vendor.xilinx_ultrascale: new supported family.
authorwhitequark <whitequark@whitequark.org>
Thu, 10 Oct 2019 16:35:48 +0000 (16:35 +0000)
committerwhitequark <whitequark@whitequark.org>
Thu, 10 Oct 2019 16:35:48 +0000 (16:35 +0000)
README.md
nmigen/vendor/xilinx_ultrascale.py [new file with mode: 0644]

index c0a532c1c6d11357761128e2b8611e9a48a210d5..0032e3c635a83f88f9bee54b1ec36201330b2fe7 100644 (file)
--- a/README.md
+++ b/README.md
@@ -47,6 +47,7 @@ nMigen can be used to target any FPGA or ASIC process that accepts behavioral Ve
   * Xilinx Spartan 3A (toolchains: ISE);
   * Xilinx Spartan 6 (toolchains: ISE);
   * Xilinx 7-series (toolchains: Vivado);
+  * Xilinx UltraScale (toolchains: Vivado);
   * Intel (toolchains: Quartus).
 
 FOSS toolchains are listed in **bold**.
diff --git a/nmigen/vendor/xilinx_ultrascale.py b/nmigen/vendor/xilinx_ultrascale.py
new file mode 100644 (file)
index 0000000..a4dd1fd
--- /dev/null
@@ -0,0 +1,422 @@
+from abc import abstractproperty
+
+from ..hdl import *
+from ..lib.cdc import ResetSynchronizer
+from ..build import *
+
+
+__all__ = ["XilinxUltraScalePlatform"]
+
+
+class XilinxUltraScalePlatform(TemplatedPlatform):
+    """
+    Required tools:
+        * ``vivado``
+
+    The environment is populated by running the script specified in the environment variable
+    ``NMIGEN_ENV_Vivado``, if present.
+
+    Available overrides:
+        * ``script_after_read``: inserts commands after ``read_xdc`` in Tcl script.
+        * ``script_after_synth``: inserts commands after ``synth_design`` in Tcl script.
+        * ``script_after_place``: inserts commands after ``place_design`` in Tcl script.
+        * ``script_after_route``: inserts commands after ``route_design`` in Tcl script.
+        * ``script_before_bitstream``: inserts commands before ``write_bitstream`` in Tcl script.
+        * ``script_after_bitstream``: inserts commands after ``write_bitstream`` in Tcl script.
+        * ``add_constraints``: inserts commands in XDC file.
+        * ``vivado_opts``: adds extra options for ``vivado``.
+
+    Build products:
+        * ``{{name}}.log``: Vivado log.
+        * ``{{name}}_timing_synth.rpt``: Vivado report.
+        * ``{{name}}_utilization_hierarchical_synth.rpt``: Vivado report.
+        * ``{{name}}_utilization_synth.rpt``: Vivado report.
+        * ``{{name}}_utilization_hierarchical_place.rpt``: Vivado report.
+        * ``{{name}}_utilization_place.rpt``: Vivado report.
+        * ``{{name}}_io.rpt``: Vivado report.
+        * ``{{name}}_control_sets.rpt``: Vivado report.
+        * ``{{name}}_clock_utilization.rpt``:  Vivado report.
+        * ``{{name}}_route_status.rpt``: Vivado report.
+        * ``{{name}}_drc.rpt``: Vivado report.
+        * ``{{name}}_timing.rpt``: Vivado report.
+        * ``{{name}}_power.rpt``: Vivado report.
+        * ``{{name}}_route.dcp``: Vivado design checkpoint.
+        * ``{{name}}.bit``: binary bitstream with metadata.
+        * ``{{name}}.bin``: binary bitstream.
+    """
+
+    toolchain = "Vivado"
+
+    device  = abstractproperty()
+    package = abstractproperty()
+    speed   = abstractproperty()
+    grade   = None
+
+    required_tools = [
+        "yosys",
+        "vivado"
+    ]
+    file_templates = {
+        **TemplatedPlatform.build_script_templates,
+        "build_{{name}}.sh": r"""
+            # {{autogenerated}}
+            set -e{{verbose("x")}}
+            if [ -z "$BASH" ] ; then exec /bin/bash "$0" "$@"; fi
+            [ -n "${{platform._toolchain_env_var}}" ] && . "${{platform._toolchain_env_var}}"
+            {{emit_commands("sh")}}
+        """,
+        "{{name}}.v": r"""
+            /* {{autogenerated}} */
+            {{emit_verilog()}}
+        """,
+        "{{name}}.debug.v": r"""
+            /* {{autogenerated}} */
+            {{emit_debug_verilog()}}
+        """,
+        "{{name}}.tcl": r"""
+            # {{autogenerated}}
+            create_project -force -name {{name}} -part {{platform.device}}-{{platform.package}}-{{platform.speed}}{{"-" + platform.grade if platform.grade else ""}}
+            {% for file in platform.iter_extra_files(".v", ".sv", ".vhd", ".vhdl") -%}
+                add_files {{file}}
+            {% endfor %}
+            add_files {{name}}.v
+            read_xdc {{name}}.xdc
+            {% for file in platform.iter_extra_files(".xdc") -%}
+                read_xdc {{file}}
+            {% endfor %}
+            {{get_override("script_after_read")|default("# (script_after_read placeholder)")}}
+            synth_design -top {{name}}
+            foreach cell [get_cells -quiet -hier -filter {nmigen.vivado.false_path == "TRUE"}] {
+                set_false_path -to $cell
+            }
+            foreach cell [get_cells -quiet -hier -filter {nmigen.vivado.max_delay != ""}] {
+                set clock [get_clocks -of_objects \
+                    [all_fanin -flat -startpoints_only [get_pin $cell/D]]]
+                if {[llength $clock] != 0} {
+                    set_max_delay -datapath_only -from $clock \
+                        -to [get_cells $cell] [get_property nmigen.vivado.max_delay $cell]
+                }
+            }
+            {{get_override("script_after_synth")|default("# (script_after_synth placeholder)")}}
+            report_timing_summary -file {{name}}_timing_synth.rpt
+            report_utilization -hierarchical -file {{name}}_utilization_hierachical_synth.rpt
+            report_utilization -file {{name}}_utilization_synth.rpt
+            opt_design
+            place_design
+            {{get_override("script_after_place")|default("# (script_after_place placeholder)")}}
+            report_utilization -hierarchical -file {{name}}_utilization_hierarchical_place.rpt
+            report_utilization -file {{name}}_utilization_place.rpt
+            report_io -file {{name}}_io.rpt
+            report_control_sets -verbose -file {{name}}_control_sets.rpt
+            report_clock_utilization -file {{name}}_clock_utilization.rpt
+            route_design
+            {{get_override("script_after_route")|default("# (script_after_route placeholder)")}}
+            phys_opt_design
+            report_timing_summary -no_header -no_detailed_paths
+            write_checkpoint -force {{name}}_route.dcp
+            report_route_status -file {{name}}_route_status.rpt
+            report_drc -file {{name}}_drc.rpt
+            report_timing_summary -datasheet -max_paths 10 -file {{name}}_timing.rpt
+            report_power -file {{name}}_power.rpt
+            {{get_override("script_before_bitstream")|default("# (script_before_bitstream placeholder)")}}
+            write_bitstream -force -bin_file {{name}}.bit
+            {{get_override("script_after_bitstream")|default("# (script_after_bitstream placeholder)")}}
+            quit
+        """,
+        "{{name}}.xdc": r"""
+            # {{autogenerated}}
+            {% for port_name, pin_name, attrs in platform.iter_port_constraints_bits() -%}
+                set_property LOC {{pin_name}} [get_ports {{port_name}}]
+                {% for attr_name, attr_value in attrs.items() -%}
+                    set_property {{attr_name}} {{attr_value}} [get_ports {{port_name}}]
+                {% endfor %}
+            {% endfor %}
+            {% for signal, frequency in platform.iter_clock_constraints() -%}
+                create_clock -name {{signal.name}} -period {{1000000000/frequency}} [get_nets {{signal|hierarchy("/")}}]
+            {% endfor %}
+            {{get_override("add_constraints")|default("# (add_constraints placeholder)")}}
+        """
+    }
+    command_templates = [
+        r"""
+        {{get_tool("vivado")}}
+            {{verbose("-verbose")}}
+            {{get_override("vivado_opts")|options}}
+            -mode batch
+            -log {{name}}.log
+            -source {{name}}.tcl
+        """
+    ]
+
+    def create_missing_domain(self, name):
+        # Xilinx devices have a global write enable (GWE) signal that asserted during configuraiton
+        # and deasserted once it ends. Because it is an asynchronous signal (GWE is driven by logic
+        # syncronous to configuration clock, which is not used by most designs), even though it is
+        # a low-skew global network, its deassertion may violate a setup/hold constraint with
+        # relation to a user clock. The recommended solution is to use a BUFGCE driven by the EOS
+        # signal. For details, see:
+        #   * https://www.xilinx.com/support/answers/44174.html
+        #   * https://www.xilinx.com/support/documentation/white_papers/wp272.pdf
+        if name == "sync" and self.default_clk is not None:
+            clk_i = self.request(self.default_clk).i
+            if self.default_rst is not None:
+                rst_i = self.request(self.default_rst).i
+
+            m = Module()
+            ready = Signal()
+            m.submodules += Instance("STARTUPE3", o_EOS=ready)
+            m.domains += ClockDomain("sync", reset_less=self.default_rst is None)
+            m.submodules += Instance("BUFGCE", i_CE=ready, i_I=clk_i, o_O=ClockSignal("sync"))
+            if self.default_rst is not None:
+                m.submodules.reset_sync = ResetSynchronizer(rst_i, domain="sync")
+            return m
+
+    def _get_xdr_buffer(self, m, pin, *, i_invert=False, o_invert=False):
+        def get_dff(clk, d, q):
+            # SDR I/O is performed by packing a flip-flop into the pad IOB.
+            for bit in range(len(q)):
+                _q = Signal()
+                _q.attrs["IOB"] = "TRUE"
+                # Vivado 2019.1 seems to make this flip-flop ineligible for IOB packing unless
+                # we prevent it from being optimized.
+                _q.attrs["DONT_TOUCH"] = "TRUE"
+                m.submodules += Instance("FDCE",
+                    i_C=clk,
+                    i_CE=Const(1),
+                    i_CLR=Const(0),
+                    i_D=d[bit],
+                    o_Q=_q
+                )
+                m.d.comb += q[bit].eq(_q)
+
+        def get_iddr(clk, d, q1, q2):
+            for bit in range(len(q1)):
+                m.submodules += Instance("IDDRE1",
+                    p_DDR_CLK_EDGE="SAME_EDGE_PIPELINED",
+                    p_IS_C_INVERTED=0, p_IS_CB_INVERTED=1,
+                    i_C=clk, i_CB=clk,
+                    i_R=Const(0),
+                    i_D=d[bit],
+                    o_Q1=q1[bit], o_Q2=q2[bit]
+                )
+
+        def get_oddr(clk, d1, d2, q):
+            for bit in range(len(q)):
+                m.submodules += Instance("ODDRE1",
+                    p_DDR_CLK_EDGE="SAME_EDGE",
+                    p_INIT=0,
+                    i_C=clk,
+                    i_SR=Const(0),
+                    i_D1=d1[bit], i_D2=d2[bit],
+                    o_Q=q[bit]
+                )
+
+        def get_ineg(y, invert):
+            if invert:
+                a = Signal.like(y, name_suffix="_n")
+                m.d.comb += y.eq(~a)
+                return a
+            else:
+                return y
+
+        def get_oneg(a, invert):
+            if invert:
+                y = Signal.like(a, name_suffix="_n")
+                m.d.comb += y.eq(~a)
+                return y
+            else:
+                return a
+
+        if "i" in pin.dir:
+            if pin.xdr < 2:
+                pin_i  = get_ineg(pin.i,  i_invert)
+            elif pin.xdr == 2:
+                pin_i0 = get_ineg(pin.i0, i_invert)
+                pin_i1 = get_ineg(pin.i1, i_invert)
+        if "o" in pin.dir:
+            if pin.xdr < 2:
+                pin_o  = get_oneg(pin.o,  o_invert)
+            elif pin.xdr == 2:
+                pin_o0 = get_oneg(pin.o0, o_invert)
+                pin_o1 = get_oneg(pin.o1, o_invert)
+
+        i = o = t = None
+        if "i" in pin.dir:
+            i = Signal(pin.width, name="{}_xdr_i".format(pin.name))
+        if "o" in pin.dir:
+            o = Signal(pin.width, name="{}_xdr_o".format(pin.name))
+        if pin.dir in ("oe", "io"):
+            t = Signal(1,         name="{}_xdr_t".format(pin.name))
+
+        if pin.xdr == 0:
+            if "i" in pin.dir:
+                i = pin_i
+            if "o" in pin.dir:
+                o = pin_o
+            if pin.dir in ("oe", "io"):
+                t = ~pin.oe
+        elif pin.xdr == 1:
+            if "i" in pin.dir:
+                get_dff(pin.i_clk, i, pin_i)
+            if "o" in pin.dir:
+                get_dff(pin.o_clk, pin_o, o)
+            if pin.dir in ("oe", "io"):
+                get_dff(pin.o_clk, ~pin.oe, t)
+        elif pin.xdr == 2:
+            if "i" in pin.dir:
+                get_iddr(pin.i_clk, i, pin_i0, pin_i1)
+            if "o" in pin.dir:
+                get_oddr(pin.o_clk, pin_o0, pin_o1, o)
+            if pin.dir in ("oe", "io"):
+                get_dff(pin.o_clk, ~pin.oe, t)
+        else:
+            assert False
+
+        return (i, o, t)
+
+    def get_input(self, pin, port, attrs, invert):
+        self._check_feature("single-ended input", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, i_invert=invert)
+        for bit in range(len(port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("IBUF",
+                i_I=port[bit],
+                o_O=i[bit]
+            )
+        return m
+
+    def get_output(self, pin, port, attrs, invert):
+        self._check_feature("single-ended output", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, o_invert=invert)
+        for bit in range(len(port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("OBUF",
+                i_I=o[bit],
+                o_O=port[bit]
+            )
+        return m
+
+    def get_tristate(self, pin, port, attrs, invert):
+        self._check_feature("single-ended tristate", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, o_invert=invert)
+        for bit in range(len(port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("OBUFT",
+                i_T=t,
+                i_I=o[bit],
+                o_O=port[bit]
+            )
+        return m
+
+    def get_input_output(self, pin, port, attrs, invert):
+        self._check_feature("single-ended input/output", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, i_invert=invert, o_invert=invert)
+        for bit in range(len(port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("IOBUF",
+                i_T=t,
+                i_I=o[bit],
+                o_O=i[bit],
+                io_IO=port[bit]
+            )
+        return m
+
+    def get_diff_input(self, pin, p_port, n_port, attrs, invert):
+        self._check_feature("differential input", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, i_invert=invert)
+        for bit in range(len(p_port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("IBUFDS",
+                i_I=p_port[bit], i_IB=n_port[bit],
+                o_O=i[bit]
+            )
+        return m
+
+    def get_diff_output(self, pin, p_port, n_port, attrs, invert):
+        self._check_feature("differential output", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, o_invert=invert)
+        for bit in range(len(p_port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("OBUFDS",
+                i_I=o[bit],
+                o_O=p_port[bit], o_OB=n_port[bit]
+            )
+        return m
+
+    def get_diff_tristate(self, pin, p_port, n_port, attrs, invert):
+        self._check_feature("differential tristate", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, o_invert=invert)
+        for bit in range(len(p_port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("OBUFTDS",
+                i_T=t,
+                i_I=o[bit],
+                o_O=p_port[bit], o_OB=n_port[bit]
+            )
+        return m
+
+    def get_diff_input_output(self, pin, p_port, n_port, attrs, invert):
+        self._check_feature("differential input/output", pin, attrs,
+                            valid_xdrs=(0, 1, 2), valid_attrs=True)
+        m = Module()
+        i, o, t = self._get_xdr_buffer(m, pin, i_invert=invert, o_invert=invert)
+        for bit in range(len(p_port)):
+            m.submodules["{}_{}".format(pin.name, bit)] = Instance("IOBUFDS",
+                i_T=t,
+                i_I=o[bit],
+                o_O=i[bit],
+                io_IO=p_port[bit], io_IOB=n_port[bit]
+            )
+        return m
+
+    # The synchronizer implementations below apply two separate but related timing constraints.
+    #
+    # First, the ASYNC_REG attribute prevents inference of shift registers from synchronizer FFs,
+    # and constraints the FFs to be placed as close as possible, ideally in one CLB. This attribute
+    # only affects the synchronizer FFs themselves.
+    #
+    # Second, the nmigen.vivado.false_path or nmigen.vivado.max_delay attribute affects the path
+    # into the synchronizer. If maximum input delay is specified, a datapath-only maximum delay
+    # constraint is applied, limiting routing delay (and therefore skew) at the synchronizer input.
+    # Otherwise, a false path constraint is used to omit the input path from the timing analysis.
+
+    def get_ff_sync(self, ff_sync):
+        m = Module()
+        flops = [Signal(ff_sync.i.shape(), name="stage{}".format(index),
+                        reset=ff_sync._reset, reset_less=ff_sync._reset_less,
+                        attrs={"ASYNC_REG": "TRUE"})
+                 for index in range(ff_sync._stages)]
+        if ff_sync._max_input_delay is None:
+            flops[0].attrs["nmigen.vivado.false_path"] = "TRUE"
+        else:
+            flops[0].attrs["nmigen.vivado.max_delay"] = str(ff_sync._max_input_delay * 1e9)
+        for i, o in zip((ff_sync.i, *flops), flops):
+            m.d[ff_sync._o_domain] += o.eq(i)
+        m.d.comb += ff_sync.o.eq(flops[-1])
+        return m
+
+    def get_reset_sync(self, reset_sync):
+        m = Module()
+        m.domains += ClockDomain("reset_sync", async_reset=True, local=True)
+        flops = [Signal(1, name="stage{}".format(index), reset=1,
+                        attrs={"ASYNC_REG": "TRUE"})
+                 for index in range(reset_sync._stages)]
+        if reset_sync._max_input_delay is None:
+            flops[0].attrs["nmigen.vivado.false_path"] = "TRUE"
+        else:
+            flops[0].attrs["nmigen.vivado.max_delay"] = str(reset_sync._max_input_delay * 1e9)
+        for i, o in zip((0, *flops), flops):
+            m.d.reset_sync += o.eq(i)
+        m.d.comb += [
+            ClockSignal("reset_sync").eq(ClockSignal(reset_sync._domain)),
+            ResetSignal("reset_sync").eq(reset_sync.arst),
+            ResetSignal(reset_sync._domain).eq(flops[-1])
+        ]
+        return m