from lib.sata.common import * tx_to_rx = [ ("write", 1), ("read", 1), ("count", 4) ] rx_to_tx = [ ("dma_activate", 1), ("data", 1), ("reg_d2h", 1) ] class SATACommandTX(Module): def __init__(self, transport, sector_size): self.sink = sink = Sink(command_tx_description(32)) self.to_rx = to_rx = Source(tx_to_rx) self.from_rx = from_rx = Sink(rx_to_tx) ### self.comb += [ transport.sink.pm_port.eq(0), transport.sink.features.eq(0), transport.sink.lba.eq(sink.sector), transport.sink.device.eq(0xe0), transport.sink.count.eq(sink.count), transport.sink.icc.eq(0), transport.sink.control.eq(0), ] self.fsm = fsm = FSM(reset_state="IDLE") fsm.act("IDLE", sink.ack.eq(0), If(sink.stb & sink.sop, If(sink.write, NextState("SEND_WRITE_DMA_CMD") ).Elif(sink.read, NextState("SEND_READ_DMA_CMD") ).Else( sink.ack.eq(1) ) ).Else( sink.ack.eq(1) ) ) fsm.act("SEND_WRITE_DMA_CMD", transport.sink.stb.eq(sink.stb), transport.sink.sop.eq(1), transport.sink.eop.eq(1), transport.sink.type.eq(fis_types["REG_H2D"]), transport.sink.c.eq(1), transport.sink.command.eq(regs["WRITE_DMA_EXT"]), If(sink.stb & transport.sink.ack, NextState("WAIT_DMA_ACTIVATE") ) ) fsm.act("WAIT_DMA_ACTIVATE", If(from_rx.dma_activate, NextState("SEND_DATA") ) ) fsm.act("SEND_DATA", transport.sink.stb.eq(sink.stb), transport.sink.sop.eq(sink.sop), transport.sink.eop.eq(sink.eop), transport.sink.type.eq(fis_types["DATA"]), transport.sink.data.eq(sink.data), sink.ack.eq(transport.sink.ack), If(sink.stb & sink.ack & sink.eop, NextState("IDLE") ) ) fsm.act("SEND_READ_DMA_CMD", transport.sink.stb.eq(sink.stb), transport.sink.sop.eq(1), transport.sink.eop.eq(1), transport.sink.type.eq(fis_types["REG_H2D"]), transport.sink.c.eq(1), transport.sink.command.eq(regs["READ_DMA_EXT"]), sink.ack.eq(transport.sink.ack), If(sink.stb & sink.ack, NextState("IDLE") ) ) self.comb += [ If(sink.stb, to_rx.write.eq(sink.write), to_rx.read.eq(sink.read), to_rx.count.eq(sink.count) ) ] class SATACommandRX(Module): def __init__(self, transport, sector_size, max_count): self.source = source = Source(command_rx_description(32)) self.to_tx = to_tx = Source(rx_to_tx) self.from_tx = from_tx = Sink(tx_to_rx) ### cmd_fifo = SyncFIFO(command_rx_cmd_description(32), 2) # Note: ideally depth=1 data_fifo = InsertReset(SyncFIFO(command_rx_data_description(32), (sector_size*max_count//4), buffered=True)) self.submodules += cmd_fifo, data_fifo def test_type(name): return transport.source.type == fis_types[name] dma_activate = Signal() self.fsm = fsm = FSM(reset_state="IDLE") fsm.act("IDLE", transport.source.ack.eq(1), If(from_tx.write, NextState("WAIT_WRITE_ACTIVATE") ).Elif(from_tx.read, NextState("WAIT_READ_DATA") ) ) fsm.act("WAIT_WRITE_ACTIVATE", transport.source.ack.eq(1), If(transport.source.stb, If(test_type("DMA_ACTIVATE_D2H"), dma_activate.eq(1), NextState("WAIT_WRITE_REG_D2H") ).Else( NextState("IDLE") # Generate an error ) ) ) fsm.act("WAIT_WRITE_REG_D2H", transport.source.ack.eq(1), If(transport.source.stb, If(test_type("REG_D2H"), NextState("PRESENT_WRITE_RESPONSE") ).Else( NextState("IDLE") # Generate an error ) ) ) fsm.act("PRESENT_WRITE_RESPONSE", cmd_fifo.sink.stb.eq(1), cmd_fifo.sink.write.eq(1), cmd_fifo.sink.success.eq(1), If(cmd_fifo.sink.stb & cmd_fifo.sink.ack, NextState("IDLE") ) ) fsm.act("WAIT_READ_DATA", transport.source.ack.eq(1), If(transport.source.stb, transport.source.ack.eq(0), If(test_type("DATA"), NextState("PRESENT_READ_DATA") ).Else( NextState("IDLE") # Generate an error ) ) ) fsm.act("PRESENT_READ_DATA", data_fifo.sink.stb.eq(transport.source.stb), data_fifo.sink.sop.eq(transport.source.sop), data_fifo.sink.eop.eq(transport.source.eop), data_fifo.sink.data.eq(transport.source.data), transport.source.ack.eq(data_fifo.sink.ack), If(data_fifo.sink.stb & data_fifo.sink.eop & data_fifo.sink.ack, NextState("WAIT_READ_REG_D2H") ) ) fsm.act("WAIT_READ_REG_D2H", transport.source.ack.eq(1), If(transport.source.stb, If(test_type("REG_D2H"), NextState("PRESENT_READ_RESPONSE") ).Else( NextState("IDLE") # Generate an error ) ) ) fsm.act("PRESENT_READ_RESPONSE", cmd_fifo.sink.stb.eq(1), cmd_fifo.sink.read.eq(1), cmd_fifo.sink.success.eq(1), cmd_fifo.sink.failed.eq(0), If(~cmd_fifo.fifo.readable, # Note: simulate a fifo with depth=1 If(cmd_fifo.sink.stb & cmd_fifo.sink.ack, If(cmd_fifo.sink.failed, data_fifo.reset.eq(1) ), NextState("IDLE") ) ) ) self.out_fsm = out_fsm = FSM(reset_state="IDLE") out_fsm.act("IDLE", If(cmd_fifo.source.stb & cmd_fifo.source.write, NextState("PRESENT_WRITE_RESPONSE"), ).Elif(cmd_fifo.source.stb & (cmd_fifo.source.read), If(cmd_fifo.source.success, NextState("PRESENT_READ_RESPONSE_SUCCESS"), ).Else( NextState("PRESENT_READ_RESPONSE_FAILED"), ) ) ) out_fsm.act("PRESENT_WRITE_RESPONSE", source.stb.eq(1), source.sop.eq(1), source.eop.eq(1), source.write.eq(1), source.success.eq(cmd_fifo.source.success), If(source.stb & source.ack, cmd_fifo.source.ack.eq(1), NextState("IDLE") ) ) out_fsm.act("PRESENT_READ_RESPONSE_SUCCESS", source.stb.eq(data_fifo.source.stb), source.read.eq(cmd_fifo.source.read), source.success.eq(1), source.sop.eq(data_fifo.source.sop), source.eop.eq(data_fifo.source.eop), source.data.eq(data_fifo.source.data), data_fifo.source.ack.eq(source.ack), If(source.stb & source.eop & source.ack, cmd_fifo.source.ack.eq(1), NextState("IDLE") ) ) out_fsm.act("PRESENT_READ_RESPONSE_FAILED", source.stb.eq(1), source.sop.eq(1), source.eop.eq(1), source.read.eq(cmd_fifo.source.read), source.failed.eq(1), If(source.stb & source.ack, cmd_fifo.source.ack.eq(1), NextState("IDLE") ) ) self.comb += [ to_tx.dma_activate.eq(dma_activate), ] class SATACommand(Module): def __init__(self, transport, sector_size=512, max_count=4): if max_count*sector_size > 8192: raise ValueError("sector_size * max_count must be <= 8192") self.tx = SATACommandTX(transport, sector_size) self.rx = SATACommandRX(transport, sector_size, max_count) self.comb += [ self.rx.to_tx.connect(self.tx.from_rx), self.tx.to_rx.connect(self.rx.from_tx) ] self.sink, self.source = self.tx.sink, self.rx.source