add remaining files

.gitignore

@@ -4,3 +4,5 @@ test
 *.vcd
 *.cfg
 *.txt
+# Bitstream build directories have _build as their suffixes
+*_build

bidirectionalIO.py

@@ -0,0 +1,25 @@
+from migen import *
+
+
+class BiDirectionalIO(Module):
+    def __init__(self, i_pads, o_pads):
+        self.i = Signal(4)
+        self.o = Signal(4)
+        self.t = Signal(4)
+
+        for i in range(4):
+            self.specials += Instance("OBUFTDS",
+                i_I=self.i[i],
+                o_O=o_pads[i].p,
+                o_OB=o_pads[i].n,
+                # Always chain the 3-states input to serializer
+                # Vivado will complain otherwise
+                i_T=self.t[i],
+            )
+        
+        for i in range(4):
+            self.specials += Instance("IBUFDS",
+                i_I=i_pads[i].p,
+                i_IB=i_pads[i].n,
+                o_O=self.o[i],
+            )

comm.py

@@ -1,8 +1,8 @@
 import serial
 
 
-def main():
-    comm = serial.Serial("/dev/ttyUSB3", 115200)
+def main(serial_port):
+    comm = serial.Serial(serial_port, 115200)
     # comm.write(b"Hello World!")
 
     # for _ in range(32):
@@ -19,4 +19,15 @@ def main():
     #         print(f'{byte[0]:0>8b}')
 
 if __name__ == "__main__":
-    main()
+    import argparse
+
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    args = parser.parse_args()
+
+    port_dict = {
+        "kasli": "/dev/ttyUSB3",
+        "efc": "/dev/ttyACM1",
+    }
+
+    main(port_dict[args.platform])

default.nix

@@ -7,14 +7,28 @@ let
         src = pkgs.fetchFromGitHub {
             owner = "m-labs";
             repo = "migen";
-            rev = "7bc4eb1387b39159a74c1dbd1b820728e0bfbbaa";
-            sha256 = "039jk8y7f0vhr32svg3nd23i88c0bhws8ngxwk9bdznfxvhiy1h6";
+            rev = "ccaee68e14d3636e1d8fb2e0864dd89b1b1f7384";
+            sha256 = "sha256-oYdeY0MbTReKbAwmSznnqw0wNawdInJoFJVWW3tesFA=";
             fetchSubmodules = true;
         };
 
         propagatedBuildInputs = with pkgs.python3Packages; [ colorama ];
     };
 
+    misoc = pkgs.python3Packages.buildPythonPackage rec {
+        name = "misoc";
+
+        src = pkgs.fetchFromGitHub {
+            owner = "m-labs";
+            repo = "misoc";
+            rev = "0cf0ebb7d4f56cc6d44a3dea3e386efab9d82419";
+            sha256 = "sha256-TI0agjSSMJtH4mgAMpSO128zxcwSo/AjY1B6AW7zBQQ=";
+            fetchSubmodules = true;
+        };
+
+        propagatedBuildInputs = with pkgs.python3Packages; [ jinja2 numpy pyserial asyncserial ] ++ [ migen ];
+    };
+
     vivadoDeps = pkgs: with pkgs; [
         libxcrypt
         ncurses5
@@ -47,6 +61,7 @@ in pkgs.mkShell {
     name = "UART-Testing";
     buildInputs = [
         migen
+        misoc
         pkgs.python3Packages.pyserial
         vivado
         vivadoEnv

flash.py

@@ -0,0 +1,60 @@
+import argparse
+import tempfile
+import subprocess
+
+
+def get_load_cmd(platform, variant):
+    return \
+'''target create xc7.spi0.proxy testee -chain-position xc7.tap
+flash bank spi0 jtagspi 0 0 0 0 xc7.spi0.proxy 0x2
+gdb_port disabled
+tcl_port disabled
+telnet_port disabled
+set error_msg "Trying to use configured scan chain anyway"
+if {[string first $error_msg [capture "init"]] != -1} {
+puts "Found error and exiting"
+exit}
+xadc_report xc7.tap
+pld load 0 {bscan_spi_xc7a100t.bit}
+flash probe spi0
+flash erase_sector spi0 0 42
+flash write_bank spi0 {''' + "{}".format(get_bitstream_path(platform, variant)) + '''} 0x0
+flash verify_bank spi0 {''' + "{}".format(get_bitstream_path(platform, variant)) + '''} 0x0
+xc7_program xc7.tap
+exit'''
+
+def get_build_dir(platform, variant):
+    return "{}_{}_build".format(platform, variant)
+
+def get_bitstream_path(platform, variant):
+    return get_build_dir(platform, variant)+"/top.bit"
+
+def run(platform, script):
+    # Dump script to a temp file
+    with tempfile.NamedTemporaryFile(mode="w", delete=False) as f:
+        f.write(script)
+    
+    board_path = {
+        "kasli": "board/kasli.cfg",
+        "efc": "efc.cfg",
+    }
+    subprocess.run([
+        "openocd", "-f", board_path[platform], "-f", f.name
+    ])
+
+supported_platform = [ "kasli", "efc" ]
+supported_variants = [ "master", "satellite" ]
+
+if __name__ == "__main__":
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    parser.add_argument("variant")
+    args = parser.parse_args()
+
+    if args.platform not in supported_platform:
+        raise ValueError("Unsupported platform")
+    if args.variant not in supported_variants:
+        raise ValueError("Unsupported variant")
+
+    script = get_load_cmd(args.platform, args.variant)
+    run(args.platform, script)

kasli_crg.py

@@ -3,8 +3,8 @@ from migen.build.platforms.sinara import kasli
 from migen.genlib.resetsync import AsyncResetSynchronizer
 
 
-class KasliCRG(Module):
-    def __init__(self, platform):
+class TransceiverCRG(Module):
+    def __init__(self, platform, clk125, gte=True):
         self.platform = platform
 
         # Generated clock domains
@@ -16,15 +16,38 @@ class KasliCRG(Module):
 
         # Configure system clock using GTP ports
         self.sys_clk_freq = 125e6
-        clk125 = self.platform.request("clk125_gtp")
         clk125_buf = Signal()
         clk125_div2 = Signal()
 
-        self.specials += Instance("IBUFDS_GTE2",
-            i_CEB=0,
-            i_I=clk125.p, i_IB=clk125.n,
-            o_O=clk125_buf,
-            o_ODIV2=clk125_div2)
+        if gte:
+            self.specials += Instance("IBUFDS_GTE2",
+                i_CEB=0,
+                i_I=clk125.p, i_IB=clk125.n,
+                o_O=clk125_buf,
+                o_ODIV2=clk125_div2)
+        else:
+            self.specials += Instance("IBUFDS",
+                i_I=clk125.p,
+                i_IB=clk125.n,
+                o_O=clk125_buf)
+
+            div2_pll_fb = Signal()
+            inner_pll_locked = Signal()
+            
+            self.specials += Instance("PLLE2_BASE",
+                p_CLKIN1_PERIOD=8.0,
+                i_CLKIN1=clk125_buf,
+
+                i_CLKFBIN=div2_pll_fb,
+                o_CLKFBOUT=div2_pll_fb,
+                o_LOCKED=inner_pll_locked,
+
+                # VCO @ 1GHz
+                p_CLKFBOUT_MULT=8, p_DIVCLK_DIVIDE=1,
+
+                # 200MHz for IDELAYCTRL
+                p_CLKOUT0_DIVIDE=16, p_CLKOUT0_PHASE=0.0, o_CLKOUT0=clk125_div2,
+            ),
 
         # MMCM to generate different frequencies
         mmcm_fb = Signal()

minimal_loopback.py

@@ -0,0 +1,180 @@
+from migen import *
+from sync_serdes import *
+from migen.genlib.fifo import SyncFIFO
+from migen.build.platforms.sinara import kasli
+from migen.genlib.misc import WaitTimer
+from kasli_crg import TransceiverCRG
+from eem_helpers import generate_pads
+from uart import UART
+from io_loopback import SingleIOLoopback
+
+
+class SingleSerDesLoopBack(Module):
+    def __init__(self, io_pad, sys_clk_freq, debug):
+        self.uart_rx = Signal()
+        self.uart_tx = Signal()
+
+        self.submodules.uart = UART(round((115200/sys_clk_freq)*2**32))
+        self.comb += [
+            self.uart.phy_rx.eq(self.uart_rx),
+            self.uart_tx.eq(self.uart.phy_tx),
+        ]
+        
+        self.submodules.tx = SingleLineTX()
+        self.submodules.rx = SingleLineRX()
+
+        # Debugging reader
+        self.submodules.bitslip_reader = BitSlipReader()
+        self.submodules.postslip_reader = BitSlipReader()
+
+        # Alignment modules
+        self.submodules.slave_aligner = SlaveAligner()
+
+        # The actual channel
+        self.submodules.channel = SingleIOLoopback(io_pad)
+
+        # Attach FIFO to UART TX, send rate is too slow w.r.t sysclk
+        self.submodules.tx_fifo = SyncFIFO(8, 64)
+
+        self.comb += [
+            # Repetitively send 0b00100
+            self.tx.txdata.eq(0b00100),
+
+            # Loopback channel
+            self.channel.i.eq(self.tx.ser_out),
+            self.rx.ser_in_no_dly.eq(self.channel.o),
+            self.channel.t.eq(self.tx.t_out),
+
+            # TX path
+            self.uart.tx_data.eq(self.tx_fifo.dout),
+            self.uart.tx_stb.eq(self.tx_fifo.readable),
+            self.tx_fifo.re.eq(self.uart.tx_ack),
+        ]
+
+        # Debugging logics
+        self.comb += [
+            self.bitslip_reader.loopback_rxdata.eq(self.rx.rxdata),
+            self.postslip_reader.loopback_rxdata.eq(self.rx.rxdata),
+            self.slave_aligner.loopback_rxdata.eq(self.rx.rxdata),
+
+            self.rx.master_bitslip.eq(
+                self.bitslip_reader.bitslip
+                | self.slave_aligner.master_bitslip
+                | self.postslip_reader.bitslip
+            ),
+            self.rx.slave_bitslip.eq(
+                self.bitslip_reader.bitslip
+                | self.slave_aligner.master_bitslip
+                | self.postslip_reader.bitslip
+            ),
+        ]
+
+        bitslip_count = Signal(3)
+
+        fsm = FSM(reset_state="WAIT_DONE")
+        self.submodules += fsm
+
+        fsm.act("WAIT_DONE",
+            self.bitslip_reader.start.eq(1),
+            If(self.bitslip_reader.done,
+                NextValue(bitslip_count, 0),
+                NextState("WRITE_UPPER"),
+            ),
+        )
+
+        fsm.act("WRITE_UPPER",
+            If(bitslip_count == 5,
+                NextState("WAIT_BITSLIP_ALIGNED"),
+            ).Elif(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][8:]),
+                NextState("WRITE_LOWER"),
+            ),
+        )
+
+        fsm.act("WRITE_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][:8]),
+                NextValue(bitslip_count, bitslip_count + 1),
+                NextState("WRITE_UPPER"),
+            )
+        )
+
+        fsm.act("WAIT_BITSLIP_ALIGNED",
+            self.slave_aligner.start.eq(1),
+            If(self.slave_aligner.done,
+                NextState("BARRIER_UPPER"),
+            ),
+        )
+
+        fsm.act("BARRIER_UPPER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0xFF),
+                NextState("BARRIER_LOWER"),
+            ),
+        )
+
+        fsm.act("BARRIER_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0xFF),
+                NextState("REWAIT_BITSLIP_READ_DONE"),
+            ),
+        )
+
+        fsm.act("REWAIT_BITSLIP_READ_DONE",
+            self.postslip_reader.start.eq(1),
+            If(self.postslip_reader.done,
+                NextValue(bitslip_count, 0),
+                NextState("REWRITE_UPPER"),
+            ),
+        )
+
+        fsm.act("REWRITE_UPPER",
+            If(bitslip_count == 5,
+                NextState("TERMINATE"),
+            ).Elif(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(self.postslip_reader.data_result[bitslip_count][8:]),
+                NextState("REWRITE_LOWER"),
+            ),
+        )
+
+        fsm.act("REWRITE_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(self.postslip_reader.data_result[bitslip_count][:8]),
+                NextValue(bitslip_count, bitslip_count + 1),
+                NextState("REWRITE_UPPER"),
+            )
+        )
+
+        fsm.act("TERMINATE",
+            NextState("TERMINATE"),
+        )
+
+        self.comb += self.tx.txdata.eq(0b00100)
+
+
+if __name__ == "__main__":
+    platform = kasli.Platform(hw_rev="v2.0")
+
+    # Generate pads for the I/O blocks
+    eem = 3
+    generate_pads(platform, eem)
+    pad = platform.request("dio{}".format(eem), 0)
+
+    crg = TransceiverCRG(platform, platform.request("clk125_gtp"))
+    top = SingleSerDesLoopBack(pad, crg.sys_clk_freq, True)
+
+    # Wire up UART core to the pads
+    uart_pads = platform.request("serial")
+    top.comb += [
+        top.uart_rx.eq(uart_pads.rx),
+        uart_pads.tx.eq(top.uart_tx),
+    ]
+
+    top.submodules += crg
+    platform.build(top)

multi_coders.py

@@ -0,0 +1,123 @@
+from migen import *
+from misoc.cores.code_8b10b import SingleEncoder, Decoder
+
+
+class MultiEncoder(Module):
+    # For 4-channel EEM
+    # Thus, no need for words parameter
+    # It is always a 2-wds -> 4-ch conversion
+    # Implement using crossbar, so we don't need to do clock domain conversion
+    # while maintaining proper disparity
+    def __init__(self, lsb_first=False):
+        WORDS = 2
+        # Keep the link layer interface identical to standard encoders
+        self.d = [Signal(8) for _ in range(WORDS)]
+        self.k = [Signal() for _ in range(WORDS)]
+
+        # Output interface is simplified because we have custom physical layer
+        self.output = [Signal(10) for _ in range(WORDS)]
+
+        # Module start signal
+        self.start = Signal()
+
+        # lsb_first should not be set set
+        # But technically if the same setting is reflected on the decoder
+        # It shouldn't be an issue
+        if lsb_first:
+            raise ValueError("lsb_first must not be set")
+
+        # Phase of the encoder
+        # Alternate crossbar between encoder and SERDES every cycle
+        phase = Signal()
+
+        # Intermediate registers for output and disparity
+        # More significant bits are buffered due to channel geometry
+        # Disparity bit is delayed. The same encoder is shared by 2 SERDES
+        output_bufs = [Signal(5) for _ in range(WORDS)]
+        disp_bufs = [Signal() for _ in range(WORDS)]
+
+        encoders = [SingleEncoder(lsb_first) for _ in range(WORDS)]
+        self.submodules += encoders
+
+        for d, k, output, output_buf, disp_buf, encoder in \
+                zip(self.d, self.k, self.output, output_bufs, disp_bufs, encoders):
+            self.comb += [
+                encoder.d.eq(d),
+                encoder.k.eq(k),
+                encoder.disp_in.eq(disp_buf),
+                # Implementing switching crossbar
+                If(phase,
+                    output.eq(Cat(encoder.output[0:5], output_buf))
+                ).Else(
+                    output.eq(Cat(output_buf, encoder.output[0:5]))
+                ),
+            ]
+            # Handle intermediate registers
+            self.sync += [
+                disp_buf.eq(encoder.disp_out),
+                output_buf.eq(encoder.output[5:10]),
+            ]
+
+        aligned = Signal()
+
+        self.sync += [
+            # Phase switching
+            phase.eq(~phase),
+            If(~aligned & self.start,
+                aligned.eq(1),
+                # Later statements take precedent
+                phase.eq(0),
+            ),
+        ]
+
+
+# Unlike the usual 8b10b decoder, it needs to know which SERDES to decode
+class CrossbarDecoder(Module):
+    def __init__(self, lsb_first=False):
+        self.raw_input = Signal(10)
+        self.d = Signal(8)
+        self.k = Signal()
+
+        # Notifier signal when group alignmnet is completed
+        self.start = Signal()
+        aligned = Signal()
+        phase = Signal()
+
+        # Intermediate register for input
+        buffer = Signal(5)
+
+        self.submodules.decoder = Decoder(lsb_first)
+
+        # lsb_first should not be set set
+        # But technically if the same setting is reflected on the decoder
+        # It shouldn't be an issue
+        if lsb_first:
+            raise ValueError("lsb_first must not be set")
+
+        # Update phase & synchronous elements
+        self.sync += [
+            phase.eq(~phase),
+            If(~aligned & self.start,
+                aligned.eq(1),
+                phase.eq(0),
+            ),
+            If(phase,
+                buffer.eq(self.raw_input[:5]),
+            ).Else(
+                buffer.eq(self.raw_input[5:])
+            ),
+        ]
+        
+        # Send appropriate input to decoder
+        self.comb += [
+            If(phase,
+                self.decoder.input.eq(Cat(buffer, self.raw_input[5:])),
+            ).Else(
+                self.decoder.input.eq(Cat(buffer, self.raw_input[:5])),
+            ),
+        ]
+
+        self.comb += [
+            self.d.eq(self.decoder.d),
+            self.k.eq(self.decoder.k),
+        ]

multi_serdes_channel.py

@@ -0,0 +1,259 @@
+from migen import *
+from sync_serdes import MultiLineRX, MultiLineTX
+from migen.genlib.fifo import SyncFIFO
+from migen.build.platforms.sinara import kasli, efc
+from multi_coders import MultiEncoder, CrossbarDecoder
+from kasli_crg import TransceiverCRG
+from eem_helpers import generate_pads
+from uart import UART
+from io_loopback import SingleIOLoopback, IOLoopBack
+
+
+class MultiTransceiverChannel(Module):
+    def __init__(self, io_pads, sys_clk_freq):
+        self.uart_rx = Signal()
+        self.uart_tx = Signal()
+
+        self.submodules.uart = UART(round((115200/sys_clk_freq)*2**32))
+        self.comb += [
+            self.uart.phy_rx.eq(self.uart_rx),
+            self.uart_tx.eq(self.uart.phy_tx),
+        ]
+
+        # SERDES impl
+        self.submodules.tx = MultiLineTX()
+        self.submodules.rx = MultiLineRX()
+
+        # 8b10b encoder & decoder
+        self.submodules.encoder = MultiEncoder(lsb_first=False)
+        decoders = [ CrossbarDecoder(lsb_first=False) for _ in range(2) ]
+        self.submodules += decoders
+
+        # The actual channel
+        self.submodules.channel = IOLoopBack(io_pads)
+
+        # FIFO to record transmission received
+        rx_records = SyncFIFO(16, 128)
+        self.submodules += rx_records
+
+        # Attach FIFO to UART TX, send rate is too slow w.r.t sysclk
+        self.submodules.tx_fifo = SyncFIFO(8, 64)
+
+        self.comb += [
+            # Loopback channel
+            self.channel.i.eq(self.tx.ser_out),
+            self.channel.t.eq(self.tx.t_out),
+            self.rx.ser_in_no_dly.eq(self.channel.o),
+
+            # Link decoders
+            decoders[0].raw_input.eq(self.rx.rxdata[:10]),
+            decoders[1].raw_input.eq(self.rx.rxdata[10:]),
+            # Default encoder linkage
+            self.tx.txdata.eq(Cat(self.encoder.output[0], self.encoder.output[1])),
+
+            # UART TX path
+            self.uart.tx_data.eq(self.tx_fifo.dout),
+            self.uart.tx_stb.eq(self.tx_fifo.readable),
+            self.tx_fifo.re.eq(self.uart.tx_ack),
+
+            # Immediate start RX alignment procedure
+            self.rx.start.eq(1),
+        ]
+
+        rx_fsm = FSM(reset_state="WAIT_GROUP_ALIGN")
+        self.submodules += rx_fsm
+
+        rx_fsm.act("WAIT_GROUP_ALIGN",
+            If(self.rx.align_done & rx_records.writable,
+                rx_records.din.eq(self.rx.rxdata),
+                rx_records.we.eq(1),
+            ),
+            If(self.rx.err,
+                NextState("WRITE_ERR_UPPER"),
+            ).Elif(self.rx.rxdata == 0b11111111111111111111,
+                decoders[0].start.eq(1),
+                decoders[1].start.eq(1),
+                NextState("RECORD_TRANSMISSION"),
+            ),
+        )
+
+        rx_fsm.act("WRITE_ERR_UPPER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0b01010101),
+                NextState("WRITE_ERR_LOWER"),
+            ),
+        )
+
+        rx_fsm.act("WRITE_ERR_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0b10101010),
+                NextState("TERMINATE"),
+            ),
+        )
+
+        rx_fsm.act("RECORD_TRANSMISSION",
+            If(rx_records.writable,
+                rx_records.din.eq(Cat(decoders[0].d, decoders[1].d)),
+                rx_records.we.eq(1),
+            ).Else(
+                NextState("DUMP_TRANSMISSION_UPPER"),
+            )
+        )
+
+        rx_fsm.act("DUMP_TRANSMISSION_UPPER",
+            If(rx_records.readable,
+                If(self.tx_fifo.writable,
+                    self.tx_fifo.we.eq(1),
+                    self.tx_fifo.din.eq(rx_records.dout[8:]),
+                    NextState("DUMP_TRANSMISSION_LOWER"),
+                )
+            ).Else(
+                NextState("TERMINATE"),
+            ),
+        )
+
+        rx_fsm.act("DUMP_TRANSMISSION_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(rx_records.dout[:8]),
+                rx_records.re.eq(1),
+                NextState("DUMP_TRANSMISSION_UPPER"),
+            )
+        )
+
+        rx_fsm.act("TERMINATE",
+            NextState("TERMINATE")
+        )
+
+        tx_fsm = FSM(reset_state="SEND_TRAINING")
+        self.submodules += tx_fsm
+
+        tx_fsm.act("SEND_TRAINING",
+            self.tx.txdata.eq(0b00100001000010000100),
+            If(self.rx.align_done,
+                NextState("SEND_ZERO"),
+            ),
+        )
+
+        send_zero_duration = Signal(2)
+
+        tx_fsm.act("SEND_ZERO",
+            self.tx.txdata.eq(0),
+            If(send_zero_duration == 0b11,
+                NextState("SEND_PULSE"),
+            ).Else(
+                NextValue(send_zero_duration, send_zero_duration + 1),
+            ),
+        )
+
+        tx_fsm.act("SEND_PULSE",
+            self.tx.txdata.eq(0b11111111111111111111),
+            self.encoder.start.eq(1),
+            NextState("WAIT_GROUP_ALIGN"),
+        )
+
+        data = [ Signal(8) for _ in range(2) ]
+
+        tx_fsm.act("WAIT_GROUP_ALIGN",
+            If(self.rx.delay_done,
+                NextValue(data[0], 0x80),
+                NextValue(data[1], 0x7F),
+                NextState("TERMINATE"),
+            ),
+        )
+
+        tx_fsm.act("TERMINATE",
+            self.encoder.d[0].eq(data[0]),
+            self.encoder.d[1].eq(data[1]),
+            self.encoder.k[0].eq(0),
+            self.encoder.k[1].eq(0),
+            NextValue(data[0], data[0] + 1),
+            NextValue(data[1], data[1] - 1),
+            NextState("TERMINATE"),
+        )
+
+        # tx_fsm.act("SEND_ARB_DATA1",
+        #     self.encoder.d[0].eq(0xDE),
+        #     self.encoder.d[1].eq(0xAD),
+        #     self.encoder.k[0].eq(0),
+        #     self.encoder.k[1].eq(0),
+        #     NextState("SEND_ARB_DATA2"),
+        # )
+
+        # tx_fsm.act("SEND_ARB_DATA2",
+        #     self.encoder.d[0].eq(0xBE),
+        #     self.encoder.d[1].eq(0xEF),
+        #     self.encoder.k[0].eq(0),
+        #     self.encoder.k[1].eq(0),
+        #     NextState("SEND_ARB_DATA3"),
+        # )
+
+        # tx_fsm.act("SEND_ARB_DATA3",
+        #     self.encoder.d[0].eq(0xBA),
+        #     self.encoder.d[1].eq(0xD0),
+        #     self.encoder.k[0].eq(0),
+        #     self.encoder.k[1].eq(0),
+        #     NextState("SEND_ARB_DATA4"),
+        # )
+
+        # tx_fsm.act("SEND_ARB_DATA4",
+        #     self.encoder.d[0].eq(0xCA),
+        #     self.encoder.d[1].eq(0xFE),
+        #     self.encoder.k[0].eq(0),
+        #     self.encoder.k[1].eq(0),
+        #     NextState("TERMINATE"),
+        # )
+
+        # tx_fsm.act("TERMINATE",
+        #     self.encoder.d[0].eq(0xAD),
+        #     self.encoder.d[1].eq(0xDE),
+        #     self.encoder.k[0].eq(0),
+        #     self.encoder.k[1].eq(0),
+        #     NextState("TERMINATE"),
+        # )
+
+
+if __name__ == "__main__":
+    import argparse
+
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    args = parser.parse_args()
+
+    platform_dict = {
+        "kasli": kasli.Platform(hw_rev="v2.0"),
+        "efc": efc.Platform(),
+    }
+
+    sysclk_name = {
+        "kasli": "clk125_gtp",
+        "efc": "gtp_clk",
+    }
+
+    platform = platform_dict[args.platform]
+    sysclk = platform.request(sysclk_name[args.platform])
+
+    # Generate pads for the I/O blocks
+    # Using EEM1 for both as both EFC and Kasli has EEM1
+    # EEM1 are not interconnected
+    eem = 4
+    generate_pads(platform, eem)
+    pads = [
+        platform.request("dio{}".format(eem), i) for i in range(4)
+    ]
+    # pad = platform.request("dio{}".format(eem), 0)
+
+    crg = TransceiverCRG(platform, sysclk)
+    top = MultiTransceiverChannel(pads, crg.sys_clk_freq)
+
+    # Wire up UART core to the pads
+    uart_pads = platform.request("serial")
+    top.comb += [
+        top.uart_rx.eq(uart_pads.rx),
+        uart_pads.tx.eq(top.uart_tx),
+    ]
+
+    top.submodules += crg
+    platform.build(top)

multi_serdes_loopback.py

@@ -0,0 +1,230 @@
+from migen import *
+from sync_serdes import MultiLineRX, MultiLineTX
+from migen.genlib.fifo import SyncFIFO
+from migen.build.platforms.sinara import kasli, efc
+from kasli_crg import TransceiverCRG
+from eem_helpers import generate_pads
+from uart import UART
+from io_loopback import SingleIOLoopback, IOLoopBack
+
+
+class MultiSerDesLoopBack(Module):
+    def __init__(self, io_pads, sys_clk_freq):
+        self.uart_rx = Signal()
+        self.uart_tx = Signal()
+
+        self.submodules.uart = UART(round((115200/sys_clk_freq)*2**32))
+        self.comb += [
+            self.uart.phy_rx.eq(self.uart_rx),
+            self.uart_tx.eq(self.uart.phy_tx),
+        ]
+
+        self.submodules.tx = MultiLineTX()
+        self.submodules.rx = MultiLineRX()
+
+        # The actual channel
+        self.submodules.channel = IOLoopBack(io_pads)
+
+        # Attach FIFO to UART TX, send rate is too slow w.r.t sysclk
+        self.submodules.tx_fifo = SyncFIFO(8, 64)
+
+        self.comb += [
+            # Repetitively send 0b00100
+            # Note: Replicate() doesn't work, 0b00100 is lowered into 3'd4
+            # I need 5'd4 for the replicate operator in Verilog
+            self.tx.txdata.eq(0b00100001000010000100),
+
+            # Loopback channel
+            self.channel.i.eq(self.tx.ser_out),
+            self.channel.t.eq(self.tx.t_out),
+            self.rx.ser_in_no_dly.eq(self.channel.o),
+
+            # TX path
+            self.uart.tx_data.eq(self.tx_fifo.dout),
+            self.uart.tx_stb.eq(self.tx_fifo.readable),
+            self.tx_fifo.re.eq(self.uart.tx_ack),
+
+            # Just start RX alignment, no reason to wait
+            self.rx.start.eq(1),
+        ]
+
+        self.submodules.rx_fsm = FSM(reset_state="WAIT_GROUP_ALIGN")
+
+        sampled_rxdata = Array(Signal(20) for _ in range(16))
+        sample_idx = Signal(4)
+
+        self.rx_fsm.act("WAIT_GROUP_ALIGN",
+            If(self.rx.err,
+                NextState("WRITE_ERR_UPPER"),
+            ).Elif(self.rx.rxdata == 0b11111111111111111111,
+                NextValue(sampled_rxdata[0], self.rx.rxdata),
+                NextValue(sample_idx, 1),
+                NextState("SAMPLE_RXDATA"),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_ERR_UPPER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0b01010101),
+                NextState("WRITE_ERR_LOWER"),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_ERR_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(0b10101010),
+                NextState("TERMINATE"),
+            ),
+        )
+
+        self.rx_fsm.act("SAMPLE_RXDATA",
+            If(sample_idx == 15,
+                NextValue(sample_idx, 0),
+                NextState("WRITE_PATTERN_FIRST_UPPER"),
+            ).Else(
+                NextValue(sampled_rxdata[sample_idx], self.rx.rxdata),
+                NextValue(sample_idx, sample_idx + 1),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_PATTERN_FIRST_UPPER",
+            If(sample_idx == 15,
+                NextState("TERMINATE"),
+            ).Elif(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(sampled_rxdata[sample_idx][8:10]),
+                NextState("WRITE_PATTERN_FIRST_LOWER"),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_PATTERN_FIRST_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(sampled_rxdata[sample_idx][:8]),
+                NextState("WRITE_PATTERN_SECOND_UPPER"),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_PATTERN_SECOND_UPPER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(sampled_rxdata[sample_idx][18:20]),
+                NextState("WRITE_PATTERN_SECOND_LOWER"),
+            ),
+        )
+
+        self.rx_fsm.act("WRITE_PATTERN_SECOND_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(sampled_rxdata[sample_idx][10:18]),
+                NextValue(sample_idx, sample_idx + 1),
+                NextState("WRITE_PATTERN_FIRST_UPPER"),
+            ),
+        )
+
+        self.rx_fsm.act("TERMINATE",
+            NextState("TERMINATE"),
+        )
+
+        self.submodules.tx_fsm = FSM(reset_state="SEND_TRAINING")
+        
+        self.tx_fsm.act("SEND_TRAINING",
+            self.tx.txdata.eq(0b00100001000010000100),
+            If(self.rx.align_done,
+                NextState("SEND_ZERO"),
+            ),
+        )
+
+        send_zero_duration = Signal(2)
+
+        self.tx_fsm.act("SEND_ZERO",
+            self.tx.txdata.eq(0),
+            If(send_zero_duration == 0b11,
+                NextState("SEND_PULSE"),
+            ).Else(
+                NextValue(send_zero_duration, send_zero_duration + 1),
+            ),
+        )
+
+        self.tx_fsm.act("SEND_PULSE",
+            self.tx.txdata.eq(0b11111111111111111111),
+            NextState("WAIT_GROUP_ALIGN"),
+        )
+
+        self.tx_fsm.act("WAIT_GROUP_ALIGN",
+            self.tx.txdata.eq(0),
+            If(self.rx.delay_done,
+                NextState("SEND_ARB_DATA1"),
+            ),
+        )
+
+        self.tx_fsm.act("SEND_ARB_DATA1",
+            self.tx.txdata.eq(0b00111001110011100111),
+            NextState("SEND_ARB_DATA2"),
+        )
+
+        self.tx_fsm.act("SEND_ARB_DATA2",
+            self.tx.txdata.eq(0),
+            NextState("SEND_ARB_DATA3"),
+        )
+
+        self.tx_fsm.act("SEND_ARB_DATA3",
+            self.tx.txdata.eq(0xDEADB),
+            NextState("SEND_ARB_DATA4"),
+        )
+
+        self.tx_fsm.act("SEND_ARB_DATA4",
+            self.tx.txdata.eq(0xBCAFE),
+            NextState("TERMINATE"),
+        )
+
+        self.tx_fsm.act("TERMINATE",
+            self.tx.txdata.eq(0),
+            NextState("TERMINATE"),
+        )
+
+
+if __name__ == "__main__":
+    import argparse
+
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    args = parser.parse_args()
+
+    platform_dict = {
+        "kasli": kasli.Platform(hw_rev="v2.0"),
+        "efc": efc.Platform(),
+    }
+
+    sysclk_name = {
+        "kasli": "clk125_gtp",
+        "efc": "gtp_clk",
+    }
+
+    platform = platform_dict[args.platform]
+    sysclk = platform.request(sysclk_name[args.platform])
+
+    # Generate pads for the I/O blocks
+    # Using EEM1 for both as both EFC and Kasli has EEM1
+    # EEM1 are not interconnected
+    eem = 1
+    generate_pads(platform, eem)
+    pads = [
+        platform.request("dio{}".format(eem), i+4) for i in range(4)
+    ]
+    # pad = platform.request("dio{}".format(eem), 0)
+
+    crg = TransceiverCRG(platform, sysclk)
+    top = MultiSerDesLoopBack(pads, crg.sys_clk_freq)
+
+    # Wire up UART core to the pads
+    uart_pads = platform.request("serial")
+    top.comb += [
+        top.uart_rx.eq(uart_pads.rx),
+        uart_pads.tx.eq(top.uart_tx),
+    ]
+
+    top.submodules += crg
+    platform.build(top)

pulse_read_rx.py

@@ -0,0 +1,255 @@
+from migen import *
+from migen.genlib.fifo import SyncFIFO
+from migen.genlib.misc import WaitTimer
+from migen.build.platforms.sinara import kasli, efc
+from eem_helpers import generate_pads
+from serdes_comm import BiDirectionalIO
+from sync_serdes import SingleLineRX, BitSlipReader, SlaveAligner
+from uart_log import UARTLogger
+from kasli_crg import TransceiverCRG
+
+
+class SingleLineReader(Module):
+    def __init__(self, uart_log, i_pads, o_pads):
+        # UART Logger
+        self.submodules.uart_logger = uart_log
+
+        # Recorder
+        self.submodules.rx_buffer = SyncFIFO(10, 64)
+
+        # PHY Channel
+        self.submodules.channel = BiDirectionalIO(i_pads, o_pads)
+
+        # Single line RX SERDES
+        self.submodules.rx = SingleLineRX()
+
+        # bitslip reader
+        self.submodules.bitslip_reader = BitSlipReader()
+        self.submodules.postslip_reader = BitSlipReader()
+
+        # Alignment modules
+        self.submodules.slave_aligner = SlaveAligner()
+
+        # Connect SERDES to PHY
+        self.comb += [
+            self.rx.ser_in_no_dly.eq(self.channel.o[0]),
+        ]
+
+        # Debugging logics
+        self.comb += [
+            self.bitslip_reader.loopback_rxdata.eq(self.rx.rxdata),
+            self.postslip_reader.loopback_rxdata.eq(self.rx.rxdata),
+            self.slave_aligner.loopback_rxdata.eq(self.rx.rxdata),
+
+            self.rx.master_bitslip.eq(
+                self.bitslip_reader.bitslip
+                | self.slave_aligner.master_bitslip
+                | self.postslip_reader.bitslip
+            ),
+            self.rx.slave_bitslip.eq(
+                self.bitslip_reader.bitslip
+                | self.slave_aligner.master_bitslip
+                | self.postslip_reader.bitslip
+            ),
+        ]
+
+        bitslip_count = Signal(3)
+
+        fsm = FSM(reset_state="WAIT_DONE")
+        self.submodules += fsm
+
+        fsm.act("WAIT_DONE",
+            self.bitslip_reader.start.eq(1),
+            If(self.bitslip_reader.done,
+                NextValue(bitslip_count, 0),
+                NextState("WRITE_UPPER"),
+            ),
+        )
+
+        fsm.act("WRITE_UPPER",
+            If(bitslip_count == 5,
+                NextState("WAIT_BITSLIP_ALIGNED"),
+            ).Elif(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][8:]),
+                NextState("WRITE_LOWER"),
+            ),
+        )
+
+        fsm.act("WRITE_LOWER",
+            If(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][:8]),
+                NextValue(bitslip_count, bitslip_count + 1),
+                NextState("WRITE_UPPER"),
+            )
+        )
+
+        fsm.act("WAIT_BITSLIP_ALIGNED",
+            self.slave_aligner.start.eq(1),
+            If(self.slave_aligner.done,
+                NextState("BARRIER_UPPER"),
+            ),
+        )
+
+        fsm.act("BARRIER_UPPER",
+            If(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(0xFF),
+                NextState("BARRIER_LOWER"),
+            ),
+        )
+
+        fsm.act("BARRIER_LOWER",
+            If(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(0xFF),
+                NextState("REWAIT_BITSLIP_READ_DONE"),
+            ),
+        )
+
+        fsm.act("REWAIT_BITSLIP_READ_DONE",
+            self.postslip_reader.start.eq(1),
+            If(self.postslip_reader.done,
+                NextValue(bitslip_count, 0),
+                NextState("REWRITE_UPPER"),
+            ),
+        )
+
+        fsm.act("REWRITE_UPPER",
+            If(bitslip_count == 5,
+                NextState("TERMINATE"),
+            ).Elif(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(self.postslip_reader.data_result[bitslip_count][8:]),
+                NextState("REWRITE_LOWER"),
+            ),
+        )
+
+        fsm.act("REWRITE_LOWER",
+            If(self.uart_logger.tx_fifo.writable,
+                self.uart_logger.tx_fifo.we.eq(1),
+                self.uart_logger.tx_fifo.din.eq(self.postslip_reader.data_result[bitslip_count][:8]),
+                NextValue(bitslip_count, bitslip_count + 1),
+                NextState("REWRITE_UPPER"),
+            )
+        )
+
+        fsm.act("TERMINATE",
+            NextState("TERMINATE"),
+        )
+
+        # self.submodules.wait_timer = WaitTimer(127)
+        # shift_count = Signal(5)
+
+        # self.submodules.fsm = FSM(reset_state="WAIT")
+
+        # self.fsm.act("WAIT",
+        #     self.wait_timer.wait.eq(1),
+        #     If(shift_count == 10,
+        #         NextState("DUMP_UPPER"),
+        #     ).Elif(self.wait_timer.done,
+        #         NextState("MEASURE"),
+        #     ),
+        # )
+
+        # self.fsm.act("MEASURE",
+        #     If(self.rx_buffer.writable,
+        #         self.rx_buffer.we.eq(1),
+        #         self.rx_buffer.din.eq(self.rx.rxdata),
+        #         NextState("SHIFT1"),
+        #     ),
+        # )
+
+        # self.fsm.act("SHIFT1",
+        #     self.rx.master_bitslip.eq(1),
+        #     self.rx.slave_bitslip.eq(1),
+        #     NextState("GAP"),
+        # )
+
+        # self.fsm.act("GAP",
+        #     NextState("SHIFT2"),
+        # )
+
+        # self.fsm.act("SHIFT2",
+        #     self.rx.master_bitslip.eq(1),
+        #     self.rx.slave_bitslip.eq(1),
+        #     NextValue(shift_count, shift_count + 1),
+        #     NextState("WAIT"),
+        # )
+
+        # self.fsm.act("DUMP_UPPER",
+        #     If(self.rx_buffer.readable,
+        #         If(self.uart_logger.tx_fifo.writable,
+        #             self.uart_logger.tx_fifo.we.eq(1),
+        #             self.uart_logger.tx_fifo.din.eq(self.rx_buffer.dout[8:]),
+        #             NextState("DUMP_LOWER"),
+        #         ),
+        #     ).Else(
+        #         NextState("TERMINATE"),
+        #     )
+        # )
+
+        # self.fsm.act("DUMP_LOWER",
+        #     If(self.uart_logger.tx_fifo.writable,
+        #         self.uart_logger.tx_fifo.we.eq(1),
+        #         self.uart_logger.tx_fifo.din.eq(self.rx_buffer.dout[:8]),
+        #         self.rx_buffer.re.eq(1),
+        #         NextState("DUMP_UPPER"),
+        #     ),
+        # )
+
+        # self.fsm.act("TERMINATE",
+        #     NextState("TERMINATE"),
+        # )
+
+
+if __name__ == "__main__":
+    import argparse
+    import functools
+    import os
+
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    args = parser.parse_args()
+
+    platform_dict = {
+        "kasli": kasli.Platform(hw_rev="v2.0"),
+        "efc": efc.Platform(),
+    }
+
+    sysclk_name = {
+        "kasli": "clk125_gtp",
+        "efc": "gtp_clk",
+    }
+
+    platform = platform_dict[args.platform]
+    sysclk = platform.request(sysclk_name[args.platform])
+    
+    # Generate pads for the I/O blocks
+    for eem in range(2):
+        generate_pads(platform, eem)
+    data_eem = 0
+
+    i_pads = [
+        platform.request("dio{}".format(data_eem), i) for i in range(4)
+    ]
+    o_pads = [
+        platform.request("dio{}".format(data_eem), i+4) for i in range(4)
+    ]
+
+    crg = TransceiverCRG(platform, sysclk)
+    uart_logger = UARTLogger(crg.sys_clk_freq)
+    top = SingleLineReader(uart_logger, i_pads, o_pads)
+
+    # Wire up UART core to the pads
+    uart_pads = platform.request("serial")
+    top.comb += [
+        uart_logger.uart_rx.eq(uart_pads.rx),
+        uart_pads.tx.eq(uart_logger.uart_tx),
+    ]
+
+    top.submodules += crg
+
+    output_dir = "{}_{}_build".format(args.platform, "satellite")
+    platform.build(top, build_dir=output_dir)

serdes_comm.py

@@ -0,0 +1,395 @@
+from migen import *
+from sync_serdes import MultiLineRX, MultiLineTX
+from multi_coders import MultiEncoder, CrossbarDecoder
+from migen.build.platforms.sinara import kasli, efc
+from eem_helpers import generate_pads
+from kasli_crg import TransceiverCRG
+from uart import UART
+from migen.genlib.fifo import SyncFIFO
+
+
+class BiDirectionalIO(Module):
+    def __init__(self, i_pads, o_pads):
+        self.i = Signal(4)
+        self.o = Signal(4)
+        self.t = Signal(4)
+
+        for i in range(4):
+            self.specials += Instance("OBUFTDS",
+                i_I=self.i[i],
+                o_O=o_pads[i].p,
+                o_OB=o_pads[i].n,
+                # Always chain the 3-states input to serializer
+                # Vivado will complain otherwise
+                i_T=self.t[i],
+            )
+        
+        for i in range(4):
+            self.specials += Instance("IBUFDS",
+                i_I=i_pads[i].p,
+                i_IB=i_pads[i].n,
+                o_O=self.o[i],
+            )
+
+
+class ClockOut(Module):
+    def __init__(self, clk_out):
+        self.clk = Signal()
+        # clk_buffer = Signal()
+        # clk_se = Signal()
+
+        # self.specials += Instance("BUFIO",
+        #     i_I=self.clk,
+        #     o_O=clk_buffer,
+        # )
+
+        # self.specials += Instance("ODDR",
+        #     i_C=clk_buffer, i_CE=1, i_D1=0, i_D2=1, o_Q=clk_se),
+
+        self.specials += Instance("OBUFDS",
+            i_I=self.clk,
+            o_O=clk_out.p,
+            o_OB=clk_out.n,
+        )
+
+
+class Master(Module):
+    def __init__(self, i_pads, o_pads):
+        self.sysclk = ClockSignal("sys")
+        self.submodules.tx = MultiLineTX()
+        self.submodules.rx = MultiLineRX()
+        self.submodules.channel = BiDirectionalIO(i_pads, o_pads)
+
+        self.submodules.encoder = MultiEncoder(lsb_first=False)
+        decoders = [ CrossbarDecoder(lsb_first=False) for _ in range(2) ]
+        self.submodules += decoders
+
+        self.comb += [
+            # Transmitter to SERDES
+            self.channel.i.eq(self.tx.ser_out),
+            self.channel.t.eq(self.tx.t_out),
+
+            # SERDES to receiver
+            self.rx.ser_in_no_dly.eq(self.channel.o),
+
+            # Connect encoders & decoders by default
+            # Overrule the encoder connection during alignment
+            self.tx.txdata.eq(Cat(self.encoder.output[0], self.encoder.output[1])),
+            decoders[0].raw_input.eq(self.rx.rxdata[:10]),
+            decoders[1].raw_input.eq(self.rx.rxdata[10:]),
+        ]
+
+        tx_fsm = FSM(reset_state="SEND_TRAINING")
+        self.submodules += tx_fsm
+
+        tx_fsm.act("SEND_TRAINING",
+            self.tx.txdata.eq(0b00100001000010000100),
+            # Keep sending the training sequence unless
+            # an identifier is received
+            NextState("SEND_TRAINING"),
+            # If(self.rx.rxdata == 0b11111111111111111111,
+            #     NextState("WAIT_IDENT_END"),
+            # ),
+        )
+
+        tx_fsm.act("WAIT_IDENT_END",
+            self.tx.txdata.eq(0),
+            If(self.rx.rxdata != 0b11111111111111111111,
+                NextState("SEND_ZERO"),
+            ),
+        )
+
+        send_zero_duration = Signal(3)
+
+        tx_fsm.act("SEND_ZERO",
+            self.tx.txdata.eq(0),
+            If(send_zero_duration == 0b111,
+                NextState("SEND_PULSE"),
+            ).Else(
+                NextValue(send_zero_duration, send_zero_duration + 1),
+            ),
+        )
+
+        tx_fsm.act("SEND_PULSE",
+            self.tx.txdata.eq(0b11111111111111111111),
+            self.encoder.start.eq(1),
+            # Slave decoder start will be triggered by this state
+            NextState("WAIT_GROUP_ALIGN"),
+        )
+
+        data = [ Signal(8) for _ in range(2) ]
+
+        tx_fsm.act("WAIT_GROUP_ALIGN",
+            # Wait for the identifier from the slave
+            # TODO: Align the master receiver after
+            If(self.rx.rxdata == 0b11111111111111111111,
+                NextValue(data[0], 0x80),
+                NextValue(data[1], 0x7F),
+                NextState("TERMINATE"),
+            ),
+        )
+
+        tx_fsm.act("TERMINATE",
+            self.encoder.d[0].eq(0x89),
+            self.encoder.d[1].eq(0x75),
+            NextValue(data[0], data[0] + 1),
+            NextValue(data[1], data[1] - 1),
+            NextState("TERMINATE"),
+        )
+
+
+class Satellite(Module):
+    def __init__(self, i_pads, o_pads, sys_clk_freq):
+        self.uart_rx = Signal()
+        self.uart_tx = Signal()
+
+        self.submodules.uart = UART(round((115200/sys_clk_freq)*2**32))
+        self.comb += [
+            self.uart.phy_rx.eq(self.uart_rx),
+            self.uart_tx.eq(self.uart.phy_tx),
+        ]
+
+        # Attach FIFO to UART TX, send rate is too slow w.r.t sysclk
+        self.submodules.tx_fifo = SyncFIFO(8, 64)
+
+        self.comb += [
+            # UART TX path
+            self.uart.tx_data.eq(self.tx_fifo.dout),
+            self.uart.tx_stb.eq(self.tx_fifo.readable),
+            self.tx_fifo.re.eq(self.uart.tx_ack),
+        ]
+
+        self.submodules.tx = MultiLineTX()
+        self.submodules.rx = MultiLineRX()
+        self.submodules.channel = BiDirectionalIO(i_pads, o_pads)
+
+        self.submodules.encoder = MultiEncoder(lsb_first=False)
+        decoders = [ CrossbarDecoder(lsb_first=False) for _ in range(2) ]
+        self.submodules += decoders
+
+        self.comb += [
+            # Transmitter to SERDES
+            self.channel.i.eq(self.tx.ser_out),
+            self.channel.t.eq(self.tx.t_out),
+
+            # SERDES to receiver
+            self.rx.ser_in_no_dly.eq(self.channel.o),
+
+            # Immediately start alignment for RX
+            self.rx.start.eq(1),
+
+            # Connect encoders & decoders by default
+            # Overrule the encoder connection during alignment
+            self.tx.txdata.eq(Cat(self.encoder.output[0], self.encoder.output[1])),
+            decoders[0].raw_input.eq(self.rx.rxdata[:10]),
+            decoders[1].raw_input.eq(self.rx.rxdata[10:]),
+
+            # Start decoder after delay_done is set
+            decoders[0].start.eq(self.rx.delay_done),
+            decoders[1].start.eq(self.rx.delay_done),
+        ]
+
+        rx_fsm = FSM(reset_state="WAIT_ALIGN_DELAY")
+        self.submodules += rx_fsm
+
+        log_buffer = SyncFIFO(20, 128)
+        self.submodules += log_buffer
+
+        rx_fsm.act("WAIT_ALIGN_DELAY",
+            If(self.rx.align_done & log_buffer.writable,
+                log_buffer.we.eq(1),
+                log_buffer.din.eq(self.rx.rxdata),
+            ),
+            If(~log_buffer.writable,
+                NextState("DUMP_LOG_UPPER"),
+            ),
+            If(self.rx.delay_done,
+                NextState("LOG_TRAFFIC"),
+            ),
+        )
+
+        rx_fsm.act("LOG_TRAFFIC",
+            If(log_buffer.writable,
+                log_buffer.we.eq(1),
+                log_buffer.din[0:8].eq(decoders[0].d),
+                log_buffer.din[10:18].eq(decoders[1].d),
+                # log_buffer.din.eq(self.rx.rxdata),
+            ).Else(
+                NextState("DUMP_LOG_UPPER"),
+            ),
+        )
+
+        rx_fsm.act("DUMP_LOG_UPPER",
+            If(log_buffer.readable,
+                If(self.tx_fifo.writable,
+                    self.tx_fifo.we.eq(1),
+                    self.tx_fifo.din.eq(log_buffer.dout[18:20]),
+                    NextState("DUMP_LOG_LOWER"),
+                ),
+            ).Else(
+                NextState("TERMINATE")
+            ),
+        )
+
+        rx_fsm.act("DUMP_LOG_LOWER",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(log_buffer.dout[10:18]),
+                # log_buffer.re.eq(1),
+                NextState("DUMP_LOG_UPPER_SECOND"),
+            ),
+        )
+
+        rx_fsm.act("DUMP_LOG_UPPER_SECOND",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(log_buffer.dout[8:10]),
+                NextState("DUMP_LOG_LOWER_SECOND"),
+            ),
+        )
+
+        rx_fsm.act("DUMP_LOG_LOWER_SECOND",
+            If(self.tx_fifo.writable,
+                self.tx_fifo.we.eq(1),
+                self.tx_fifo.din.eq(log_buffer.dout[:8]),
+                log_buffer.re.eq(1),
+                NextState("DUMP_LOG_UPPER"),
+            ),
+        )
+
+        rx_fsm.act("TERMINATE",
+            NextState("TERMINATE"),
+        )
+
+        tx_fsm = FSM(reset_state="WAIT_RX_INTRA_ALIGN")
+        self.submodules += tx_fsm
+
+        tx_fsm.act("WAIT_RX_INTRA_ALIGN",
+            # Note: (Redundant) Only send something when aligned
+            self.tx.txdata.eq(0),
+            If(self.rx.align_done,
+                NextState("SEND_INTRA_ALIGN_IDENT"),
+            ),
+        )
+
+        # Master receiver is not aligned yet
+        # We need to account for the possibility of group delay
+        # and SERDES misalignment
+        # 4 cycles of full 1s seems sufficiently detectable
+        ident_timer = Signal(2)
+
+        tx_fsm.act("SEND_INTRA_ALIGN_IDENT",
+            self.tx.txdata.eq(0b11111111111111111111),
+            If(ident_timer == 0b11,
+                NextValue(ident_timer, 0),
+                NextState("WAIT_RX_GROUP_ALIGN"),
+            ).Else(
+                NextValue(ident_timer, ident_timer + 1)
+            ),
+        )
+
+        tx_fsm.act("WAIT_RX_GROUP_ALIGN",
+            self.tx.txdata.eq(0),
+            If(self.rx.delay_done,
+                NextState("SEND_RX_DELAY_IDENT"),
+            ),
+        )
+
+        tx_fsm.act("SEND_RX_DELAY_IDENT",
+            self.tx.txdata.eq(0b11111111111111111111),
+            If(ident_timer == 0b11,
+                NextValue(ident_timer, 0),
+                NextState("TERMINATE"),
+            ).Else(
+                NextValue(ident_timer, ident_timer + 1)
+            ),
+        )
+
+        tx_fsm.act("TERMINATE",
+            # TODO: Release the TX serdes to the encoders
+            self.tx.txdata.eq(0),
+            NextState("TERMINATE"),
+        )
+
+
+if __name__ == "__main__":
+    import argparse
+    import functools
+    import os
+
+    parser = argparse.ArgumentParser()
+    parser.add_argument("platform")
+    parser.add_argument("variant")
+    args = parser.parse_args()
+
+    platform_dict = {
+        "kasli": kasli.Platform(hw_rev="v2.0"),
+        "efc": efc.Platform(),
+    }
+
+    sysclk_name = {
+        "kasli": "clk125_gtp",
+        "efc": "gtp_clk",
+    }
+
+    platform = platform_dict[args.platform]
+    
+    # Generate pads for the I/O blocks
+    for eem in range(2):
+        generate_pads(platform, eem)
+    data_eem = 0
+    clk_eem = 1
+
+    clk_pad = platform.request("dio{}".format(clk_eem), 0)
+
+    # Manage clock source
+    if args.variant == "master":
+        sysclk = platform.request(sysclk_name[args.platform])
+        # Fan out clock through EEM1 pair 0
+        # clkout = ClockOut(clk_pad)
+    elif args.variant == "satellite":
+        # Receive clock from EEM1 pair 0
+        sysclk = clk_pad
+
+    if args.variant == "master": 
+        i_pads = [
+            platform.request("dio{}".format(data_eem), i) for i in range(4)
+        ]
+        o_pads = [
+            platform.request("dio{}".format(data_eem), i+4) for i in range(4)
+        ]
+    elif args.variant == "satellite":
+        i_pads = [
+            platform.request("dio{}".format(data_eem), i) for i in range(4)
+        ]
+        o_pads = [
+            platform.request("dio{}".format(data_eem), i+4) for i in range(4)
+        ]
+    else:
+        raise ValueError("variant {} not implemented".format(args.variant))
+
+    crg = TransceiverCRG(platform, sysclk, gte=(args.variant == "master"))
+
+    variant = {
+        "master": functools.partial(Master, i_pads, o_pads),
+        "satellite": functools.partial(Satellite, i_pads, o_pads, crg.sys_clk_freq),
+    }
+    module_cls = variant[args.variant]
+
+    top = module_cls()
+    
+    # Wire up UART core to the pads
+    if args.variant == "satellite":
+        uart_pads = platform.request("serial")
+        top.comb += [
+            top.uart_rx.eq(uart_pads.rx),
+            uart_pads.tx.eq(top.uart_tx),
+        ]
+
+    top.submodules += crg
+    # if args.variant == "master":
+    #     top.submodules += clkout
+    #     top.comb += clkout.clk.eq(top.sysclk)
+
+    output_dir = "{}_{}_build".format(args.platform, args.variant)
+    platform.build(top, build_dir=output_dir)

short_pulse_tx.py

@@ -0,0 +1,50 @@
+from migen import *
+from migen.build.platforms.sinara import kasli, efc
+from sync_serdes import MultiLineTX
+from bidirectionalIO import BiDirectionalIO
+from eem_helpers import generate_pads
+from kasli_crg import TransceiverCRG
+
+
+class ShortPulseTX(Module):
+    def __init__(self, i_pads, o_pads):
+        # TX serdes
+        self.submodules.tx = MultiLineTX()
+        # TX PHY
+        self.submodules.channel = BiDirectionalIO(i_pads, o_pads)
+
+        self.comb += [
+            # Transmitter to SERDES
+            self.channel.i.eq(self.tx.ser_out),
+            self.channel.t.eq(self.tx.t_out),
+
+            # # SERDES to receiver
+            # self.rx.ser_in_no_dly.eq(self.channel.o),
+
+            # Hardwire TX with 1 pulse signal
+            self.tx.txdata.eq(0b00000000000000010000)
+        ]
+
+
+if __name__ == "__main__":
+    platform = efc.Platform()
+    
+    # Generate pads for the I/O blocks
+    for eem in range(2):
+        generate_pads(platform, eem)
+    data_eem = 0
+
+    i_pads = [
+        platform.request("dio{}".format(data_eem), i) for i in range(4)
+    ]
+    o_pads = [
+        platform.request("dio{}".format(data_eem), i+4) for i in range(4)
+    ]
+
+    crg = TransceiverCRG(platform, platform.request("gtp_clk"))
+    top = ShortPulseTX(i_pads, o_pads)
+
+    top.submodules += crg
+
+    output_dir = "{}_{}_build".format("efc", "master")
+    platform.build(top, build_dir=output_dir)

single_serdes_loopback.py

@@ -1,9 +1,9 @@
 from migen import *
 from sync_serdes import *
 from migen.genlib.fifo import SyncFIFO
-from migen.build.platforms.sinara import kasli
+from migen.build.platforms.sinara import kasli, efc
 from migen.genlib.misc import WaitTimer
-from kasli_crg import KasliCRG
+from kasli_crg import TransceiverCRG
 from eem_helpers import generate_pads
 from uart import UART
 from io_loopback import SingleIOLoopback
@@ -82,11 +82,6 @@ class SingleSerDesLoopBack(Module):
         # Debugging logics
         if debug:
             self.comb += [
-                # Start the reader initially
-                self.bitslip_reader.start.eq(1),
-                self.post_align_reader.start.eq(0),
-                self.phase_reader.start.eq(0),
-
                 self.bitslip_reader.loopback_rxdata.eq(self.rx.rxdata),
                 self.post_align_reader.loopback_rxdata.eq(self.rx.rxdata),
                 self.phase_reader.loopback_rxdata.eq(self.rx.rxdata),
@@ -212,7 +207,9 @@ class SingleSerDesLoopBack(Module):
             self.submodules += fsm
 
             fsm.act("WAIT_DONE",
+                self.bitslip_reader.start.eq(1),
                 If(self.bitslip_reader.done,
+                    NextValue(bitslip_count, 0),
                     NextState("WRITE_UPPER"),
                 ),
             )
@@ -229,10 +226,12 @@ class SingleSerDesLoopBack(Module):
             )
 
             fsm.act("WRITE_LOWER",
-                self.tx_fifo.we.eq(1),
-                self.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][:8]),
-                NextValue(bitslip_count, bitslip_count + 1),
-                NextState("WRITE_UPPER"),
+                If(self.tx_fifo.writable,
+                    self.tx_fifo.we.eq(1),
+                    self.tx_fifo.din.eq(self.bitslip_reader.data_result[bitslip_count][:8]),
+                    NextValue(bitslip_count, bitslip_count + 1),
+                    NextState("WRITE_UPPER"),
+                )
             )
 
             fsm.act("START_SLAVE_ALIGNER",
@@ -373,6 +372,12 @@ class SingleSerDesLoopBack(Module):
                 If(self.tx_fifo.writable,
                     self.tx_fifo.we.eq(1),
                     self.tx_fifo.din.eq(self.delay_solver.opt_delay_tap),
+                    NextState("WAIT_OPT_DELAY_ACTIVE"),
+                ),
+            )
+
+            fsm.act("WAIT_OPT_DELAY_ACTIVE",
+                If(self.rx.cnt_out == self.delay_solver.opt_delay_tap,
                     NextState("RESAMPLE_RXDATA_UPPER"),
                 ),
             )
@@ -465,18 +470,16 @@ class SingleSerDesLoopBack(Module):
 
 
 if __name__ == "__main__":
-    platform = kasli.Platform(hw_rev="v2.0")
+    # platform = kasli.Platform(hw_rev="v2.0")
+    platform = efc.Platform()
 
     # Generate pads for the I/O blocks
-    eem = 3
+    eem = 1
     generate_pads(platform, eem)
-    # pads = [
-    #     platform.request("dio{}".format(eem), i) for i in range(4)
-    # ]
     pad = platform.request("dio{}".format(eem), 0)
 
-    crg = KasliCRG(platform)
-    top = SingleSerDesLoopBack(pad, crg.sys_clk_freq, False)
+    crg = TransceiverCRG(platform, platform.request("gtp_clk"))
+    top = SingleSerDesLoopBack(pad, crg.sys_clk_freq, True)
 
     # Wire up UART core to the pads
     uart_pads = platform.request("serial")

sync_serdes.py

@@ -1,5 +1,6 @@
 from migen import *
 from migen.genlib.misc import WaitTimer
+from migen.genlib.fifo import SyncFIFO
 from util import PriorityEncoderMSB
 
 
@@ -36,7 +37,6 @@ class SingleLineRX(Module):
         self.ce = Signal()
         self.cnt_in = Signal(5)
         self.cnt_out = Signal(5)
-        self.opt_delay = Signal(5)
         self.master_bitslip = Signal()
         self.slave_bitslip = Signal()
 
@@ -207,9 +207,8 @@ class SlaveAligner(Module):
         self.done = Signal()
         self.master_bitslip = Signal()
         self.slave_bitslip = Signal()
-        # self.data_result = Array(Signal(10) for _ in range(5))
 
-        self.slip_count = Signal(3)
+        slip_count = Signal(3)
 
         check_odd = Signal()
         check_even = Signal()
@@ -220,8 +219,6 @@ class SlaveAligner(Module):
         fsm.act("WAIT_START",
             If(self.start,
                 NextState("WAIT_TIMER"),
-            ).Else(
-                NextState("WAIT_START"),
             )
         )
 
@@ -244,7 +241,7 @@ class SlaveAligner(Module):
                 NextValue(check_even, self.loopback_rxdata[0]),
                 NextState("CHECK_MASTER_BITSLIP"),
             ).Else(
-                NextValue(self.slip_count, self.slip_count + 1),
+                NextValue(slip_count, slip_count + 1),
                 NextState("HIGH_BITSLIP_FIRST"),
             )
         )
@@ -266,7 +263,7 @@ class SlaveAligner(Module):
         fsm.act("HIGH_BITSLIP_SECOND",
             self.master_bitslip.eq(1),
             self.slave_bitslip.eq(1),
-            If(self.slip_count == 5,
+            If(slip_count == 5,
                 NextState("SHIFT_WAIT_TIMER"),
             ).Else(
                 NextState("WAIT_TIMER"),
@@ -314,7 +311,7 @@ class SlaveAligner(Module):
         # After eliminating the potentially duplicating pattern,
         # Shift the entire output pattern for delay tap optimization
         # Ideally, the optimized first edge would be the middle pair
-        # So, shift it until bit 4/5 is set and bit 6 is not set
+        # So, shift it until bit 3/4 is set but bit 5 is not set
         fsm.act("SHIFT_WAIT_TIMER",
             self.stab_timer.wait.eq(1),
             If(self.stab_timer.done,
@@ -323,7 +320,7 @@ class SlaveAligner(Module):
         )
 
         fsm.act("SHIFT_SAMPLE_PATTERN",
-            If((self.loopback_rxdata[4:6] != 0) & ~self.loopback_rxdata[6],
+            If((self.loopback_rxdata[3:5] != 0) & ~self.loopback_rxdata[5],
                 NextState("TERMINATE"),
             ).Else(
                 NextState("SHIFT_HIGH_BITSLIP_FIRST"),
@@ -552,7 +549,13 @@ class DelayOptimizer(Module):
         fsm.act("LOAD_OPT_DELAY",
             self.ld.eq(1),
             # The optimal delay tap is prepared in the SAMPLE_PULSE_OUT state
-            NextState("TERMINATE"),
+            NextState("WAIT_DELAY_LOAD"),
+        )
+
+        fsm.act("WAIT_DELAY_LOAD",
+            If(self.delay_tap == self.opt_delay_tap,
+                NextState("TERMINATE"),
+            ),
         )
 
         fsm.act("TERMINATE",
@@ -560,3 +563,201 @@ class DelayOptimizer(Module):
             self.select_odd.eq(self.expected_pulse[0]),
             NextState("TERMINATE"),
         )
+
+
+class SyncSingleRX(Module):
+    def __init__(self):
+        # Ports
+        # IN: Undelayed serial signal
+        self.ser_in_no_dly = Signal()
+        # IN: Start RX alignment signal
+        self.start = Signal()
+        # OUT: Received data after self-alignment, decimation
+        self.rxdata = Signal(5)
+        # OUT: RXDATA from this channel is self-aligned
+        self.align_done = Signal()
+
+        # Components
+        self.submodules.rx = SingleLineRX()
+        self.submodules.slave_aligner = SlaveAligner()
+        self.submodules.delay_solver = DelayOptimizer()
+
+        # Sample decimation
+        select_odd = Signal()
+        decimated_rxdata = Signal(5)
+
+        # Dataflow
+        self.comb += [
+            # Delay and oversample the original signal
+            self.rx.ser_in_no_dly.eq(self.ser_in_no_dly),
+
+            # Use the deserialized signals for alignment
+            self.slave_aligner.loopback_rxdata.eq(self.rx.rxdata),
+            self.delay_solver.loopback_rxdata.eq(self.rx.rxdata),
+
+            # Decimate the oversampled signals
+            If(select_odd,
+                decimated_rxdata.eq(self.rx.rxdata[1::2]),
+            ).Else(
+                decimated_rxdata.eq(self.rx.rxdata[::2]),
+            ),
+
+            # Send it to the output
+            self.rxdata.eq(decimated_rxdata),
+        ]
+
+        # Control signals
+        self.comb += [
+            # Bitslip alignment
+            self.rx.master_bitslip.eq(self.slave_aligner.master_bitslip),
+            self.rx.slave_bitslip.eq(self.slave_aligner.slave_bitslip),
+
+            # Tap delay optimization
+            self.rx.ce.eq(self.delay_solver.inc_en),
+            self.rx.ld.eq(self.delay_solver.ld),
+            self.rx.cnt_in.eq(self.delay_solver.opt_delay_tap),
+            self.delay_solver.delay_tap.eq(self.rx.cnt_out),
+        ]
+
+        self.submodules.fsm = FSM(reset_state="WAIT_SIGNAL")
+
+        self.fsm.act("WAIT_SIGNAL",
+            If((self.rx.rxdata != 0) & self.start,
+                NextState("WAIT_ALIGNER")
+            ),
+        )
+
+        self.fsm.act("WAIT_ALIGNER",
+            self.slave_aligner.start.eq(1),
+            If(self.slave_aligner.done,
+                NextState("WAIT_DELAY_OPT"),
+            ),
+        )
+
+        self.fsm.act("WAIT_DELAY_OPT",
+            self.delay_solver.start.eq(1),
+            If(self.delay_solver.done,
+                NextValue(select_odd, self.delay_solver.select_odd),
+                NextState("INTRA_ALIGN_DONE"),
+            ),
+        )
+
+        self.fsm.act("INTRA_ALIGN_DONE",
+            self.align_done.eq(1),
+            NextState("INTRA_ALIGN_DONE"),
+        )
+
+
+class MultiLineTX(Module):
+    def __init__(self):
+        # Ports
+        # IN: Unserialized data
+        self.txdata = Signal(20)
+        # OUT: Serialized data
+        self.ser_out = Signal(4)
+        # OUT: 3-state signal output
+        self.t_out = Signal(4)
+
+        for idx in range(4):
+            single_tx = SingleLineTX()
+
+            self.comb += [
+                self.ser_out[idx].eq(single_tx.ser_out),
+                self.t_out[idx].eq(single_tx.t_out),
+                single_tx.txdata.eq(self.txdata[5*idx:5*(idx+1)]),
+            ]
+
+            self.submodules += single_tx
+
+
+class MultiLineRX(Module):
+    def __init__(self):
+        # Ports
+        # IN: Undelayed serial signal
+        self.ser_in_no_dly = Signal(4)
+        # IN: Start alignment process of all channels
+        self.start = Signal()
+        # OUT: Received data after self-alignment, decimation
+        self.rxdata = Signal(20)
+        # OUT: RXDATA from all channels are self-aligned
+        self.align_done = Signal()
+        # OUT: Group delay compensated
+        self.delay_done = Signal()
+        # OUT: Group delay adjustment failed
+        self.err = Signal()
+
+        channel_align_done = Signal(4)
+        self.comb += self.align_done.eq(channel_align_done == 0b1111)
+
+        buffer_outflow = Signal(4)
+        self.comb += buffer_outflow.eq(0b1111)
+
+        for idx in range(4):
+            single_rx = SyncSingleRX()
+
+            self.comb += [
+                single_rx.ser_in_no_dly.eq(self.ser_in_no_dly[idx]),
+                channel_align_done[idx].eq(single_rx.align_done),
+                # Propagate start alignment signal to all channels
+                single_rx.start.eq(self.start),
+            ]
+        
+            # FIFOs for handling group delay
+            # Signal from each OSERDES group can have a different delay
+            # So, add delay to the groups that receives the pulse early
+            # Maximum delay = 8
+            channel_buffer = SyncFIFO(5, 16)
+
+            self.comb += [
+                # Allow data go through the FIFO unless aligning
+                # Pay the memory delay cost
+                channel_buffer.we.eq(1),
+                channel_buffer.re.eq(buffer_outflow[idx]),
+
+                # Data always flow from individual RX to the rxdata port
+                channel_buffer.din.eq(single_rx.rxdata),
+                self.rxdata[5*idx:5*(idx+1)].eq(channel_buffer.dout),
+            ]
+
+            # If at any point the FIFO fills up,
+            # group delay can no longer be determined and compensated
+            self.sync += [
+                If(~channel_buffer.writable,
+                    self.err.eq(1),
+                ),
+            ]
+
+            self.submodules += [ single_rx, channel_buffer ]
+
+        self.submodules.fsm = FSM(reset_state="WAIT_ALIGN_DONE")
+
+        self.fsm.act("WAIT_ALIGN_DONE",
+            If(self.align_done,
+                NextState("WAIT_ZERO"),
+            ),
+        )
+
+        self.fsm.act("WAIT_ZERO",
+            If(self.rxdata == 0,
+                NextState("WAIT_PULSE"),
+            ),
+        )
+
+        self.fsm.act("WAIT_PULSE",
+            # Control outflow until all channels finds the pulse
+            If(self.rxdata == 0b11111111111111111111,
+                buffer_outflow.eq(0b1111),
+                self.delay_done.eq(1),
+                NextState("GROUP_DELAY_DONE"),
+            ).Else(
+                buffer_outflow[0].eq(self.rxdata[ 0: 5] == 0),
+                buffer_outflow[1].eq(self.rxdata[ 5:10] == 0),
+                buffer_outflow[2].eq(self.rxdata[10:15] == 0),
+                buffer_outflow[3].eq(self.rxdata[15:20] == 0),
+            ),
+        )
+
+        self.fsm.act("GROUP_DELAY_DONE",
+            self.delay_done.eq(1),
+            NextState("GROUP_DELAY_DONE"),
+        )

test_coder.py

@@ -0,0 +1,103 @@
+from migen import *
+from multi_coders import MultiEncoder, CrossbarDecoder
+
+
+class IdentityCoders(Module):
+    def __init__(self):
+        self.submodules.encoder = MultiEncoder(lsb_first=False)
+        decoders = [ CrossbarDecoder(lsb_first=False) for _ in range(2) ]
+        self.submodules += decoders
+
+        # Interface fo input/output
+        self.d_in = [ Signal(8) for _ in range(2) ]
+        self.k_in = [ Signal() for _ in range(2) ]
+        self.d_out = [ Signal(8) for _ in range(2) ]
+        self.k_out = [ Signal() for _ in range(2) ]
+
+        # Signal to start both encoders & decoders
+        self.encoder_start = Signal()
+        self.decoder_start = Signal()
+        self.comb += self.encoder.start.eq(self.encoder_start)
+        for decoder in decoders:
+            self.comb += decoder.start.eq(self.decoder_start)
+
+        # Interconnect encoders and decoders
+        for encoder_output, decoder in zip(self.encoder.output, decoders):
+            self.sync += decoder.raw_input.eq(encoder_output)
+        
+        for d_in, k_in, encoder_d, encoder_k in \
+                zip(self.d_in, self.k_in, self.encoder.d, self.encoder.k):
+            self.comb += [
+                # Connect symbols to encoder
+                encoder_d.eq(d_in),
+                encoder_k.eq(k_in),
+            ]
+
+        # Connect symbols from decoder
+        for d_out, k_out, decoder in zip(self.d_out, self.k_out, decoders):
+            self.comb += [
+                d_out.eq(decoder.d),
+                k_out.eq(decoder.k),
+            ]
+
+
+import random
+
+
+def testbench(dut, transmission_delay=1):
+    data_size = 256
+    list_of_data = [
+        (random.randint(0, 0xFF), random.getrandbits(1)) \
+            for _ in range(data_size)
+    ]
+    # Control characters
+    controls = [
+        0x1C, 0x3C, 0x5C, 0x7C, 0x9C, 0xBC, 0xDC, 0xFC,
+        0xF7, 0xFB, 0xFD, 0xFE
+    ]
+
+    # Correct control symbols
+    for idx, (data, control) in enumerate(list_of_data):
+        if control:
+            list_of_data[idx] = (controls[random.randint(0, len(controls) - 1)], 1)
+    # Decoder, Encoder, and the channel all introduces delay
+    delay_list = [ None ] * 5
+
+    send_list = list_of_data + delay_list
+    recv_list = delay_list + list_of_data
+
+    yield dut.encoder_start.eq(1)
+    # Skip exactly 1 cycle. The channel has 1 cycle delay.
+    yield
+    yield dut.decoder_start.eq(1)
+
+    for _ in range(transmission_delay):
+        yield
+
+    for data_in, data_out in zip(send_list, recv_list):
+        if data_in is not None:
+            d_in, k_in = data_in
+            yield dut.d_in[0].eq(d_in)
+            yield dut.d_in[1].eq(d_in)
+            yield dut.k_in[0].eq(k_in)
+            yield dut.k_in[1].eq(k_in)
+        else:
+            yield dut.d_in[0].eq(0)
+            yield dut.d_in[1].eq(0)
+            yield dut.k_in[0].eq(0)
+            yield dut.k_in[1].eq(0)
+        
+        if data_out is not None:
+            d_out, k_out = data_out
+            assert (yield dut.d_out[0]) == d_out
+            assert (yield dut.d_out[1]) == d_out
+            assert (yield dut.k_out[0]) == k_out
+            assert (yield dut.k_out[1]) == k_out
+        yield
+    
+    for _ in range(10):
+        yield
+
+for delay in range(16):
+    dut = IdentityCoders()
+    run_simulation(dut, testbench(dut, delay), vcd_name="coders.vcd")

uart_log.py

@@ -0,0 +1,25 @@
+from migen import *
+from migen.genlib.fifo import SyncFIFO
+from uart import UART
+
+
+class UARTLogger(Module):
+    def __init__(self, sys_clk_freq):
+        # UART PHY interface
+        self.uart_rx = Signal()
+        self.uart_tx = Signal()
+
+        # Attach FIFO to UART TX, send rate is too slow w.r.t sysclk
+        self.submodules.tx_fifo = SyncFIFO(8, 64)
+
+        self.submodules.uart = UART(round((115200/sys_clk_freq)*2**32))
+        self.comb += [
+            # PHY connection
+            self.uart.phy_rx.eq(self.uart_rx),
+            self.uart_tx.eq(self.uart.phy_tx),
+
+            # UART TX path
+            self.uart.tx_data.eq(self.tx_fifo.dout),
+            self.uart.tx_stb.eq(self.tx_fifo.readable),
+            self.tx_fifo.re.eq(self.uart.tx_ack),
+        ]