from nmigen.compat.sim import run_simulation
from nmigen.cli import verilog, rtlil
-from nmigen import Module, Signal, Elaboratable
+from nmigen import Module, Signal, Const, Elaboratable
from nmutil.latch import SRLatch
class FUDependenceCell(Elaboratable):
""" implements 11.4.7 mitch alsup dependence cell, p27
"""
- def __init__(self, n_fu=1):
+ def __init__(self, dummy, n_fu=1):
self.n_fu = n_fu
+ self.dummy = Const(~(1<<dummy), n_fu)
# inputs
self.rd_pend_i = Signal(n_fu, reset_less=True) # read pend in (left)
self.wr_pend_i = Signal(n_fu, reset_less=True) # write pend in (left)
m.d.comb += rd_c.go_i.eq(self.go_rd_i)
# connect pend_i
- m.d.comb += wr_c.pend_i.eq(self.wr_pend_i)
- m.d.comb += rd_c.pend_i.eq(self.rd_pend_i)
+ m.d.comb += wr_c.pend_i.eq(self.wr_pend_i & self.dummy)
+ m.d.comb += rd_c.pend_i.eq(self.rd_pend_i & self.dummy)
# connect output
m.d.comb += self.wr_wait_o.eq(wr_c.wait_o)
# ---
# matrix of dependency cells
# ---
- dm = Array(FUDependenceCell(self.n_fu_row) \
- for f in range(self.n_fu_col))
- for x in range(self.n_fu_col):
- setattr(m.submodules, "dm%d" % x, dm[x])
+ dm = Array(FUDependenceCell(f, self.n_fu_col) \
+ for f in range(self.n_fu_row))
+ for y in range(self.n_fu_row):
+ setattr(m.submodules, "dm%d" % y, dm[y])
# ---
# array of Function Unit Readable/Writable: row-length, horizontal
# connect FU Pending
# ---
for y in range(self.n_fu_row):
+ dc = dm[y]
fu = fur[y]
- rd_wait_o = []
- wr_wait_o = []
- for x in range(self.n_fu_col):
- dc = dm[x]
- # accumulate cell outputs rd/wr-pending
- rd_wait_o.append(dc.rd_wait_o[y])
- wr_wait_o.append(dc.wr_wait_o[y])
# connect cell reg-select outputs to Reg Vector In
- m.d.comb += [fu.rd_pend_i.eq(Cat(*rd_wait_o)),
- fu.wr_pend_i.eq(Cat(*wr_wait_o)),
+ m.d.comb += [fu.rd_pend_i.eq(dc.rd_wait_o),
+ fu.wr_pend_i.eq(dc.wr_wait_o),
]
# ---
# connect Dependency Matrix dest/src1/src2/issue to module d/s/s/i
# ---
for x in range(self.n_fu_col):
- dc = dm[x]
issue_i = []
for y in range(self.n_fu_row):
+ dc = dm[y]
# accumulate cell inputs issue
- issue_i.append(dc.issue_i[y])
- # wire up inputs from module to row cell inputs (Cat is gooood)
+ issue_i.append(dc.issue_i[x])
+ # wire up inputs from module to row cell inputs
m.d.comb += Cat(*issue_i).eq(self.issue_i)
# ---
# connect Matrix go_rd_i/go_wr_i to module readable/writable
# ---
for y in range(self.n_fu_row):
- go_rd_i = []
- go_wr_i = []
- go_die_i = []
- for x in range(self.n_fu_col):
- dc = dm[x]
- # accumulate cell go_rd/go_wr
- go_rd_i.append(dc.go_rd_i[y])
- go_wr_i.append(dc.go_wr_i[y])
- go_die_i.append(dc.go_die_i[y])
- # wire up inputs from module to row cell inputs (Cat is gooood)
- m.d.comb += [Cat(*go_rd_i).eq(self.go_rd_i),
- Cat(*go_wr_i).eq(self.go_wr_i),
- Cat(*go_die_i).eq(self.go_die_i),
+ dc = dm[y]
+ # wire up inputs from module to row cell inputs
+ m.d.comb += [dc.go_rd_i.eq(self.go_rd_i),
+ dc.go_wr_i.eq(self.go_wr_i),
+ dc.go_die_i.eq(self.go_die_i),
]
-
# ---
# connect Matrix pending
# ---
for y in range(self.n_fu_row):
- rd_pend_i = []
- wr_pend_i = []
- for x in range(self.n_fu_col):
- dc = dm[x]
- if x == y: # ignore hazards on the diagonal: self-against-self
- dummyrd = Signal(reset_less=True)
- dummywr = Signal(reset_less=True)
- rd_pend_i.append(dummyrd)
- wr_pend_i.append(dummywr)
- continue
- # accumulate cell rd_pend/wr_pend/go_rd/go_wr
- rd_pend_i.append(dc.rd_pend_i[y])
- wr_pend_i.append(dc.wr_pend_i[y])
- # wire up inputs from module to row cell inputs (Cat is gooood)
- m.d.comb += [Cat(*rd_pend_i).eq(self.rd_pend_i),
- Cat(*wr_pend_i).eq(self.wr_pend_i),
+ dc = dm[y]
+ # wire up inputs from module to row cell inputs
+ m.d.comb += [dc.rd_pend_i.eq(self.rd_pend_i),
+ dc.wr_pend_i.eq(self.wr_pend_i),
]
return m
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