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amaranth/nmigen/vendor/xilinx_spartan_3_6.py
whitequark 53bb4300a3 build.plat: strip internal attributes from Verilog output. 
Although useful for debugging, most external tools often complain
about such attributes (with notable exception of Vivado). As such,
it is better to emit Verilog with these attributes into a separate
file such as `design.debug.v` and only emit the attributes that were
explicitly placed by the user to `design.v`.

This still leaves the (*init*) attribute. See #220 for details.
2019-09-24 14:56:00 +00:00

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from abc import abstractproperty
from ..hdl import *
from ..build import *
__all__ = ["XilinxSpartan3APlatform", "XilinxSpartan6Platform"]
# The interface to Spartan 3 and 6 are substantially the same. Handle
# differences internally using one class and expose user-aliases for
# convenience.
class XilinxSpartan3Or6Platform(TemplatedPlatform):
"""
Required tools:
* ISE toolchain:
* ``xst``
* ``ngdbuild``
* ``map``
* ``par``
* ``bitgen``
The environment is populated by running the script specified in the environment variable
``NMIGEN_ENV_ISE``, if present.
Available overrides:
* ``script_after_run``: inserts commands after ``run`` in XST script.
* ``add_constraints``: inserts commands in UCF file.
* ``xst_opts``: adds extra options for ``xst``.
* ``ngdbuild_opts``: adds extra options for ``ngdbuild``.
* ``map_opts``: adds extra options for ``map``.
* ``par_opts``: adds extra options for ``par``.
* ``bitgen_opts``: adds extra and overrides default options for ``bitgen``;
default options: ``-g Compress``.
Build products:
* ``{{name}}.srp``: synthesis report.
* ``{{name}}.ngc``: synthesized RTL.
* ``{{name}}.bld``: NGDBuild log.
* ``{{name}}.ngd``: design database.
* ``{{name}}_map.map``: MAP log.
* ``{{name}}_map.mrp``: mapping report.
* ``{{name}}_map.ncd``: mapped netlist.
* ``{{name}}.pcf``: physical constraints.
* ``{{name}}_par.par``: PAR log.
* ``{{name}}_par_pad.txt``: I/O usage report.
* ``{{name}}_par.ncd``: place and routed netlist.
* ``{{name}}.drc``: DRC report.
* ``{{name}}.bgn``: BitGen log.
* ``{{name}}.bit``: binary bitstream with metadata.
* ``{{name}}.bin``: raw binary bitstream.
"""
toolchain = "ISE"
device = abstractproperty()
package = abstractproperty()
speed = abstractproperty()
required_tools = [
"xst",
"ngdbuild",
"map",
"par",
"bitgen",
]
@property
def family(self):
device = self.device.upper()
if device.startswith("XC3S"):
if device.endswith("A"):
return "3A"
elif device.endswith("E"):
raise NotImplementedError("""Spartan 3E family is not supported
as a nMigen platform.""")
else:
raise NotImplementedError("""Spartan 3 family is not supported
as a nMigen platform.""")
elif device.startswith("XC6S"):
return "6"
else:
assert False
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}}.prj": r"""
# {{autogenerated}}
{% for file in platform.iter_extra_files(".vhd", ".vhdl") -%}
vhdl work {{file}}
{% endfor %}
{% for file in platform.iter_extra_files(".v") -%}
verilog work {{file}}
{% endfor %}
verilog work {{name}}.v
""",
"{{name}}.xst": r"""
# {{autogenerated}}
run
-ifn {{name}}.prj
-ofn {{name}}.ngc
-top {{name}}
{% if platform.family in ["3", "3E", "3A"] %}
-use_new_parser yes
{% endif %}
-p {{platform.device}}{{platform.package}}-{{platform.speed}}
{{get_override("script_after_run")|default("# (script_after_run placeholder)")}}
""",
"{{name}}.ucf": r"""
# {{autogenerated}}
{% for port_name, pin_name, attrs in platform.iter_port_constraints_bits() -%}
{% set port_name = port_name|replace("[", "<")|replace("]", ">") -%}
NET "{{port_name}}" LOC={{pin_name}};
{% for attr_name, attr_value in attrs.items() -%}
NET "{{port_name}}" {{attr_name}}={{attr_value}};
{% endfor %}
{% endfor %}
{% for signal, frequency in platform.iter_clock_constraints() -%}
NET "{{signal|hierarchy("/")}}" TNM_NET="PRD{{signal|hierarchy("/")}}";
TIMESPEC "TS{{signal|hierarchy("/")}}"=PERIOD "PRD{{signal|hierarchy("/")}}" {{1000000000/frequency}} ns HIGH 50%;
{% endfor %}
{{get_override("add_constraints")|default("# (add_constraints placeholder)")}}
"""
}
command_templates = [
r"""
{{get_tool("xst")}}
{{get_override("xst_opts")|options}}
-ifn {{name}}.xst
""",
r"""
{{get_tool("ngdbuild")}}
{{quiet("-quiet")}}
{{verbose("-verbose")}}
{{get_override("ngdbuild_opts")|options}}
-uc {{name}}.ucf
{{name}}.ngc
""",
r"""
{{get_tool("map")}}
{{verbose("-detail")}}
{{get_override("map_opts")|default([])|options}}
-w
-o {{name}}_map.ncd
{{name}}.ngd
{{name}}.pcf
""",
r"""
{{get_tool("par")}}
{{get_override("par_opts")|default([])|options}}
-w
{{name}}_map.ncd
{{name}}_par.ncd
{{name}}.pcf
""",
r"""
{{get_tool("bitgen")}}
{{get_override("bitgen_opts")|default(["-g Compress"])|options}}
-w
-g Binary:Yes
{{name}}_par.ncd
{{name}}.bit
"""
]
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 (if available). 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()
if self.family == "6":
m.submodules += Instance("STARTUP_SPARTAN6", o_EOS=ready)
else:
raise NotImplementedError("Spartan 3 devices lack an end-of-startup signal; "
"ensure the design has an appropriate reset")
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.d.comb += ResetSignal("sync").eq(rst_i)
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"
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, q0, q1):
for bit in range(len(q0)):
m.submodules += Instance("IDDR2",
p_DDR_ALIGNMENT="C0",
p_SRTYPE="ASYNC",
p_INIT_Q0=0, p_INIT_Q1=0,
i_C0=clk, i_C1=~clk,
i_CE=Const(1),
i_S=Const(0), i_R=Const(0),
i_D=d[bit],
o_Q0=q0[bit], o_Q1=q1[bit]
)
def get_oddr(clk, d0, d1, q):
for bit in range(len(q)):
m.submodules += Instance("ODDR2",
p_DDR_ALIGNMENT="C0",
p_SRTYPE="ASYNC",
p_INIT=0,
i_C0=clk, i_C1=~clk,
i_CE=Const(1),
i_S=Const(0), i_R=Const(0),
i_D0=d0[bit], i_D1=d1[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:
# Re-register first input before it enters fabric. This allows both inputs to
# enter fabric on the same clock edge, and adds one cycle of latency.
i0_ff = Signal.like(pin_i0, name_suffix="_ff")
get_dff(pin.i_clk, i0_ff, pin_i0)
get_iddr(pin.i_clk, i, i0_ff, 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 the ASYNC_REG attribute. This 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.
def get_ff_sync(self, ff_sync):
if ff_sync._max_input_delay is not None:
raise NotImplementedError("Platform '{}' does not support constraining input delay "
"for FFSynchronizer"
.format(type(self).__name__))
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)]
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):
if reset_sync._max_input_delay is not None:
raise NotImplementedError("Platform '{}' does not support constraining input delay "
"for ResetSynchronizer"
.format(type(self).__name__))
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)]
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
XilinxSpartan3APlatform = XilinxSpartan3Or6Platform
XilinxSpartan6Platform = XilinxSpartan3Or6Platform
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