from nmigen.cli import verilog, rtlil
-class InputTest:
- def __init__(self, dut, width, fpkls, fpop, vals, single_op):
+class MuxInOut:
+ def __init__(self, dut, width, fpkls, fpop, vals, single_op, opcode):
self.dut = dut
self.fpkls = fpkls
self.fpop = fpop
self.single_op = single_op
+ self.opcode = opcode
self.di = {}
self.do = {}
self.tlen = len(vals) // dut.num_rows
self.do[muxid] = []
for i in range(self.tlen):
if self.single_op:
- (op1, ) = vals.pop(0)
+ #print ("vals", vals)
+ op1 = vals.pop(0)
+ if isinstance(op1, tuple):
+ assert len(op1) == 1
+ op1 = op1[0]
res = self.fpop(self.fpkls(op1))
self.di[muxid][i] = (op1, )
else:
(op1, op2, ) = vals.pop(0)
+ #print ("test", hex(op1), hex(op2))
res = self.fpop(self.fpkls(op1), self.fpkls(op2))
self.di[muxid][i] = (op1, op2)
self.do[muxid].append(res.bits)
rs = self.dut.p[muxid]
yield rs.valid_i.eq(1)
yield rs.data_i.a.eq(op1)
+ if self.opcode is not None:
+ yield rs.data_i.ctx.op.eq(self.opcode)
if not self.single_op:
yield rs.data_i.b.eq(op2)
yield rs.data_i.muxid.eq(muxid)
print ("recv ended", muxid)
-class InputTestRandom(InputTest):
- def __init__(self, dut, width, fpkls, fpop, single_op=False, n_vals=10):
- vals = []
- for muxid in range(dut.num_rows):
- for i in range(n_vals):
- if single_op:
- op1 = randint(0, (1<<width)-1)
- #op1 = 0x40900000
- #op1 = 0x94607b66
- #op1 = 0x889cd8c
- #op1 = 0xe98646d7
- #op1 = 0x3340f2a7
- #op1 = 0x3a05de50
- #op1 = 0xfff13f05
- vals.append((op1,))
- else:
- op1 = randint(0, (1<<width)-1)
- op2 = randint(0, (1<<width)-1)
- vals.append((op1, op2,))
-
- InputTest.__init__(self, dut, width, fpkls, fpop, vals, single_op)
-
-
-def runfp(dut, width, name, fpkls, fpop, single_op=False, n_vals=10):
+def create_random(num_rows, width, single_op=False, n_vals=10):
+ vals = []
+ for muxid in range(num_rows):
+ for i in range(n_vals):
+ if single_op:
+ op1 = randint(0, (1<<width)-1)
+ #op1 = 0x40900000
+ #op1 = 0x94607b66
+ #op1 = 0x889cd8c
+ #op1 = 0xe98646d7
+ #op1 = 0x3340f2a7
+ #op1 = 0xfff13f05
+ #op1 = 0x453eb000
+ #op1 = 0x3a05de50
+ #op1 = 0xc27ff989
+ #op1 = 0x41689000
+ #op1 = 0xbbc0edec
+ #op1 = 0x2EDBE6FF
+ #op1 = 0x358637BD
+ #op1 = 0x3340f2a7
+ #op1 = 0x33D6BF95
+ #op1 = 0x9885020648d8c0e8
+ #op1 = 0xc26b
+ #op1 = 3
+
+ #op1 = 0x3a66
+ #op1 = 0x5299
+ #op1 = 0xe0eb
+ #op1 = 0x3954
+ #op1 = 0x4dea
+ #op1 = 0x65eb
+
+ #op1 = 0x1841
+
+ # FSQRT
+ #op1 = 0x3449f9a9
+ #op1 = 0x1ba94baa
+
+ # FRSQRT
+ #op1 = 0x3686
+ #op1 = 0x4400
+ #op1 = 0x4800
+ #op1 = 0x48f0
+
+ vals.append((op1,))
+ else:
+ op1 = randint(0, (1<<width)-1)
+ op2 = randint(0, (1<<width)-1)
+
+ #op2 = 0x4000
+ #op1 = 0x3c50
+ #op2 = 0x3e00
+ #op2 = 0xb371
+ #op1 = 0x4400
+ #op1 = 0x656c
+ op1 = 0x738c
+
+ vals.append((op1, op2,))
+ return vals
+
+
+def repeat(num_rows, vals):
+ """ bit of a hack: repeats the last value to create a list
+ that will be accepted by the muxer, all mux lists to be
+ of equal length
+ """
+ vals = list(vals)
+ n_to_repeat = len(vals) % num_rows
+ #print ("repeat", vals)
+ return vals + [vals[-1]] * n_to_repeat
+
+
+def pipe_cornercases_repeat(dut, name, mod, fmod, width, fn, cc, fpfn, count,
+ single_op=False, opcode=None):
+ for i, fixed_num in enumerate(cc(mod)):
+ vals = fn(mod, fixed_num, count, width, single_op)
+ vals = repeat(dut.num_rows, vals)
+ #print ("repeat", i, fn, single_op, list(vals))
+ fmt = "test_pipe_fp%d_%s_cornercases_%d"
+ runfp(dut, width, fmt % (width, name, i),
+ fmod, fpfn, vals=vals, single_op=single_op, opcode=opcode)
+
+
+def runfp(dut, width, name, fpkls, fpop, single_op=False, n_vals=10,
+ vals=None, opcode=None):
vl = rtlil.convert(dut, ports=dut.ports())
with open("%s.il" % name, "w") as f:
f.write(vl)
- test = InputTestRandom(dut, width, fpkls, fpop, single_op, n_vals)
- run_simulation(dut, [test.rcv(1), test.rcv(0),
- test.rcv(3), test.rcv(2),
- test.send(0), test.send(1),
- test.send(3), test.send(2),
- ],
- vcd_name="%s.vcd" % name)
+ if vals is None:
+ vals = create_random(dut.num_rows, width, single_op, n_vals)
+ test = MuxInOut(dut, width, fpkls, fpop, vals, single_op, opcode=opcode)
+ fns = []
+ for i in range(dut.num_rows):
+ fns.append(test.rcv(i))
+ fns.append(test.send(i))
+ run_simulation(dut, fns, vcd_name="%s.vcd" % name)