(*args, **kwargs):
    width = get_length(args[0])
    return Or(len(args), width, **kwargs)(*args)
Esempio n. 11
0
from magma import wire, compile, EndCircuit
from mantle import Or
from loam.boards.icestick import IceStick

N = 2
icestick = IceStick()
for i in range(2 * N):
    icestick.J1[i].input().on()
for i in range(N):
    icestick.J3[i].output().on()

main = icestick.main()

or2 = Or(2, N)
wire(or2(main.J1[0:N], main.J1[N:2 * N]), main.J3)

EndCircuit()
Esempio n. 12
0
from magma import wire, compile, EndCircuit
from mantle import Or
from loam.boards.icestick import IceStick

icestick = IceStick()
for i in range(2):
    icestick.J1[i].input().on()
icestick.D5.on()

main = icestick.main()

or2 = Or(2)
or2(main.J1[0], main.J1[1])
wire(or2.O, main.D5)

EndCircuit()