from migen.fhdl.std import * from migen.genlib.cdc import NoRetiming, MultiReg, GrayCounter from migen.genlib.record import layout_len, Record def _inc(signal, modulo): if modulo == 2**flen(signal): return signal.eq(signal + 1) else: return If(signal == (modulo - 1), signal.eq(0) ).Else( signal.eq(signal + 1) ) class _FIFOInterface: """ Data written to the input interface (`din`, `we`, `writable`) is buffered and can be read at the output interface (`dout`, `re`, `readable`). The data entry written first to the input also appears first on the output. Parameters ---------- width_or_layout : int, layout Bit width or `Record` layout for the data. depth : int Depth of the FIFO. Attributes ---------- din : in, width_or_layout Input data either flat or Record structured. writable : out There is space in the FIFO and `we` can be asserted to load new data. we : in Write enable signal to latch `din` into the FIFO. Does nothing if `writable` is not asserted. dout : out, width_or_layout Output data, same type as `din`. Only valid if `readable` is asserted. readable : out Output data `dout` valid, FIFO not empty. re : in Acknowledge `dout`. If asserted, the next entry will be available on the next cycle (if `readable` is high then). """ def __init__(self, width_or_layout, depth): self.we = Signal() self.writable = Signal() # not full self.re = Signal() self.readable = Signal() # not empty if isinstance(width_or_layout, list): self.din = Record(width_or_layout) self.dout = Record(width_or_layout) self.din_bits = self.din.raw_bits() self.dout_bits = self.dout.raw_bits() self.width = layout_len(width_or_layout) else: self.din = Signal(width_or_layout) self.dout = Signal(width_or_layout) self.din_bits = self.din self.dout_bits = self.dout self.width = width_or_layout class SyncFIFO(Module, _FIFOInterface): """Synchronous FIFO (first in, first out) Read and write interfaces are accessed from the same clock domain. If different clock domains are needed, use :class:`AsyncFIFO`. {interface} level : out Number of unread entries. flush : in Flush the FIFO discarding pending write. In the next cycle `readable` will be deasserted and `writable` will be asserted, `level` will be zero. """ __doc__ = __doc__.format(interface=_FIFOInterface.__doc__) def __init__(self, width_or_layout, depth): _FIFOInterface.__init__(self, width_or_layout, depth) self.flush = Signal() self.level = Signal(max=depth+1) ### do_write = Signal() do_read = Signal() self.comb += [ do_write.eq(self.writable & self.we), do_read.eq(self.readable & self.re) ] produce = Signal(max=depth) consume = Signal(max=depth) storage = Memory(self.width, depth) self.specials += storage wrport = storage.get_port(write_capable=True) self.specials += wrport self.comb += [ wrport.adr.eq(produce), wrport.dat_w.eq(self.din_bits), wrport.we.eq(do_write) ] self.sync += If(do_write, _inc(produce, depth)) rdport = storage.get_port(async_read=True) self.specials += rdport self.comb += [ rdport.adr.eq(consume), self.dout_bits.eq(rdport.dat_r) ] self.sync += If(do_read, _inc(consume, depth)) self.sync += [ If(self.flush, produce.eq(0), consume.eq(0), self.level.eq(0), ).Elif(do_write, If(~do_read, self.level.eq(self.level + 1)) ).Elif(do_read, self.level.eq(self.level - 1) ) ] self.comb += [ self.writable.eq(self.level != depth), self.readable.eq(self.level != 0) ] class SyncFIFOClassic(Module, _FIFOInterface): def __init__(self, width_or_layout, depth): _FIFOInterface.__init__(self, width_or_layout, depth) self.submodules.fifo = fifo = SyncFIFO(width_or_layout, depth) self.writable = fifo.writable self.din_bits = fifo.din_bits self.din = fifo.din self.we = fifo.we self.readable = fifo.readable self.re = fifo.re self.flush = fifo.flush self.level = fifo.level ### self.sync += [ If(self.re & self.readable, self.dout_bits.eq(fifo.dout_bits), )] class SyncFIFOBuffered(Module, _FIFOInterface): def __init__(self, width_or_layout, depth): _FIFOInterface.__init__(self, width_or_layout, depth) self.submodules.fifo = fifo = SyncFIFOClassic(width_or_layout, depth) self.writable = fifo.writable self.din_bits = fifo.din_bits self.din = fifo.din self.we = fifo.we self.dout_bits = fifo.dout_bits self.dout = fifo.dout self.flush = fifo.flush self.level = fifo.level ### self.comb += [ fifo.re.eq(fifo.readable & (~self.readable | self.re)), ] self.sync += [ If(self.flush, self.readable.eq(0), ).Elif(fifo.re, self.readable.eq(1), ).Elif(self.re, self.readable.eq(0), )] class AsyncFIFO(Module, _FIFOInterface): """Asynchronous FIFO (first in, first out) Read and write interfaces are accessed from different clock domains, named `read` and `write`. Use `RenameClockDomains` to rename to other names. {interface} """ __doc__ = __doc__.format(interface=_FIFOInterface.__doc__) def __init__(self, width_or_layout, depth): _FIFOInterface.__init__(self, width_or_layout, depth) ### depth_bits = log2_int(depth, True) produce = RenameClockDomains(GrayCounter(depth_bits+1), "write") consume = RenameClockDomains(GrayCounter(depth_bits+1), "read") self.submodules += produce, consume self.comb += [ produce.ce.eq(self.writable & self.we), consume.ce.eq(self.readable & self.re) ] produce_rdomain = Signal(depth_bits+1) self.specials += [ NoRetiming(produce.q), MultiReg(produce.q, produce_rdomain, "read") ] consume_wdomain = Signal(depth_bits+1) self.specials += [ NoRetiming(consume.q), MultiReg(consume.q, consume_wdomain, "write") ] if depth_bits == 1: self.comb += self.writable.eq((produce.q[-1] == consume_wdomain[-1]) | (produce.q[-2] == consume_wdomain[-2])) else: self.comb += [ self.writable.eq((produce.q[-1] == consume_wdomain[-1]) | (produce.q[-2] == consume_wdomain[-2]) | (produce.q[:-2] != consume_wdomain[:-2])) ] self.comb += self.readable.eq(consume.q != produce_rdomain) storage = Memory(self.width, depth) self.specials += storage wrport = storage.get_port(write_capable=True, clock_domain="write") self.specials += wrport self.comb += [ wrport.adr.eq(produce.q_binary[:-1]), wrport.dat_w.eq(self.din_bits), wrport.we.eq(produce.ce) ] rdport = storage.get_port(clock_domain="read") self.specials += rdport self.comb += [ rdport.adr.eq(consume.q_next_binary[:-1]), self.dout_bits.eq(rdport.dat_r) ]