# array of address-latches
m.submodules.l = self.l = l = SRLatch(llen=self.n_adr, sync=False)
- self.addrs_r = addrs_r = Array(Signal(self.bitwid, reset_less=True,
+ self.adrs_r = adrs_r = Array(Signal(self.bitwid, reset_less=True,
name="a_r") \
for i in range(self.n_adr))
# copy in addresses (and "enable" signals)
for i in range(self.n_adr):
- latchregister(m, self.addrs_i[i], addrs_r[i], l.q[i])
+ latchregister(m, self.addrs_i[i], adrs_r[i], l.q[i])
# is there a clash, yes/no
matchgrp = []
def is_match(self, i, j):
if i == j:
return Const(0) # don't match against self!
- return self.addrs_r[i] == self.addrs_r[j]
+ return self.adrs_r[i] == self.adrs_r[j]
def __iter__(self):
yield from self.addrs_i
self.bit_len = bit_len
self.len_i = Signal(bit_len, reset_less=True)
self.addr_i = Signal(bit_len, reset_less=True)
- self.explen_o = Signal(1<<(bit_len+1), reset_less=True)
+ self.lexp_o = Signal(1<<(bit_len+1), reset_less=True)
def elaborate(self, platform):
m = Module()
# temp
binlen = Signal((1<<self.bit_len)+1, reset_less=True)
- comb += binlen.eq((Const(1, self.bit_len+1) << (1+self.len_i)) - 1)
- comb += self.explen_o.eq(binlen << self.addr_i)
+ comb += binlen.eq((Const(1, self.bit_len+1) << (self.len_i)) - 1)
+ comb += self.lexp_o.eq(binlen << self.addr_i)
return m
def ports(self):
- return [self.len_i, self.addr_i, self.explen_o,]
+ return [self.len_i, self.addr_i, self.lexp_o,]
class PartialAddrBitmap(PartialAddrMatch):
# expanded lengths, needed in match
expwid = 1+self.lsbwid # XXX assume LD/ST no greater than 8
- self.explen = Array(Signal(1<<expwid, reset_less=True,
+ self.lexp = Array(Signal(1<<expwid, reset_less=True,
name="a_l") \
for i in range(self.n_adr))
comb = m.d.comb
# intermediaries
- addrs_r, l = self.addrs_r, self.l
+ adrs_r, l = self.adrs_r, self.l
len_r = Array(Signal(self.lsbwid, reset_less=True,
name="l_r") \
for i in range(self.n_adr))
latchregister(m, self.len_i[i], len_r[i], l.q[i])
# add one to intermediate addresses
- comb += self.addr1s[i].eq(self.addrs_r[i]+1)
+ comb += self.addr1s[i].eq(self.adrs_r[i]+1)
# put the bottom bits of each address into each LenExpander.
comb += be.len_i.eq(len_r[i])
comb += be.addr_i.eq(self.faddrs_i[i][:self.lsbwid])
# connect expander output
- comb += self.explen[i].eq(be.explen_o)
+ comb += self.lexp[i].eq(be.lexp_o)
return m
hexp = expwid >> 1
expwid2 = expwid + hexp
print (self.lsbwid, expwid)
- return ((self.addrs_r[i] == self.addrs_r[j]) & \
- (self.explen[i][:expwid] & self.explen[j][:expwid]).bool() |
- (self.addr1s[i] == self.addrs_r[j]) & \
- (self.explen[i][expwid:expwid2] & self.explen[j][:hexp]).bool())
+ return (((self.adrs_r[i] == self.adrs_r[j]) &
+ (self.lexp[i][:expwid] & self.lexp[j][:expwid]).bool()) |
+ ((self.addr1s[i] == self.adrs_r[j]) &
+ (self.lexp[i][expwid:expwid2] & self.lexp[j][:hexp]).bool())
+ )
+ # ((self.addr1s[j] == self.adrs_r[i]) &
+ # (self.lexp[j][expwid:expwid2] & self.lexp[i][:hexp]).bool()))
def __iter__(self):
yield from self.faddrs_i
yield dut.go_wr_i.eq(0)
yield
+def part_addr_bit(dut):
+ yield dut.len_i[0].eq(8)
+ yield dut.faddrs_i[0].eq(0b1011011)
+ yield dut.addr_en_i[0].eq(1)
+ yield
+ yield dut.addr_en_i[0].eq(0)
+ yield
+ yield dut.len_i[1].eq(2)
+ yield dut.faddrs_i[1].eq(0b1100010)
+ yield dut.addr_en_i[1].eq(1)
+ yield
+ yield dut.addr_en_i[1].eq(0)
+ yield
+ yield dut.len_i[2].eq(2)
+ yield dut.faddrs_i[2].eq(0b1011010)
+ yield dut.addr_en_i[2].eq(1)
+ yield
+ yield dut.addr_en_i[2].eq(0)
+ yield
+ yield dut.addr_rs_i[1].eq(1)
+ yield
+ yield dut.addr_rs_i[1].eq(0)
+ yield
+
def test_part_addr():
dut = LenExpand(4)
vl = rtlil.convert(dut, ports=dut.ports())
with open("test_part_bit.il", "w") as f:
f.write(vl)
+ run_simulation(dut, part_addr_bit(dut), vcd_name='test_part_bit.vcd')
+
dut = PartialAddrMatch(3, 10)
vl = rtlil.convert(dut, ports=dut.ports())
with open("test_part_addr.il", "w") as f:
projects / soc.git / commitdiff