Exemplo n.º 1
0
def _run_vivado(build_name, vivado_path, source, ver=None):
    if sys.platform == "win32" or sys.platform == "cygwin":
        build_script_contents = "REM Autogenerated by Migen\n"
        build_script_contents += "vivado -mode batch -source " + build_name + ".tcl\n"
        build_script_file = "build_" + build_name + ".bat"
        tools.write_to_file(build_script_file, build_script_contents)
        command = build_script_file
    else:
        build_script_contents = "# Autogenerated by Migen\nset -e\n"

        # For backwards compatibility with ISE paths, also
        # look for a version in a subdirectory named "Vivado"
        # under the current directory.
        paths_to_try = [vivado_path, os.path.join(vivado_path, "Vivado")]
        for p in paths_to_try:
            try:
                settings = common.settings(p, ver)
            except OSError:
                continue
            break
        else:
            raise OSError("Unable to locate Vivado directory or settings.")

        build_script_contents += "source " + settings + "\n"
        build_script_contents += "vivado -mode batch -source " + build_name + ".tcl\n"
        build_script_file = "build_" + build_name + ".sh"
        tools.write_to_file(build_script_file, build_script_contents)
        command = ["bash", build_script_file]
    r = tools.subprocess_call_filtered(command, common.colors)
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 2
0
    def _build_batch(self, platform, sources, build_name):
        tcl = []
        for filename, language, library in sources:
            filename_tcl = "{" + filename + "}"
            tcl.append("add_files " + filename_tcl)
            tcl.append("set_property library {} [get_files {}]"
                       .format(library, filename_tcl))

        tcl.append("read_xdc {}.xdc".format(build_name))
        tcl.extend(c.format(build_name=build_name) for c in self.pre_synthesis_commands)
        tcl.append("synth_design -top {} -part {} -include_dirs {{{}}}".format(build_name, platform.device, " ".join(platform.verilog_include_paths)))
        tcl.append("report_utilization -hierarchical -file {}_utilization_hierarchical_synth.rpt".format(build_name))
        tcl.append("report_utilization -file {}_utilization_synth.rpt".format(build_name))
        tcl.append("place_design")
        if self.with_phys_opt:
            tcl.append("phys_opt_design -directive AddRetime")
        tcl.append("report_utilization -hierarchical -file {}_utilization_hierarchical_place.rpt".format(build_name))
        tcl.append("report_utilization -file {}_utilization_place.rpt".format(build_name))
        tcl.append("report_io -file {}_io.rpt".format(build_name))
        tcl.append("report_control_sets -verbose -file {}_control_sets.rpt".format(build_name))
        tcl.append("report_clock_utilization -file {}_clock_utilization.rpt".format(build_name))
        tcl.append("route_design")
        tcl.append("report_route_status -file {}_route_status.rpt".format(build_name))
        tcl.append("report_drc -file {}_drc.rpt".format(build_name))
        tcl.append("report_timing_summary -max_paths 10 -file {}_timing.rpt".format(build_name))
        tcl.append("report_power -file {}_power.rpt".format(build_name))
        for bitstream_command in self.bitstream_commands:
            tcl.append(bitstream_command.format(build_name=build_name))
        tcl.append("write_bitstream -force {}.bit ".format(build_name))
        for additional_command in self.additional_commands:
            tcl.append(additional_command.format(build_name=build_name))
        tcl.append("quit")
        tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 3
0
    def build(self, platform, fragment, build_dir="build", build_name="top",
              toolchain_path=None, run=True, **kwargs):
        if toolchain_path is None:
            toolchain_path = "/opt/Diamond"
        os.makedirs(build_dir, exist_ok=True)
        cwd = os.getcwd()
        os.chdir(build_dir)

        if not isinstance(fragment, _Fragment):
            fragment = fragment.get_fragment()
        platform.finalize(fragment)

        v_output = platform.get_verilog(fragment, name=build_name, **kwargs)
        named_sc, named_pc = platform.resolve_signals(v_output.ns)
        v_file = build_name + ".v"
        v_output.write(v_file)
        sources = platform.sources | {(v_file, "verilog", "work")}
        _build_files(platform.device, sources, platform.verilog_include_paths, build_name)

        tools.write_to_file(build_name + ".lpf", _build_lpf(named_sc, named_pc))

        script = _build_script(build_name, platform.device, toolchain_path)
        if run:
            _run_script(script)

        os.chdir(cwd)

        return v_output.ns
Exemplo n.º 4
0
def _build_script(build_name, device, toolchain_path, ver=None):
    if sys.platform in ("win32", "cygwin"):
        script_ext = ".bat"
        build_script_contents = "@echo off\nrem Autogenerated by Migen\n\n"
        copy_stmt = "copy"
        fail_stmt = " || exit /b"
    else:
        script_ext = ".sh"
        build_script_contents = "# Autogenerated by Migen\nset -e\n\n"
        copy_stmt = "cp"
        fail_stmt = ""

    if sys.platform not in ("win32", "cygwin"):
        build_script_contents += "bindir={}\n".format(toolchain_path)
        build_script_contents += ". ${{bindir}}/diamond_env{fail_stmt}\n".format(
            fail_stmt=fail_stmt)
    build_script_contents += "{pnmainc} {tcl_script}{fail_stmt}\n".format(
        pnmainc=os.path.join(toolchain_path, "pnmainc"),
        tcl_script=build_name + ".tcl",
        fail_stmt=fail_stmt)
    for ext in (".bit", ".jed"):
        if ext == ".jed" and not _produces_jedec(device):
            continue
        build_script_contents += "{copy_stmt} {diamond_product} {migen_product}" \
                                 "{fail_stmt}\n".format(
            copy_stmt=copy_stmt,
            fail_stmt=fail_stmt,
            diamond_product=os.path.join("impl", build_name + "_impl" + ext),
            migen_product=build_name + ext)

    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file, build_script_contents,
                        force_unix=False)
    return build_script_file
Exemplo n.º 5
0
def _build_sim(platform, vns, build_name, include_paths, serial, verbose):
    include = ""
    for path in include_paths:
        include += "-I"+path+" "

    build_script_contents = """# Autogenerated by LiteX
    rm -rf obj_dir/
verilator {disable_warnings} -O3 --cc dut.v --exe dut_tb.cpp -LDFLAGS "-lpthread -lSDL" -trace {include}
make -j -C obj_dir/ -f Vdut.mk Vdut

""".format(
    disable_warnings="-Wno-fatal",
    include=include)
    build_script_file = "build_" + build_name + ".sh"
    tools.write_to_file(build_script_file, build_script_contents, force_unix=True)

    _build_tb(platform, vns, serial, os.path.join(sim_directory, "dut_tb.cpp"))
    p = subprocess.Popen(["bash", build_script_file], stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
    output, _ = p.communicate()
    output = output.decode('utf-8')
    if p.returncode != 0:
        error_messages = []
        for l in output.splitlines():
            if verbose or "error" in l.lower():
                error_messages.append(l)
        raise OSError("Subprocess failed with {}\n{}".format(p.returncode, "\n".join(error_messages)))
    if verbose:
        print(output)
Exemplo n.º 6
0
    def build(self, platform, fragment, build_dir="build", build_name="top",
            toolchain_path="/opt/Xilinx/Vivado", source=True, run=True,
            synth_mode="vivado", enable_xpm=False, **kwargs):
        if toolchain_path is None:
            toolchain_path = "/opt/Xilinx/Vivado"
        os.makedirs(build_dir, exist_ok=True)
        cwd = os.getcwd()
        os.chdir(build_dir)

        if not isinstance(fragment, _Fragment):
            fragment = fragment.get_fragment()
        platform.finalize(fragment)
        self._convert_clocks(platform)
        self._constrain(platform)
        v_output = platform.get_verilog(fragment, name=build_name, **kwargs)
        named_sc, named_pc = platform.resolve_signals(v_output.ns)
        v_file = build_name + ".v"
        v_output.write(v_file)
        sources = platform.sources | {(v_file, "verilog", "work")}
        edifs = platform.edifs
        ips = platform.ips
        self._build_batch(platform, sources, edifs, ips, build_name, synth_mode, enable_xpm)
        tools.write_to_file(build_name + ".xdc", _build_xdc(named_sc, named_pc))
        if run:
            if synth_mode == "yosys":
                common._run_yosys(platform.device, sources, platform.verilog_include_paths, build_name)
            _run_vivado(build_name, toolchain_path, source)

        os.chdir(cwd)

        return v_output.ns
Exemplo n.º 7
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def _run_sim(build_name):
    run_script_contents = """obj_dir/Vdut
"""
    run_script_file = "run_" + build_name + ".sh"
    tools.write_to_file(run_script_file, run_script_contents, force_unix=True)
    r = subprocess.call(["bash", run_script_file])
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 8
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 def export_csv(self, vns, filename):
     def format_line(*args):
         return ",".join(args) + "\n"
     r = format_line("config", "dw", str(self.dw))
     r += format_line("config", "depth", str(self.depth))
     r += format_line("config", "cd_ratio", str(int(self.cd_ratio)))
     for s in self.signals:
         r += format_line("signal", vns.get_name(s), str(len(s)))
     write_to_file(filename, r)
Exemplo n.º 9
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def _generate_sim_variables(include_paths):
    include = ""
    for path in include_paths:
        include += "-I"+path+" "
    content = """\
SRC_DIR = {}
INC_DIR = {}
""".format(core_directory, include)
    tools.write_to_file("variables.mak", content)
Exemplo n.º 10
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    def _generate_csr_csv(self):
        memory_regions = self.soc.get_memory_regions()
        csr_regions = self.soc.get_csr_regions()
        constants = self.soc.get_constants()

        csr_dir = os.path.dirname(self.csr_csv)
        os.makedirs(csr_dir, exist_ok=True)
        write_to_file(
            self.csr_csv,
            cpu_interface.get_csr_csv(csr_regions, constants, memory_regions))
Exemplo n.º 11
0
def _build_io_pdc(named_sc, named_pc, build_name, additional_io_constraints):
    pdc = ""
    for sig, pins, others, resname in named_sc:
        if len(pins) > 1:
            for i, p in enumerate(pins):
                pdc += _format_io_pdc(sig + "[" + str(i) + "]", p, others)
        else:
            pdc += _format_io_pdc(sig, pins[0], others)
    pdc += "\n".join(additional_io_constraints)
    tools.write_to_file(build_name + "_io.pdc", pdc)
Exemplo n.º 12
0
Arquivo: ise.py Projeto: mithro/litex
    def build(self, platform, fragment, build_dir="build", build_name="top",
            toolchain_path=None, source=True, run=True, mode="xst", **kwargs):
        if not isinstance(fragment, _Fragment):
            fragment = fragment.get_fragment()
        if toolchain_path is None:
            if sys.platform == "win32":
                toolchain_path = "C:\\Xilinx"
            elif sys.platform == "cygwin":
                toolchain_path = "/cygdrive/c/Xilinx"
            else:
                toolchain_path = "/opt/Xilinx"

        platform.finalize(fragment)
        ngdbuild_opt = self.ngdbuild_opt
        vns = None

        os.makedirs(build_dir, exist_ok=True)
        cwd = os.getcwd()
        os.chdir(build_dir)
        try:
            if mode in ("xst", "yosys", "cpld"):
                v_output = platform.get_verilog(fragment, name=build_name, **kwargs)
                vns = v_output.ns
                named_sc, named_pc = platform.resolve_signals(vns)
                v_file = build_name + ".v"
                v_output.write(v_file)
                sources = platform.sources | {(v_file, "verilog", "work")}
                if mode in ("xst", "cpld"):
                    _build_xst_files(platform.device, sources, platform.verilog_include_paths, build_name, self.xst_opt)
                    isemode = mode
                else:
                    _run_yosys(platform.device, sources, platform.verilog_include_paths, build_name)
                    isemode = "edif"
                    ngdbuild_opt += "-p " + platform.device

            if mode == "mist":
                from mist import synthesize
                synthesize(fragment, platform.constraint_manager.get_io_signals())

            if mode == "edif" or mode == "mist":
                e_output = platform.get_edif(fragment)
                vns = e_output.ns
                named_sc, named_pc = platform.resolve_signals(vns)
                e_file = build_name + ".edif"
                e_output.write(e_file)
                isemode = "edif"

            tools.write_to_file(build_name + ".ucf", _build_ucf(named_sc, named_pc))
            if run:
                _run_ise(build_name, toolchain_path, source, isemode,
                         ngdbuild_opt, self, platform)
        finally:
            os.chdir(cwd)

        return vns
Exemplo n.º 13
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 def export(self, vns, filename):
     def format_line(*args):
         return ",".join(args) + "\n"
     r = ""
     r += format_line("config", "dw", str(self.dw))
     r += format_line("config", "depth", str(self.depth))
     r += format_line("config", "with_rle", str(int(self.with_rle)))
     if not isinstance(self.layout, tuple):
         self.layout = [self.layout]
     for e in self.layout:
         r += format_line("layout", vns.get_name(e), str(len(e)))
     write_to_file(filename, r)
Exemplo n.º 14
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def _run_diamond(build_name, source, ver=None):
    if sys.platform == "win32" or sys.platform == "cygwin":
        build_script_contents = "REM Autogenerated by LiteX\n"
        build_script_contents = "pnmainc " + build_name + ".tcl\n"
        build_script_file = "build_" + build_name + ".bat"
        tools.write_to_file(build_script_file, build_script_contents)
        r = subprocess.call([build_script_file])
        shutil.copy(os.path.join("implementation", build_name + "_implementation.bit"), build_name + ".bit")
    else:
        raise NotImplementedError

    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 15
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def _build_files(device, sources, vincpaths, build_name):
    tcl = []
    tcl.append("prj_project new -name \"{}\" -impl \"implementation\" -dev {} -synthesis \"synplify\"".format(build_name, device))
    for path in vincpaths:
        tcl.append("prj_impl option {include path} {\"" + path + "\"}")
    for filename, language, library in sources:
        tcl.append("prj_src add \"" + filename + "\" -work " + library)
    tcl.append("prj_run Synthesis -impl implementation -forceOne")
    tcl.append("prj_run Translate -impl implementation")
    tcl.append("prj_run Map -impl implementation")
    tcl.append("prj_run PAR -impl implementation")
    tcl.append("prj_run Export -impl implementation -task Bitgen")
    tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 16
0
Arquivo: ise.py Projeto: mithro/litex
def _run_ise(build_name, ise_path, source, mode, ngdbuild_opt,
        toolchain, platform, ver=None):
    if sys.platform == "win32" or sys.platform == "cygwin":
        source_cmd = "call "
        script_ext = ".bat"
        shell = ["cmd", "/c"]
        build_script_contents = "@echo off\nrem Autogenerated by Migen\n"
        fail_stmt = " || exit /b"
    else:
        source_cmd = "source "
        script_ext = ".sh"
        shell = ["bash"]
        build_script_contents = "# Autogenerated by Migen\nset -e\n"
        fail_stmt = ""
    if source:
        settings = common.settings(ise_path, ver, "ISE_DS")
        build_script_contents += source_cmd + tools.cygpath(settings) + "\n"
    if mode == "edif":
        ext = "edif"
    else:
        ext = "ngc"
        build_script_contents += """
xst -ifn {build_name}.xst{fail_stmt}
"""

    build_script_contents += """
ngdbuild {ngdbuild_opt} -uc {build_name}.ucf {build_name}.{ext} {build_name}.ngd{fail_stmt}
"""
    if mode == "cpld":
        build_script_contents += """
cpldfit -ofmt verilog {par_opt} -p {device} {build_name}.ngd{fail_stmt}
taengine -f {build_name}.vm6 -detail -iopath -l {build_name}.tim{fail_stmt}
hprep6 -s IEEE1532 -i {build_name}.vm6{fail_stmt}
"""
    else:
        build_script_contents += """
map {map_opt} -o {build_name}_map.ncd {build_name}.ngd {build_name}.pcf{fail_stmt}
par {par_opt} {build_name}_map.ncd {build_name}.ncd {build_name}.pcf{fail_stmt}
bitgen {bitgen_opt} {build_name}.ncd {build_name}.bit{fail_stmt}
"""
    build_script_contents = build_script_contents.format(build_name=build_name,
            ngdbuild_opt=ngdbuild_opt, bitgen_opt=toolchain.bitgen_opt, ext=ext,
            par_opt=toolchain.par_opt, map_opt=toolchain.map_opt,
            device=platform.device, fail_stmt=fail_stmt)
    build_script_contents += toolchain.ise_commands.format(build_name=build_name)
    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file, build_script_contents, force_unix=False)
    command = shell + [build_script_file]
    r = tools.subprocess_call_filtered(command, common.colors)
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 17
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def main():
    if len(sys.argv) < 2:
        print("usage: litex_read_verilog verilog_file [module]")
        exit(1)

    verilog_file = sys.argv[1]
    json_file = verilog_file + ".json"
    module = None if len(sys.argv) < 3 else sys.argv[2]

    # use yosys to convert verilog to json
    yosys_v2j = "\n".join([
        "read_verilog -sv {}".format(verilog_file),
        "write_json {}.json".format(verilog_file)
    ])
    tools.write_to_file("yosys_v2j.ys", yosys_v2j)
    os.system("yosys -q yosys_v2j.ys")

    # load json and convert to migen module
    f = open(json_file, "r")
    j = json.load(f)

    # create list of modules
    modules = [module] if module is not None else j["modules"].keys()

    # create migen definitions
    for module in modules:
        migen_def = []
        migen_def.append("class {}(Module):".format(module))
        migen_def.append(" "*4 + "def __init__(self):")
        for name, info in j["modules"][module]["ports"].items():
            length = "" if len(info["bits"]) == 1 else len(info["bits"])
            migen_def.append(" " * 8 + "self.{} = Signal({})".format(name, length))
        migen_def.append("")
        migen_def.append(" "*8 + "# # #")
        migen_def.append("")
        migen_def.append(" "*8 + "self.specials += Instance(\"{}\",".format(module))
        for name, info in j["modules"][module]["ports"].items():
            io_prefix = {
                "input": "i",
                "output": "o",
                "inout": "io"
            }[info["direction"]]
            migen_def.append(" "*12 + "{}_{}=self.{},".format(io_prefix, name, name))
        migen_def.append(" "*8 + ")")
        migen_def.append("")
        print("\n".join(migen_def))

    # keep things clean after us
    os.system("rm " + json_file)
Exemplo n.º 18
0
def _build_script(build_name, device, toolchain_path, ver=None):
    if sys.platform in ("win32", "cygwin"):
        script_ext = ".bat"
        build_script_contents = "@echo off\nrem Autogenerated by Migen\n\n"
        copy_stmt = "copy"
        fail_stmt = " || exit /b"
    else:
        script_ext = ".sh"
        build_script_contents = "# Autogenerated by Migen\n\n"
        copy_stmt = "cp"
        fail_stmt = " || exit 1"

    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file, build_script_contents,
                        force_unix=False)
    return build_script_file
Exemplo n.º 19
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def _build_xst_files(device, sources, vincpaths, build_name, xst_opt):
    prj_contents = ""
    for filename, language, library in sources:
        prj_contents += language + " " + library + " " + filename + "\n"
    tools.write_to_file(build_name + ".prj", prj_contents)

    xst_contents = """run
-ifn {build_name}.prj
-top {build_name}
{xst_opt}
-ofn {build_name}.ngc
-p {device}
""".format(build_name=build_name, xst_opt=xst_opt, device=device)
    for path in vincpaths:
        xst_contents += "-vlgincdir " + path + "\n"
    tools.write_to_file(build_name + ".xst", xst_contents)
Exemplo n.º 20
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def _run_sim(build_name, as_root=False):
    run_script_contents = "sudo " if as_root else ""
    run_script_contents += "obj_dir/Vdut"
    run_script_file = "run_" + build_name + ".sh"
    tools.write_to_file(run_script_file, run_script_contents, force_unix=True)
    if sys.platform != "win32":
        import termios
        termios_settings = termios.tcgetattr(sys.stdin.fileno())
    try:
        r = subprocess.call(["bash", run_script_file])
        if r != 0:
            raise OSError("Subprocess failed")
    except:
        pass
    if sys.platform != "win32":
        termios.tcsetattr(sys.stdin.fileno(), termios.TCSAFLUSH, termios_settings)
Exemplo n.º 21
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def _build_sim(build_name, sources, threads, coverage):
    makefile = os.path.join(core_directory, 'Makefile')
    cc_srcs = []
    for filename, language, library in sources:
        cc_srcs.append("--cc " + filename + " ")
    build_script_contents = """\
rm -rf obj_dir/
make -C . -f {} {} {} {}
mkdir -p modules && cp obj_dir/*.so modules
""".format(makefile,
    "CC_SRCS=\"{}\"".format("".join(cc_srcs)),
    "THREADS={}".format(threads) if int(threads) > 1 else "",
    "COVERAGE=1" if coverage else "",
    )
    build_script_file = "build_" + build_name + ".sh"
    tools.write_to_file(build_script_file, build_script_contents, force_unix=True)
Exemplo n.º 22
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def _run_yosys(device, sources, vincpaths, build_name):
    ys_contents = ""
    incflags = ""
    for path in vincpaths:
        incflags += " -I" + path
    for filename, language, library in sources:
        ys_contents += "read_{}{} {}\n".format(language, incflags, filename)

    ys_contents += """\
hierarchy -top top

# FIXME: Are these needed?
# proc; memory; opt; fsm; opt

# Map keep to keep=1 for yosys
log
log XX. Converting (* keep = "xxxx" *) attribute for Yosys
log
attrmap -tocase keep -imap keep="true" keep=1 -imap keep="false" keep=0 -remove keep=0
select -list a:keep=1

# Add keep=1 for yosys to objects which have dont_touch="true" attribute.
log
log XX. Converting (* dont_touch = "true" *) attribute for Yosys
log
select -list a:dont_touch=true
setattr -set keep 1 a:dont_touch=true

# Convert (* async_reg = "true" *) to async registers for Yosys.
# (* async_reg = "true", dont_touch = "true" *) reg xilinxmultiregimpl0_regs1 = 1'd0;
log
log XX. Converting (* async_reg = "true" *) attribute to async registers for Yosys
log
select -list a:async_reg=true
setattr -set keep 1 a:async_reg=true

synth_xilinx -top top

write_edif -pvector bra -attrprop {build_name}.edif
""".format(build_name=build_name)

    ys_name = build_name + ".ys"
    tools.write_to_file(ys_name, ys_contents)
    r = subprocess.call(["yosys", ys_name])
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 23
0
    def build(self, platform, fragment, build_dir="build", build_name="top",
            toolchain_path=None, source=None, run=True, mode="xst", **kwargs):
        if not isinstance(fragment, _Fragment):
            fragment = fragment.get_fragment()
        if toolchain_path is None:
            if sys.platform == "win32":
                toolchain_path = "C:\\Xilinx"
            elif sys.platform == "cygwin":
                toolchain_path = "/cygdrive/c/Xilinx"
            else:
                toolchain_path = "/opt/Xilinx"
        if source is None:
            source = sys.platform != "win32"

        platform.finalize(fragment)
        ngdbuild_opt = self.ngdbuild_opt
        vns = None

        tools.mkdir_noerror(build_dir)
        cwd = os.getcwd()
        os.chdir(build_dir)
        try:
            if mode == "xst" or mode == "yosys":
                v_output = platform.get_verilog(fragment, name=build_name, **kwargs)
                vns = v_output.ns
                named_sc, named_pc = platform.resolve_signals(vns)
                v_file = build_name + ".v"
                v_output.write(v_file)
                sources = platform.sources | {(v_file, "verilog", "work")}
                if mode == "xst":
                    _build_xst_files(platform.device, sources, platform.verilog_include_paths, build_name, self.xst_opt)
                    isemode = "xst"
                else:
                    _run_yosys(platform.device, sources, platform.verilog_include_paths, build_name)
                    isemode = "edif"
                    ngdbuild_opt += "-p " + platform.device

            tools.write_to_file(build_name + ".ucf", _build_ucf(named_sc, named_pc))
            if run:
                _run_ise(build_name, toolchain_path, source, isemode,
                         ngdbuild_opt, self.bitgen_opt, self.ise_commands,
                         self.map_opt, self.par_opt)
        finally:
            os.chdir(cwd)

        return vns
Exemplo n.º 24
0
Arquivo: ise.py Projeto: mithro/litex
def _run_yosys(device, sources, vincpaths, build_name):
    ys_contents = ""
    incflags = ""
    for path in vincpaths:
        incflags += " -I" + path
    for filename, language, library in sources:
        ys_contents += "read_{}{} {}\n".format(language, incflags, filename)

    ys_contents += """hierarchy -check -top top
proc; memory; opt; fsm; opt
synth_xilinx -top top -edif {build_name}.edif""".format(build_name=build_name)

    ys_name = build_name + ".ys"
    tools.write_to_file(ys_name, ys_contents)
    r = subprocess.call(["yosys", ys_name])
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 25
0
def _run_quartus(build_name, quartus_path):
    build_script_contents = """# Autogenerated by LiteX

set -e

quartus_map --read_settings_files=on --write_settings_files=off {build_name} -c {build_name}
quartus_fit --read_settings_files=off --write_settings_files=off {build_name} -c {build_name}
quartus_asm --read_settings_files=off --write_settings_files=off {build_name} -c {build_name}
quartus_sta {build_name} -c {build_name}

""".format(build_name=build_name)  # noqa
    build_script_file = "build_" + build_name + ".sh"
    tools.write_to_file(build_script_file,
                        build_script_contents,
                        force_unix=True)

    if subprocess.call(["bash", build_script_file]):
        raise OSError("Subprocess failed")
Exemplo n.º 26
0
def _build_timing_sdc(vns, clocks, false_paths, build_name, additional_timing_constraints):
    sdc = []

    for clk, period in sorted(clocks.items(), key=lambda x: x[0].duid):
        sdc.append(
            "create_clock -name {clk} -period " + str(period) +
            " [get_nets {clk}]".format(clk=vns.get_name(clk)))
    for from_, to in sorted(false_paths,
                            key=lambda x: (x[0].duid, x[1].duid)):
        sdc.append(
            "set_clock_groups "
            "-group [get_clocks -include_generated_clocks -of [get_nets {from_}]] "
            "-group [get_clocks -include_generated_clocks -of [get_nets {to}]] "
            "-asynchronous".format(from_=from_, to=to))

    # generate sdc
    sdc += additional_timing_constraints
    tools.write_to_file(build_name + ".sdc", "\n".join(sdc))
Exemplo n.º 27
0
def _generate_sim_h(platform):
    content = """\
#ifndef __SIM_CORE_H_
#define __SIM_CORE_H_
#include "pads.h"

"""
    for args in platform.sim_requested:
        content += _generate_sim_h_struct(*args)

    content += """\
#ifndef __cplusplus
void litex_sim_init(void **out);
#endif

#endif /* __SIM_CORE_H_ */
"""
    tools.write_to_file("dut_header.h", content)
Exemplo n.º 28
0
def _run_vivado(build_name, vivado_path, source, ver=None):
    if sys.platform == "win32" or sys.platform == "cygwin":
        build_script_contents = "REM Autogenerated by LiteX\n"
        build_script_contents += "vivado -mode batch -source " + build_name + ".tcl\n"
        build_script_file = "build_" + build_name + ".bat"
        tools.write_to_file(build_script_file, build_script_contents)
        r = subprocess.call([build_script_file])
    else:
        build_script_contents = "# Autogenerated by LiteX\nset -e\n"
        if vivado_path is None:
            vivado_path = "/opt/Xilinx/Vivado"
        settings = common.settings(vivado_path, ver)
        build_script_contents += "source " + settings + "\n"
        build_script_contents += "vivado -mode batch -source " + build_name + ".tcl\n"
        build_script_file = "build_" + build_name + ".sh"
        tools.write_to_file(build_script_file, build_script_contents)
        r = subprocess.call(["bash", build_script_file])

    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 29
0
def _build_script(source, build_template, build_name, **kwargs):
    if sys.platform in ("win32", "cygwin"):
        script_ext = ".bat"
        build_script_contents = "@echo off\nrem Autogenerated by Migen\n\n"
        fail_stmt = " || exit /b"
    else:
        script_ext = ".sh"
        build_script_contents = "# Autogenerated by Migen\nset -e\n\n"
        fail_stmt = ""

    for s in build_template:
        s_fail = s + "{fail_stmt}\n"  # Required so Windows scripts fail early.
        build_script_contents += s_fail.format(build_name=build_name,
                                               fail_stmt=fail_stmt,
                                               **kwargs)

    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file, build_script_contents,
                        force_unix=False)
    return build_script_file
Exemplo n.º 30
0
def _build_files(device, sources, vincpaths, named_sc, named_pc, build_name):
    lines = []
    for filename, language, library in sources:
        # Enforce use of SystemVerilog
        # (Quartus does not support global parameters in Verilog)
        if language == "verilog":
            language = "systemverilog"
        lines.append(
            "set_global_assignment -name {lang}_FILE {path} "
            "-library {lib}".format(
                lang=language.upper(),
                path=filename.replace("\\", "/"),
                lib=library))

    for path in vincpaths:
        lines.append("set_global_assignment -name SEARCH_PATH {}".format(
            path.replace("\\", "/")))

    lines.append(_build_qsf(named_sc, named_pc))
    lines.append("set_global_assignment -name DEVICE {}".format(device))
    tools.write_to_file("{}.qsf".format(build_name), "\n".join(lines))
    def _build_batch(self, platform, sources, edifs, ips, build_name,
                     synth_mode, enable_xpm):
        assert synth_mode in ["vivado", "yosys"]
        tcl = []
        tcl.append("create_project -force -name {} -part {}".format(
            build_name, platform.device))
        if enable_xpm:
            tcl.append(
                "set_property XPM_LIBRARIES {XPM_CDC XPM_MEMORY} [current_project]"
            )
        if synth_mode == "vivado":
            # "-include_dirs {}" crashes Vivado 2016.4
            for filename, language, library in sources:
                filename_tcl = "{" + filename + "}"
                tcl.append("add_files " + filename_tcl)
                if language == "vhdl":
                    tcl.append("set_property library {} [get_files {}]".format(
                        library, filename_tcl))
        for filename in edifs:
            filename_tcl = "{" + filename + "}"
            tcl.append("read_edif " + filename_tcl)

        for filename in ips:
            filename_tcl = "{" + filename + "}"
            ip = os.path.splitext(os.path.basename(filename))[0]
            tcl.append("read_ip " + filename_tcl)
            tcl.append("upgrade_ip [get_ips {}]".format(ip))
            tcl.append("generate_target all [get_ips {}]".format(ip))
            tcl.append("synth_ip [get_ips {}] -force".format(ip))
            tcl.append("get_files -all -of_objects [get_files {}]".format(
                filename_tcl))

        tcl.append("read_xdc {}.xdc".format(build_name))
        tcl.extend(
            c.format(build_name=build_name)
            for c in self.pre_synthesis_commands)

        if synth_mode == "vivado":
            if platform.verilog_include_paths:
                tcl.append(
                    "synth_design -top {} -part {} -include_dirs {{{}}}".
                    format(build_name, platform.device,
                           " ".join(platform.verilog_include_paths)))
            else:
                tcl.append("synth_design -top {} -part {}".format(
                    build_name, platform.device))
        elif synth_mode == "yosys":
            tcl.append("read_edif {}.edif".format(build_name))
            tcl.append("link_design -top {} -part {}".format(
                build_name, platform.device))
        else:
            raise OSError("Unknown synthesis mode! {}".format(synth_mode))

        tcl.append("report_timing_summary -file {}_timing_synth.rpt".format(
            build_name))
        tcl.append(
            "report_utilization -hierarchical -file {}_utilization_hierarchical_synth.rpt"
            .format(build_name))
        tcl.append("report_utilization -file {}_utilization_synth.rpt".format(
            build_name))
        tcl.append("opt_design")
        tcl.append("place_design")
        if self.with_phys_opt:
            tcl.append("phys_opt_design -directive AddRetime")
        tcl.append(
            "report_utilization -hierarchical -file {}_utilization_hierarchical_place.rpt"
            .format(build_name))
        tcl.append("report_utilization -file {}_utilization_place.rpt".format(
            build_name))
        tcl.append("report_io -file {}_io.rpt".format(build_name))
        tcl.append(
            "report_control_sets -verbose -file {}_control_sets.rpt".format(
                build_name))
        tcl.append(
            "report_clock_utilization -file {}_clock_utilization.rpt".format(
                build_name))
        tcl.append("route_design")
        tcl.append("phys_opt_design")
        tcl.append("report_timing_summary -no_header -no_detailed_paths")
        tcl.append("write_checkpoint -force {}_route.dcp".format(build_name))
        tcl.append(
            "report_route_status -file {}_route_status.rpt".format(build_name))
        tcl.append("report_drc -file {}_drc.rpt".format(build_name))
        tcl.append(
            "report_timing_summary -datasheet -max_paths 10 -file {}_timing.rpt"
            .format(build_name))
        tcl.append("report_power -file {}_power.rpt".format(build_name))
        for bitstream_command in self.bitstream_commands:
            tcl.append(bitstream_command.format(build_name=build_name))
        tcl.append("write_bitstream -force {}.bit ".format(build_name))
        for additional_command in self.additional_commands:
            tcl.append(additional_command.format(build_name=build_name))
        tcl.append("quit")
        tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 32
0
 def load_bitstream(self, bitstream_file):
     xcf_file = bitstream_file.replace(".bit", ".xcf")
     xcf_content = self.xcf_template.format(bitstream_file=bitstream_file)
     tools.write_to_file(xcf_file, xcf_content)
     subprocess.call(["pgrcmd", "-infile", xcf_file])
Exemplo n.º 33
0
def main():
    parser = argparse.ArgumentParser(description="Opsis LiteX SoC",
                                     conflict_handler='resolve')
    get_args(parser)
    builder_args(parser)
    soc_sdram_args(parser)

    args = parser.parse_args()

    platform = get_platform(args)

    soc = get_soc(args, platform)

    builddir = get_builddir(args)
    testdir = get_testdir(args)

    buildargs = builder_argdict(args)
    if not buildargs.get('output_dir', None):
        buildargs['output_dir'] = builddir

    if hasattr(soc, 'cpu_type'):
        if not buildargs.get('csr_csv', None):
            buildargs['csr_csv'] = os.path.join(testdir, "csr.csv")

        if not buildargs.get('csr_json', None):
            buildargs['csr_json'] = os.path.join(testdir, "csr.json")

        builder = Builder(soc, **buildargs)

        if builder.bios_options is None:
            builder.bios_options = {}

        # using 'bios_options' is a hack, as those settings
        # are intended for the firmware (not bios) - there
        # is just no dictionary for 'firmware_options'
        # available in LiteX;
        # the intended effect of setting those options is to
        # generate entries in the .mak files that can be used
        # in the Makefile
        if 'user_flash' in soc.mem_regions:
            builder.bios_options['EXECUTE_IN_PLACE'] = 1
        else:
            builder.bios_options['COPY_TO_MAIN_RAM'] = 1

        if not args.no_compile_firmware or args.override_firmware:
            builder.add_software_package("uip",
                                         "{}/firmware/uip".format(os.getcwd()))

            # FIXME: All platforms which current run their user programs from
            # SPI flash lack the block RAM resources to run the default
            # firmware. Check whether to use the stub or default firmware
            # should be refined (perhaps soc attribute?).
            if "main_ram" in soc.mem_regions:
                builder.add_software_package("firmware",
                                             "{}/firmware".format(os.getcwd()))
            else:
                builder.add_software_package(
                    "stub", "{}/firmware/stub".format(os.getcwd()))
        vns = builder.build(**dict(args.build_option))
    else:
        vns = platform.build(soc, build_dir=os.path.join(builddir, "gateware"))

    if hasattr(soc, 'pcie_phy'):
        from litex.soc.integration.export import get_csr_header, get_soc_header
        csr_header = get_csr_header(soc.csr_regions,
                                    soc.constants,
                                    with_access_functions=False)
        soc_header = get_soc_header(soc.constants, with_access_functions=False)
        kerneldir = os.path.join(builddir, "software", "pcie", "kernel")
        os.makedirs(kerneldir, exist_ok=True)
        write_to_file(os.path.join(kerneldir, "csr.h"), csr_header)
        write_to_file(os.path.join(kerneldir, "soc.h"), soc_header)

    if hasattr(soc, 'do_exit'):
        soc.do_exit(vns, filename="{}/analyzer.csv".format(testdir))
Exemplo n.º 34
0
    if actions["all"]:
        actions["build-csr-csv"] = True
        actions["build-csr-header"] = True
        actions["build-bitstream"] = True
        actions["load-bitstream"] = True

    if actions["build-bitstream"]:
        actions["build-csr-csv"] = True
        actions["build-csr-header"] = True

    if actions["clean"]:
        subprocess.call(["rm", "-rf", "build/*"])

    if actions["build-csr-csv"]:
        csr_csv = cpu_interface.get_csr_csv(csr_regions)
        write_to_file(args.csr_csv, csr_csv)

    if actions["build-csr-header"]:
        csr_header = cpu_interface.get_csr_header(csr_regions,
                                                  soc.get_constants(),
                                                  with_access_functions=False)
        write_to_file(args.csr_header, csr_header)

    if actions["build-bitstream"]:
        build_kwargs = dict((k, autotype(v)) for k, v in args.build_option)
        vns = platform.build(soc, build_name=build_name, **build_kwargs)
        if hasattr(soc, "do_exit") and vns is not None:
            if hasattr(soc.do_exit, '__call__'):
                soc.do_exit(vns)

    if actions["load-bitstream"]:
Exemplo n.º 35
0
def _run_ise(build_name, mode, ngdbuild_opt, toolchain, platform):
    if sys.platform == "win32" or sys.platform == "cygwin":
        script_ext = ".bat"
        shell = ["cmd", "/c"]
        build_script_contents = "@echo off\nrem Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
        ) + "\n"
        fail_stmt = " || exit /b"
    else:
        script_ext = ".sh"
        shell = ["bash"]
        build_script_contents = "# Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
        ) + "\nset -e\n"
        if os.getenv("LITEX_ENV_ISE", False):
            build_script_contents += "source " + os.path.join(
                os.getenv("LITEX_ENV_ISE"), "settings64.sh\n")
        fail_stmt = ""
    if mode == "edif":
        ext = "ngo"
        build_script_contents += """
edif2ngd {build_name}.edif {build_name}.{ext}{fail_stmt}
"""
    else:
        ext = "ngc"
        build_script_contents += """
xst -ifn {build_name}.xst{fail_stmt}
"""

    # This generates a .v file for post synthesis simulation
    build_script_contents += """
netgen -ofmt verilog -w -sim {build_name}.{ext} {build_name}_synth.v
"""

    build_script_contents += """
ngdbuild {ngdbuild_opt} -uc {build_name}.ucf {build_name}.{ext} {build_name}.ngd{fail_stmt}
"""
    if mode == "cpld":
        build_script_contents += """
cpldfit -ofmt verilog {par_opt} -p {device} {build_name}.ngd{fail_stmt}
taengine -f {build_name}.vm6 -detail -iopath -l {build_name}.tim{fail_stmt}
hprep6 -s IEEE1532 -i {build_name}.vm6{fail_stmt}
"""
    else:
        build_script_contents += """
map {map_opt} -o {build_name}_map.ncd {build_name}.ngd {build_name}.pcf{fail_stmt}
par {par_opt} {build_name}_map.ncd {build_name}.ncd {build_name}.pcf{fail_stmt}
bitgen {bitgen_opt} {build_name}.ncd {build_name}.bit{fail_stmt}
"""
    build_script_contents = build_script_contents.format(
        build_name=build_name,
        ngdbuild_opt=ngdbuild_opt,
        bitgen_opt=toolchain.bitgen_opt,
        ext=ext,
        par_opt=toolchain.par_opt,
        map_opt=toolchain.map_opt,
        device=platform.device,
        fail_stmt=fail_stmt)
    build_script_contents += toolchain.ise_commands.format(
        build_name=build_name)
    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file,
                        build_script_contents,
                        force_unix=False)
    command = shell + [build_script_file]

    if which("ise") is None and os.getenv("LITEX_ENV_ISE", False) == False:
        msg = "Unable to find or source ISE toolchain, please either:\n"
        msg += "- Source ISE's settings manually.\n"
        msg += "- Or set LITEX_ENV_ISE environment variant to ISE's settings path.\n"
        msg += "- Or add ISE toolchain to your $PATH."
        raise OSError(msg)

    if tools.subprocess_call_filtered(command, common.colors) != 0:
        raise OSError("Error occured during ISE's script execution.")
Exemplo n.º 36
0
Arquivo: ise.py Projeto: zsipos/litex
    def build(self,
              platform,
              fragment,
              build_dir="build",
              build_name="top",
              toolchain_path=None,
              source=True,
              run=True,
              mode="xst",
              **kwargs):

        # Get default toolchain path (if not specified)
        if toolchain_path is None:
            if sys.platform == "win32":
                toolchain_path = "C:\\Xilinx"
            elif sys.platform == "cygwin":
                toolchain_path = "/cygdrive/c/Xilinx"
            else:
                toolchain_path = "/opt/Xilinx"

        # Create build directory
        os.makedirs(build_dir, exist_ok=True)
        cwd = os.getcwd()
        os.chdir(build_dir)

        # Finalize design
        if not isinstance(fragment, _Fragment):
            fragment = fragment.get_fragment()
        platform.finalize(fragment)

        vns = None
        try:
            if mode in ["xst", "yosys", "cpld"]:
                # Generate verilog
                v_output = platform.get_verilog(fragment,
                                                name=build_name,
                                                **kwargs)
                vns = v_output.ns
                named_sc, named_pc = platform.resolve_signals(vns)
                v_file = build_name + ".v"
                v_output.write(v_file)
                platform.add_source(v_file)

                # Generate design project (.xst)
                if mode in ["xst", "cpld"]:
                    _build_xst(platform.device, platform.sources,
                               platform.verilog_include_paths, build_name,
                               self.xst_opt)
                    isemode = mode
                else:
                    # Run Yosys
                    if run:
                        _run_yosys(platform.device, platform.sources,
                                   platform.verilog_include_paths, build_name)
                    isemode = "edif"
                    self.ngdbuild_opt += "-p " + platform.device

            if mode in ["edif"]:
                # Generate edif
                e_output = platform.get_edif(fragment)
                vns = e_output.ns
                named_sc, named_pc = platform.resolve_signals(vns)
                e_file = build_name + ".edif"
                e_output.write(e_file)
                isemode = "edif"

            # Generate design constraints (.ucf)
            tools.write_to_file(build_name + ".ucf",
                                _build_ucf(named_sc, named_pc))

            # Run ISE
            if run:
                _run_ise(build_name, toolchain_path, source, isemode,
                         self.ngdbuild_opt, self, platform)
        finally:
            os.chdir(cwd)

        return vns
Exemplo n.º 37
0
def _generate_sim_config(config):
    content = config.get_json()
    tools.write_to_file("sim_config.js", content)
Exemplo n.º 38
0
def _build_fp_pdc(build_name, additional_fp_constraints):
    pdc = "\n".join(additional_fp_constraints)
    tools.write_to_file(build_name + "_fp.pdc", pdc)
Exemplo n.º 39
0
 def build_timing_constraints(self, vns):
     r = ""
     for clk, period in self.clocks.items():
         r += """ctx.addClock("{}", {})\n""".format(vns.get_name(clk), 1e3/period)
     tools.write_to_file(self._build_name + "_pre_pack.py", r)
     return (self._build_name + "_pre_pack.py", "PY")
Exemplo n.º 40
0
    # dependencies
    if actions["all"]:
        actions["build-csr-csv"] = True
        actions["build-bitstream"] = True
        actions["load-bitstream"] = True

    if actions["build-bitstream"]:
        actions["build-csr-csv"] = True

    if actions["clean"]:
        subprocess.call(["rm", "-rf", "build/*"])

    if actions["build-csr-csv"]:
        csr_csv = cpu_interface.get_csr_csv(csr_regions, csr_constants)
        write_to_file(args.csr_csv, csr_csv)

    if actions["build-core"]:
        soc_fragment = soc.get_fragment()
        platform.finalize(soc_fragment)
        v_output = platform.get_verilog(
            soc_fragment,
            name="litescope",
            special_overrides=xilinx_special_overrides)
        v_output.write("build/litescope.v")

    if actions["build-bitstream"]:
        build_kwargs = dict((k, autotype(v)) for k, v in args.build_option)
        vns = platform.build(soc, build_name=build_name, **build_kwargs)
        if hasattr(soc, "do_exit") and vns is not None:
            if hasattr(soc.do_exit, '__call__'):
Exemplo n.º 41
0
    def _generate_includes(self):
        # Generate Include/Generated directories.
        _create_dir(self.include_dir)
        _create_dir(self.generated_dir)

        # Generate BIOS files when the SoC uses it.
        with_bios = self.soc.cpu_type not in [None, "zynq7000"]
        if with_bios:

            # Generate Variables to variables.mak.
            variables_contents = []

            def define(k, v):
                variables_contents.append("{}={}".format(
                    k, _makefile_escape(v)))

            # Define the CPU variables.
            for k, v in export.get_cpu_mak(self.soc.cpu,
                                           self.compile_software):
                define(k, v)

            # Define the SoC/Compiler-RT/Software/Include directories.
            define("SOC_DIRECTORY", soc_directory)
            define("COMPILER_RT_DIRECTORY", compiler_rt_directory)
            variables_contents.append("export BUILDINC_DIRECTORY")
            define("BUILDINC_DIRECTORY", self.include_dir)
            for name, src_dir in self.software_packages:
                define(name.upper() + "_DIRECTORY", src_dir)

            # Define the BIOS Options.
            for bios_option in self.bios_options:
                assert bios_option in [
                    "TERM_NO_HIST", "TERM_MINI", "TERM_NO_COMPLETE"
                ]
                define(bios_option, "1")

            # Write to variables.mak.
            write_to_file(os.path.join(self.generated_dir, "variables.mak"),
                          "\n".join(variables_contents))

            # Generate Output Format to output_format.ld.
            output_format_contents = export.get_linker_output_format(
                self.soc.cpu)
            write_to_file(os.path.join(self.generated_dir, "output_format.ld"),
                          output_format_contents)

            # Generate Memory Regions to regions.ld.
            regions_contents = export.get_linker_regions(self.soc.mem_regions)
            write_to_file(os.path.join(self.generated_dir, "regions.ld"),
                          regions_contents)

        # Generate Memory Regions to mem.h.
        mem_contents = export.get_mem_header(self.soc.mem_regions)
        write_to_file(os.path.join(self.generated_dir, "mem.h"), mem_contents)

        # Generate Memory Regions to memory.x if specified.
        if self.memory_x is not None:
            memory_x_contents = export.get_memory_x(self.soc)
            write_to_file(os.path.realpath(self.memory_x), memory_x_contents)

        # Generate SoC Config/Constants to soc.h.
        soc_contents = export.get_soc_header(self.soc.constants)
        write_to_file(os.path.join(self.generated_dir, "soc.h"), soc_contents)

        # Generate CSR registers definitions/access functions to csr.h.
        csr_contents = export.get_csr_header(
            regions=self.soc.csr_regions,
            constants=self.soc.constants,
            csr_base=self.soc.mem_regions['csr'].origin)
        write_to_file(os.path.join(self.generated_dir, "csr.h"), csr_contents)

        # Generate Git SHA1 of tools to git.h
        git_contents = export.get_git_header()
        write_to_file(os.path.join(self.generated_dir, "git.h"), git_contents)

        # Generate LiteDRAM C header to sdram_phy.h when the SoC use it.
        if hasattr(self.soc, "sdram"):
            from litedram.init import get_sdram_phy_c_header
            sdram_contents = get_sdram_phy_c_header(
                self.soc.sdram.controller.settings.phy,
                self.soc.sdram.controller.settings.timing)
            write_to_file(os.path.join(self.generated_dir, "sdram_phy.h"),
                          sdram_contents)
Exemplo n.º 42
0
    def _generate_includes(self):
        os.makedirs(self.include_dir, exist_ok=True)
        os.makedirs(self.generated_dir, exist_ok=True)

        if self.soc.cpu_type is not None:
            variables_contents = []

            def define(k, v):
                variables_contents.append("{}={}\n".format(
                    k, _makefile_escape(v)))

            for k, v in export.get_cpu_mak(self.soc.cpu,
                                           self.compile_software):
                define(k, v)
            # Distinguish between LiteX and MiSoC.
            define("LITEX", "1")
            # Distinguish between applications running from main RAM and
            # flash for user-provided software packages.
            exec_profiles = {"COPY_TO_MAIN_RAM": "0", "EXECUTE_IN_PLACE": "0"}
            if "main_ram" in self.soc.mem_regions.keys():
                exec_profiles["COPY_TO_MAIN_RAM"] = "1"
            else:
                exec_profiles["EXECUTE_IN_PLACE"] = "1"
            for k, v in exec_profiles.items():
                define(k, v)
            define("COMPILER_RT_DIRECTORY",
                   get_data_mod("software", "compiler_rt").data_location)
            define("SOC_DIRECTORY", soc_directory)
            variables_contents.append("export BUILDINC_DIRECTORY\n")
            define("BUILDINC_DIRECTORY", self.include_dir)
            for name, src_dir in self.software_packages:
                define(name.upper() + "_DIRECTORY", src_dir)

            if self.bios_options is not None:
                for option in self.bios_options:
                    define(option, "1")

            write_to_file(os.path.join(self.generated_dir, "variables.mak"),
                          "".join(variables_contents))
            write_to_file(os.path.join(self.generated_dir, "output_format.ld"),
                          export.get_linker_output_format(self.soc.cpu))
            write_to_file(os.path.join(self.generated_dir, "regions.ld"),
                          export.get_linker_regions(self.soc.mem_regions))

        write_to_file(os.path.join(self.generated_dir, "mem.h"),
                      export.get_mem_header(self.soc.mem_regions))
        write_to_file(os.path.join(self.generated_dir, "soc.h"),
                      export.get_soc_header(self.soc.constants))
        write_to_file(
            os.path.join(self.generated_dir, "csr.h"),
            export.get_csr_header(self.soc.csr_regions, self.soc.constants))
        write_to_file(os.path.join(self.generated_dir, "git.h"),
                      export.get_git_header())

        if hasattr(self.soc, "sdram"):
            from litedram.init import get_sdram_phy_c_header
            write_to_file(
                os.path.join(self.generated_dir, "sdram_phy.h"),
                get_sdram_phy_c_header(
                    self.soc.sdram.controller.settings.phy,
                    self.soc.sdram.controller.settings.timing))
Exemplo n.º 43
0
 def build_placement_constraints(self):
     pdc = "\n".join(self.additional_fp_constraints)
     tools.write_to_file(self._build_name + "_fp.pdc", pdc)
     return (self._build_name + "_fp.pdc", "PDC")
Exemplo n.º 44
0
    def build_script(self):
        if sys.platform == "win32" or sys.platform == "cygwin":
            script_ext = ".bat"
            shell = ["cmd", "/c"]
            build_script_contents = "@echo off\nrem Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
            ) + "\n"
            fail_stmt = " || exit /b"
        else:
            script_ext = ".sh"
            shell = ["bash"]
            build_script_contents = "# Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
            ) + "\nset -e\n"
            if os.getenv("LITEX_ENV_ISE", False):
                build_script_contents += "source " + os.path.join(
                    os.getenv("LITEX_ENV_ISE"), "settings64.sh\n")
            fail_stmt = ""
        if self._isemode == "edif":
            ext = "ngo"
            build_script_contents += """
edif2ngd {build_name}.edif {build_name}.{ext}{fail_stmt}
"""
        else:
            ext = "ngc"
            build_script_contents += """
xst -ifn {build_name}.xst{fail_stmt}
"""

        # This generates a .v file for post synthesis simulation
        build_script_contents += """
netgen -ofmt verilog -w -sim {build_name}.{ext} {build_name}_synth.v
"""

        build_script_contents += """
ngdbuild {ngdbuild_opt} -uc {build_name}.ucf {build_name}.{ext} {build_name}.ngd{fail_stmt}
"""
        if self._isemode == "cpld":
            build_script_contents += """
cpldfit -ofmt verilog {par_opt} -p {device} {build_name}.ngd{fail_stmt}
taengine -f {build_name}.vm6 -detail -iopath -l {build_name}.tim{fail_stmt}
hprep6 -s IEEE1532 -i {build_name}.vm6{fail_stmt}
"""
        else:
            build_script_contents += """
map {map_opt} -o {build_name}_map.ncd {build_name}.ngd {build_name}.pcf{fail_stmt}
par {par_opt} {build_name}_map.ncd {build_name}.ncd {build_name}.pcf{fail_stmt}
bitgen {bitgen_opt} {build_name}.ncd {build_name}.bit{fail_stmt}
"""
        build_script_contents = build_script_contents.format(
            build_name=self._build_name,
            ngdbuild_opt=self.ngdbuild_opt,
            bitgen_opt=self.bitgen_opt,
            ext=ext,
            par_opt=self.par_opt,
            map_opt=self.map_opt,
            device=self.platform.device,
            fail_stmt=fail_stmt)
        build_script_contents += self.ise_commands.format(
            build_name=self._build_name)
        build_script_file = "build_" + self._build_name + script_ext
        tools.write_to_file(build_script_file,
                            build_script_contents,
                            force_unix=False)
        return build_script_file
Exemplo n.º 45
0
    def _generate_includes(self, with_bios=True):
        # Generate Include/Generated directories.
        _create_dir(self.include_dir)
        _create_dir(self.generated_dir)

        # Generate BIOS files when the SoC uses it.
        if with_bios:
            # Generate Variables to variables.mak.
            variables_contents = self._get_variables_contents()
            write_to_file(os.path.join(self.generated_dir, "variables.mak"),
                          variables_contents)

            # Generate Output Format to output_format.ld.
            output_format_contents = export.get_linker_output_format(
                self.soc.cpu)
            write_to_file(os.path.join(self.generated_dir, "output_format.ld"),
                          output_format_contents)

            # Generate Memory Regions to regions.ld.
            regions_contents = export.get_linker_regions(self.soc.mem_regions)
            write_to_file(os.path.join(self.generated_dir, "regions.ld"),
                          regions_contents)

        # Generate Memory Regions to mem.h.
        mem_contents = export.get_mem_header(self.soc.mem_regions)
        write_to_file(os.path.join(self.generated_dir, "mem.h"), mem_contents)

        # Generate Memory Regions to memory.x if specified.
        if self.memory_x is not None:
            memory_x_contents = export.get_memory_x(self.soc)
            write_to_file(os.path.realpath(self.memory_x), memory_x_contents)

        # Generate SoC Config/Constants to soc.h.
        soc_contents = export.get_soc_header(self.soc.constants)
        write_to_file(os.path.join(self.generated_dir, "soc.h"), soc_contents)

        # Generate CSR registers definitions/access functions to csr.h.
        csr_contents = export.get_csr_header(
            regions=self.soc.csr_regions,
            constants=self.soc.constants,
            csr_base=self.soc.mem_regions['csr'].origin)
        write_to_file(os.path.join(self.generated_dir, "csr.h"), csr_contents)

        # Generate Git SHA1 of tools to git.h
        git_contents = export.get_git_header()
        write_to_file(os.path.join(self.generated_dir, "git.h"), git_contents)

        # Generate LiteDRAM C header to sdram_phy.h when the SoC use it
        if hasattr(self.soc, "sdram"):
            from litedram.init import get_sdram_phy_c_header
            sdram_contents = get_sdram_phy_c_header(
                self.soc.sdram.controller.settings.phy,
                self.soc.sdram.controller.settings.timing)
            write_to_file(os.path.join(self.generated_dir, "sdram_phy.h"),
                          sdram_contents)
Exemplo n.º 46
0
Arquivo: ise.py Projeto: zsipos/litex
def _run_ise(build_name,
             ise_path,
             source,
             mode,
             ngdbuild_opt,
             toolchain,
             platform,
             ver=None):
    if sys.platform == "win32" or sys.platform == "cygwin":
        source_cmd = "call "
        script_ext = ".bat"
        shell = ["cmd", "/c"]
        build_script_contents = "@echo off\nrem Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
        ) + "\n"
        fail_stmt = " || exit /b"
    else:
        source_cmd = "source "
        script_ext = ".sh"
        shell = ["bash"]
        build_script_contents = "# Autogenerated by LiteX / git: " + tools.get_litex_git_revision(
        ) + "\nset -e\n"
        fail_stmt = ""
    if source:
        settings = common.settings(ise_path, ver, "ISE_DS")
        build_script_contents += source_cmd + tools.cygpath(settings) + "\n"
    if mode == "edif":
        ext = "ngo"
        build_script_contents += """
edif2ngd {build_name}.edif {build_name}.{ext}{fail_stmt}
"""
    else:
        ext = "ngc"
        build_script_contents += """
xst -ifn {build_name}.xst{fail_stmt}
"""

    # This generates a .v file for post synthesis simulation
    build_script_contents += """
netgen -ofmt verilog -w -sim {build_name}.{ext} {build_name}_synth.v
"""

    build_script_contents += """
ngdbuild {ngdbuild_opt} -uc {build_name}.ucf {build_name}.{ext} {build_name}.ngd{fail_stmt}
"""
    if mode == "cpld":
        build_script_contents += """
cpldfit -ofmt verilog {par_opt} -p {device} {build_name}.ngd{fail_stmt}
taengine -f {build_name}.vm6 -detail -iopath -l {build_name}.tim{fail_stmt}
hprep6 -s IEEE1532 -i {build_name}.vm6{fail_stmt}
"""
    else:
        build_script_contents += """
map {map_opt} -o {build_name}_map.ncd {build_name}.ngd {build_name}.pcf{fail_stmt}
par {par_opt} {build_name}_map.ncd {build_name}.ncd {build_name}.pcf{fail_stmt}
bitgen {bitgen_opt} {build_name}.ncd {build_name}.bit{fail_stmt}
"""
    build_script_contents = build_script_contents.format(
        build_name=build_name,
        ngdbuild_opt=ngdbuild_opt,
        bitgen_opt=toolchain.bitgen_opt,
        ext=ext,
        par_opt=toolchain.par_opt,
        map_opt=toolchain.map_opt,
        device=platform.device,
        fail_stmt=fail_stmt)
    build_script_contents += toolchain.ise_commands.format(
        build_name=build_name)
    build_script_file = "build_" + build_name + script_ext
    tools.write_to_file(build_script_file,
                        build_script_contents,
                        force_unix=False)
    command = shell + [build_script_file]
    r = tools.subprocess_call_filtered(command, common.colors)
    if r != 0:
        raise OSError("Subprocess failed")
Exemplo n.º 47
0
def _build_tcl(platform, sources, build_dir, build_name):
    tcl = []

    # create project
    tcl.append(" ".join([
        "new_project",
        "-location {./impl}",
        "-name {}".format(tcl_name(build_name)),
        "-project_description {}",
        "-block_mode 0",
        "-standalone_peripheral_initialization 0",
        "-instantiate_in_smartdesign 1",
        "-ondemand_build_dh 0",
        "-use_enhanced_constraint_flow 0",
        "-hdl {VERILOG}",
        "-family {PolarFire}",
        "-die {}",
        "-package {}",
        "-speed {}",
        "-die_voltage {}",
        "-part_range {}",
        "-adv_options {}"
        ]))

    die, package, speed = platform.device.split("-")
    tcl.append(" ".join([
        "set_device",
        "-family {PolarFire}",
        "-die {}".format(tcl_name(die)),
        "-package {}".format(tcl_name(package)),
        "-speed {}".format(tcl_name("-" + speed)),
        # FIXME: common to all PolarFire devices?
        "-die_voltage {1.0}",
        "-part_range {EXT}",
        "-adv_options {IO_DEFT_STD:LVCMOS 1.8V}",
        "-adv_options {RESTRICTPROBEPINS:1}",
        "-adv_options {RESTRICTSPIPINS:0}",
        "-adv_options {TEMPR:EXT}",
        "-adv_options {UNUSED_MSS_IO_RESISTOR_PULL:None}",
        "-adv_options {VCCI_1.2_VOLTR:EXT}",
        "-adv_options {VCCI_1.5_VOLTR:EXT}",
        "-adv_options {VCCI_1.8_VOLTR:EXT}",
        "-adv_options {VCCI_2.5_VOLTR:EXT}",
        "-adv_options {VCCI_3.3_VOLTR:EXT}",
        "-adv_options {VOLTR:EXT} "
    ]))

    # add files
    for filename, language, library in sources:
        filename_tcl = "{" + filename + "}"
        tcl.append("import_files -hdl_source " + filename_tcl)

    # set top
    tcl.append("set_root -module {}".format(tcl_name(build_name)))

    # copy init files FIXME: support for include path on LiberoSoC?
    for file in os.listdir(build_dir):
        if file.endswith(".init"):
            tcl.append("file copy -- {} impl/synthesis".format(file))

    # import io constraints
    tcl.append("import_files -io_pdc {}".format(tcl_name(build_name + "_io.pdc")))

    # import floorplanner constraints
    tcl.append("import_files -fp_pdc {}".format(tcl_name(build_name + "_fp.pdc")))

    # import timing constraints
    tcl.append("import_files -convert_EDN_to_HDL 0 -sdc {}".format(tcl_name(build_name + ".sdc")))

    # associate constraints with tools
    tcl.append(" ".join(["organize_tool_files",
        "-tool {SYNTHESIZE}",
        "-file impl/constraint/{}.sdc".format(build_name),
        "-module {}".format(build_name),
        "-input_type {constraint}"
    ]))
    tcl.append(" ".join(["organize_tool_files",
        "-tool {PLACEROUTE}",
        "-file impl/constraint/io/{}_io.pdc".format(build_name),
        "-file impl/constraint/fp/{}_fp.pdc".format(build_name),
        "-file impl/constraint/{}.sdc".format(build_name),
        "-module {}".format(build_name),
        "-input_type {constraint}"
    ]))
    tcl.append(" ".join(["organize_tool_files",
        "-tool {VERIFYTIMING}",
        "-file impl/constraint/{}.sdc".format(build_name),
        "-module {}".format(build_name),
        "-input_type {constraint}"
    ]))

    # build flow
    tcl.append("run_tool -name {CONSTRAINT_MANAGEMENT}")
    tcl.append("run_tool -name {SYNTHESIZE}")
    tcl.append("run_tool -name {PLACEROUTE}")
    tcl.append("run_tool -name {GENERATEPROGRAMMINGDATA}")
    tcl.append("run_tool -name {GENERATEPROGRAMMINGFILE}")

    # generate tcl
    tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 48
0
    def add_sources(platform, use_ghdl_yosys_plugin=False):
        sources = [
            # Common / Types / Helpers.
            "decode_types.vhdl",
            "wishbone_types.vhdl",
            "utils.vhdl",
            "common.vhdl",
            "helpers.vhdl",
            "nonrandom.vhdl",

            # Fetch.
            "fetch1.vhdl",

            # Instruction/Data Cache.
            "cache_ram.vhdl",
            "plru.vhdl",
            "dcache.vhdl",
            "icache.vhdl",

            # Decode.
            "insn_helpers.vhdl",
            "decode1.vhdl",
            "control.vhdl",
            "decode2.vhdl",

            # Register/CR File.
            "register_file.vhdl",
            "crhelpers.vhdl",
            "cr_file.vhdl",

            # Execute.
            "ppc_fx_insns.vhdl",
            "logical.vhdl",
            "rotator.vhdl",
            "countbits.vhdl",
            "execute1.vhdl",

            # Load/Store.
            "loadstore1.vhdl",

            # Divide.
            "divider.vhdl",

            # FPU.
            "fpu.vhdl",

            # PMU.
            "pmu.vhdl",

            # Writeback.
            "writeback.vhdl",

            # MMU.
            "mmu.vhdl",

            # Core.
            "core_debug.vhdl",
            "core.vhdl",
        ]
        from litex.build.xilinx import XilinxPlatform
        if isinstance(platform, XilinxPlatform) and not use_ghdl_yosys_plugin:
            sources.append("xilinx-mult.vhdl")
        else:
            sources.append("multiply.vhdl")

        sdir = get_data_mod("cpu", "microwatt").data_location
        cdir = os.path.dirname(__file__)
        # Convert VHDL to Verilog through GHDL/Yosys.
        if use_ghdl_yosys_plugin:
            from litex.build import tools
            import subprocess
            ys = []
            ys.append(
                "ghdl --ieee=synopsys -fexplicit -frelaxed-rules --std=08 \\")
            for source in sources:
                ys.append(os.path.join(sdir, source) + " \\")
            ys.append(
                os.path.join(os.path.dirname(__file__),
                             "microwatt_wrapper.vhdl") + " \\")
            ys.append("-e microwatt_wrapper")
            ys.append("chformal -assert -remove")
            ys.append("write_verilog {}".format(
                os.path.join(cdir, "microwatt.v")))
            tools.write_to_file(os.path.join(cdir, "microwatt.ys"),
                                "\n".join(ys))
            if subprocess.call([
                    "yosys", "-q", "-m", "ghdl",
                    os.path.join(cdir, "microwatt.ys")
            ]):
                raise OSError(
                    "Unable to convert Microwatt CPU to verilog, please check your GHDL-Yosys-plugin install"
                )
            platform.add_source(os.path.join(cdir, "microwatt.v"))
        # Direct use of VHDL sources.
        else:
            platform.add_sources(sdir, *sources)
            platform.add_source(
                os.path.join(os.path.dirname(__file__),
                             "microwatt_wrapper.vhdl"))
Exemplo n.º 49
0
    def _generate_makefile(self, platform, build_name):
        Var = _MakefileGenerator.Var
        Rule = _MakefileGenerator.Rule

        makefile = _MakefileGenerator([
            "# Autogenerated by LiteX / git: " +
            tools.get_litex_git_revision() + "\n",
            Var("TOP", build_name),
            Var("PARTNAME", self._partname),
            Var("DEVICE", self.symbiflow_device),
            Var("BITSTREAM_DEVICE", self.bitstream_device),
            "",
            Var("VERILOG", [
                f for f, language, _ in platform.sources
                if language in ["verilog", "system_verilog"]
            ]),
            Var("MEM_INIT",
                [f"{name}"
                 for name in os.listdir() if name.endswith(".init")]),
            Var("SDC", f"{build_name}.sdc"),
            Var("XDC", f"{build_name}.xdc"),
            Var("ARTIFACTS", [
                "$(TOP).eblif", "$(TOP).frames", "$(TOP).ioplace",
                "$(TOP).net", "$(TOP).place", "$(TOP).route", "$(TOP)_synth.*",
                "*.bit", "*.fasm", "*.json", "*.log", "*.rpt",
                "constraints.place"
            ]),
            Rule("all", ["$(TOP).bit"], phony=True),
            Rule(
                "$(TOP).eblif", ["$(VERILOG)", "$(MEM_INIT)", "$(XDC)"],
                commands=[
                    "symbiflow_synth -t $(TOP) -v $(VERILOG) -d $(BITSTREAM_DEVICE) -p $(PARTNAME) -x $(XDC) > /dev/null"
                ]),
            Rule(
                "$(TOP).net", ["$(TOP).eblif", "$(SDC)"],
                commands=[
                    "symbiflow_pack -e $(TOP).eblif -d $(DEVICE) -s $(SDC) > /dev/null"
                ]),
            Rule(
                "$(TOP).place", ["$(TOP).net"],
                commands=[
                    "symbiflow_place -e $(TOP).eblif -d $(DEVICE) -n $(TOP).net -P $(PARTNAME) -s $(SDC) > /dev/null"
                ]),
            Rule(
                "$(TOP).route", ["$(TOP).place"],
                commands=[
                    "symbiflow_route -e $(TOP).eblif -d $(DEVICE) -s $(SDC) > /dev/null"
                ]),
            Rule(
                "$(TOP).fasm", ["$(TOP).route"],
                commands=[
                    "symbiflow_write_fasm -e $(TOP).eblif -d $(DEVICE) > /dev/null"
                ]),
            Rule(
                "$(TOP).bit", ["$(TOP).fasm"],
                commands=[
                    "symbiflow_write_bitstream -d $(BITSTREAM_DEVICE) -f $(TOP).fasm -p $(PARTNAME) -b $(TOP).bit > /dev/null"
                ]),
            Rule("clean", phony=True, commands=["rm -f $(ARTIFACTS)"]),
        ])

        tools.write_to_file("Makefile", makefile.generate())
Exemplo n.º 50
0
Arquivo: vivado.py Projeto: ret/litex
    def _build_tcl(self, platform, build_name, synth_mode, enable_xpm):
        assert synth_mode in ["vivado", "yosys"]
        tcl = []

        # Create project
        tcl.append("\n# Create Project\n")
        tcl.append("create_project -force -name {} -part {}".format(
            build_name, platform.device))
        tcl.append("set_msg_config -id {Common 17-55} -new_severity {Warning}")

        # Enable Xilinx Parameterized Macros
        if enable_xpm:
            tcl.append("\n# Enable Xilinx Parameterized Macros\n")
            tcl.append(
                "set_property XPM_LIBRARIES {XPM_CDC XPM_MEMORY} [current_project]"
            )

        # Add sources (when Vivado used for synthesis)
        if synth_mode == "vivado":
            tcl.append("\n# Add Sources\n")
            # "-include_dirs {}" crashes Vivado 2016.4
            for filename, language, library in platform.sources:
                filename_tcl = "{" + filename + "}"
                if (language == "systemverilog"):
                    tcl.append("read_verilog -sv " + filename_tcl)
                elif (language == "verilog"):
                    tcl.append("read_verilog " + filename_tcl)
                elif (language == "vhdl"):
                    tcl.append("read_vhdl -vhdl2008 " + filename_tcl)
                    tcl.append("set_property library {} [get_files {}]".format(
                        library, filename_tcl))
                else:
                    tcl.append("add_files " + filename_tcl)

        # Add EDIFs
        tcl.append("\n# Add EDIFs\n")
        for filename in platform.edifs:
            filename_tcl = "{" + filename + "}"
            tcl.append("read_edif " + filename_tcl)

        # Add IPs
        tcl.append("\n# Add IPs\n")
        for filename in platform.ips:
            filename_tcl = "{" + filename + "}"
            ip = os.path.splitext(os.path.basename(filename))[0]
            tcl.append("read_ip " + filename_tcl)
            tcl.append("upgrade_ip [get_ips {}]".format(ip))
            tcl.append("generate_target all [get_ips {}]".format(ip))
            tcl.append("synth_ip [get_ips {}] -force".format(ip))
            tcl.append("get_files -all -of_objects [get_files {}]".format(
                filename_tcl))

        # Add constraints
        tcl.append("\n# Add constraints\n")
        tcl.append("read_xdc {}.xdc".format(build_name))

        # Add pre-synthesis commands
        tcl.append("\n# Add pre-synthesis commands\n")
        tcl.extend(
            c.format(build_name=build_name)
            for c in self.pre_synthesis_commands)

        # Synthesis
        if synth_mode == "vivado":
            tcl.append("\n# Synthesis\n")
            synth_cmd = "synth_design -directive {} -top {} -part {}".format(
                self.vivado_synth_directive, build_name, platform.device)
            if platform.verilog_include_paths:
                synth_cmd += " -include_dirs {{{}}}".format(" ".join(
                    platform.verilog_include_paths))
            tcl.append(synth_cmd)
        elif synth_mode == "yosys":
            tcl.append("\n# Read Yosys EDIF\n")
            tcl.append("read_edif {}.edif".format(build_name))
            tcl.append("link_design -top {} -part {}".format(
                build_name, platform.device))
        else:
            raise OSError("Unknown synthesis mode! {}".format(synth_mode))
        tcl.append("\n# Synthesis report\n")
        tcl.append("report_timing_summary -file {}_timing_synth.rpt".format(
            build_name))
        tcl.append(
            "report_utilization -hierarchical -file {}_utilization_hierarchical_synth.rpt"
            .format(build_name))
        tcl.append("report_utilization -file {}_utilization_synth.rpt".format(
            build_name))

        # Optimize
        tcl.append("\n# Optimize design\n")
        tcl.append("opt_design -directive {}".format(self.opt_directive))

        # Incremental implementation
        if self.incremental_implementation:
            tcl.append("\n# Read design checkpoint\n")
            tcl.append(
                "read_checkpoint -incremental {}_route.dcp".format(build_name))

        # Add pre-placement commands
        tcl.append("\n# Add pre-placement commands\n")
        tcl.extend(
            c.format(build_name=build_name)
            for c in self.pre_placement_commands)

        # Placement
        tcl.append("\n# Placement\n")
        tcl.append("place_design -directive {}".format(
            self.vivado_place_directive))
        if self.vivado_post_place_phys_opt_directive:
            tcl.append("phys_opt_design -directive {}".format(
                self.vivado_post_place_phys_opt_directive))
        tcl.append("\n# Placement report\n")
        tcl.append(
            "report_utilization -hierarchical -file {}_utilization_hierarchical_place.rpt"
            .format(build_name))
        tcl.append("report_utilization -file {}_utilization_place.rpt".format(
            build_name))
        tcl.append("report_io -file {}_io.rpt".format(build_name))
        tcl.append(
            "report_control_sets -verbose -file {}_control_sets.rpt".format(
                build_name))
        tcl.append(
            "report_clock_utilization -file {}_clock_utilization.rpt".format(
                build_name))

        # Add pre-routing commands
        tcl.append("\n# Add pre-routing commands\n")
        tcl.extend(
            c.format(build_name=build_name) for c in self.pre_routing_commands)

        # Routing
        tcl.append("\n# Routing\n")
        tcl.append("route_design -directive {}".format(
            self.vivado_route_directive))
        tcl.append("phys_opt_design -directive {}".format(
            self.vivado_post_route_phys_opt_directive))
        tcl.append("write_checkpoint -force {}_route.dcp".format(build_name))
        tcl.append("\n# Routing report\n")
        tcl.append("report_timing_summary -no_header -no_detailed_paths")
        tcl.append(
            "report_route_status -file {}_route_status.rpt".format(build_name))
        tcl.append("report_drc -file {}_drc.rpt".format(build_name))
        tcl.append(
            "report_timing_summary -datasheet -max_paths 10 -file {}_timing.rpt"
            .format(build_name))
        tcl.append("report_power -file {}_power.rpt".format(build_name))
        for bitstream_command in self.bitstream_commands:
            tcl.append(bitstream_command.format(build_name=build_name))

        # Bitstream generation
        tcl.append("\n# Bitstream generation\n")
        tcl.append("write_bitstream -force {}.bit ".format(build_name))
        for additional_command in self.additional_commands:
            tcl.append(additional_command.format(build_name=build_name))

        # Quit
        tcl.append("\n# End\n")
        tcl.append("quit")
        tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 51
0
 def _build_batch(self, platform, sources, edifs, build_name):
     tcl = []
     tcl.append("create_project -force -name {} -part {}".format(
         build_name, platform.device))
     for filename, language, library in sources:
         filename_tcl = "{" + filename + "}"
         tcl.append("add_files " + filename_tcl)
         tcl.append("set_property library {} [get_files {}]".format(
             library, filename_tcl))
     for filename in edifs:
         filename_tcl = "{" + filename + "}"
         tcl.append("read_edif " + filename_tcl)
     tcl.append("read_xdc {}.xdc".format(build_name))
     tcl.extend(
         c.format(build_name=build_name)
         for c in self.pre_synthesis_commands)
     # "-include_dirs {}" crashes Vivado 2016.4
     if platform.verilog_include_paths:
         tcl.append(
             "synth_design -top {} -part {} -include_dirs {{{}}}".format(
                 build_name, platform.device,
                 " ".join(platform.verilog_include_paths)))
     else:
         tcl.append("synth_design -top {} -part {}".format(
             build_name, platform.device))
     tcl.append("report_timing_summary -file {}_timing_synth.rpt".format(
         build_name))
     tcl.append(
         "report_utilization -hierarchical -file {}_utilization_hierarchical_synth.rpt"
         .format(build_name))
     tcl.append("report_utilization -file {}_utilization_synth.rpt".format(
         build_name))
     tcl.append("opt_design")
     tcl.append("place_design")
     if self.with_phys_opt:
         tcl.append("phys_opt_design -directive AddRetime")
     tcl.append(
         "report_utilization -hierarchical -file {}_utilization_hierarchical_place.rpt"
         .format(build_name))
     tcl.append("report_utilization -file {}_utilization_place.rpt".format(
         build_name))
     tcl.append("report_io -file {}_io.rpt".format(build_name))
     tcl.append(
         "report_control_sets -verbose -file {}_control_sets.rpt".format(
             build_name))
     tcl.append(
         "report_clock_utilization -file {}_clock_utilization.rpt".format(
             build_name))
     tcl.append("route_design")
     tcl.append("write_checkpoint -force {}_route.dcp".format(build_name))
     tcl.append(
         "report_route_status -file {}_route_status.rpt".format(build_name))
     tcl.append("report_drc -file {}_drc.rpt".format(build_name))
     tcl.append(
         "report_timing_summary -datasheet -max_paths 10 -file {}_timing.rpt"
         .format(build_name))
     tcl.append("report_power -file {}_power.rpt".format(build_name))
     for bitstream_command in self.bitstream_commands:
         tcl.append(bitstream_command.format(build_name=build_name))
     tcl.append("write_bitstream -force {}.bit ".format(build_name))
     for additional_command in self.additional_commands:
         tcl.append(additional_command.format(build_name=build_name))
     tcl.append("quit")
     tools.write_to_file(build_name + ".tcl", "\n".join(tcl))
Exemplo n.º 52
0
        analyzer_groups = {}

        # Analyzer group
        analyzer_groups[0] = [
            self.serdes.d0.signals,
            self.serdes.d1.signals,
            self.serdes.d2.signals,
            self.serdes.d3.signals,
        ]

        # analyzer
        self.submodules.analyzer = LiteScopeAnalyzer(analyzer_groups, 512)

    def do_exit(self, vns):
        self.analyzer.export_csv(vns, "test/analyzer.csv")


platform = arty.Platform()

soc = LiteScopeSoC(platform)
vns = platform.build(soc, run="no-compile" not in sys.argv[1:])

#
# Create csr and analyzer files
#
soc.finalize()

csr_csv = export.get_csr_csv(soc.csr_regions, soc.constants)
write_to_file("test/csr.csv", csr_csv)
soc.do_exit(vns)
Exemplo n.º 53
0
    def _generate_includes(self):
        cpu_type = self.soc.cpu_type
        memory_regions = self.soc.get_memory_regions()
        flash_boot_address = getattr(self.soc, "flash_boot_address", None)
        csr_regions = self.soc.get_csr_regions()
        constants = self.soc.get_constants()
        if isinstance(self.soc, soc_sdram.SoCSDRAM) and self.soc._sdram_phy:
            sdram_phy_settings = self.soc._sdram_phy[0].settings
        else:
            sdram_phy_settings = None

        buildinc_dir = os.path.join(self.output_dir, "software", "include")
        generated_dir = os.path.join(buildinc_dir, "generated")
        os.makedirs(generated_dir, exist_ok=True)

        variables_contents = []

        def define(k, v):
            variables_contents.append("{}={}\n".format(k, _makefile_escape(v)))

        for k, v in cpu_interface.get_cpu_mak(cpu_type):
            define(k, v)
        define("SOC_DIRECTORY", soc_directory)
        variables_contents.append("export BUILDINC_DIRECTORY\n")
        define("BUILDINC_DIRECTORY", buildinc_dir)
        for name, src_dir in self.software_packages:
            define(name.upper() + "_DIRECTORY", src_dir)
        write_to_file(os.path.join(generated_dir, "variables.mak"),
                      "".join(variables_contents))

        write_to_file(os.path.join(generated_dir, "output_format.ld"),
                      cpu_interface.get_linker_output_format(cpu_type))
        write_to_file(os.path.join(generated_dir, "regions.ld"),
                      cpu_interface.get_linker_regions(memory_regions))

        write_to_file(
            os.path.join(generated_dir, "mem.h"),
            cpu_interface.get_mem_header(memory_regions, flash_boot_address))
        write_to_file(os.path.join(generated_dir, "csr.h"),
                      cpu_interface.get_csr_header(csr_regions, constants))

        if sdram_phy_settings is not None:
            write_to_file(os.path.join(generated_dir, "sdram_phy.h"),
                          sdram_init.get_sdram_phy_header(sdram_phy_settings))
Exemplo n.º 54
0
    def add_sources(platform, use_ghdl_yosys_plugin=False):
        sources = [
            # Common / Types / Helpers
            "decode_types.vhdl",
            "wishbone_types.vhdl",
            "utils.vhdl",
            "common.vhdl",
            "helpers.vhdl",

            # XICS controller
            "xics.vhdl",
        ]
        sdir = get_data_mod("cpu", "microwatt").data_location
        cdir = os.path.dirname(__file__)
        if use_ghdl_yosys_plugin:
            from litex.build import tools
            import subprocess

            # ICP
            ys = []
            ys.append(
                "ghdl --ieee=synopsys -fexplicit -frelaxed-rules --std=08 \\")
            for source in sources:
                ys.append(os.path.join(sdir, source) + " \\")
            ys.append(
                os.path.join(os.path.dirname(__file__), "xics_wrapper.vhdl") +
                " \\")
            ys.append("-e xics_icp_wrapper")
            ys.append("chformal -assert -remove")
            ys.append("write_verilog {}".format(
                os.path.join(cdir, "xics_icp.v")))
            tools.write_to_file(os.path.join(cdir, "xics_icp.ys"),
                                "\n".join(ys))
            if subprocess.call([
                    "yosys", "-q", "-m", "ghdl",
                    os.path.join(cdir, "xics_icp.ys")
            ]):
                raise OSError(
                    "Unable to convert Microwatt XICS ICP controller to verilog, please check your GHDL-Yosys-plugin install"
                )
            platform.add_source(os.path.join(cdir, "xics_icp.v"))

            # ICS
            ys = []
            ys.append(
                "ghdl --ieee=synopsys -fexplicit -frelaxed-rules --std=08 \\")
            for source in sources:
                ys.append(os.path.join(sdir, source) + " \\")
            ys.append(
                os.path.join(os.path.dirname(__file__), "xics_wrapper.vhdl") +
                " \\")
            ys.append("-e xics_ics_wrapper")
            ys.append("chformal -assert -remove")
            ys.append("write_verilog {}".format(
                os.path.join(cdir, "xics_ics.v")))
            tools.write_to_file(os.path.join(cdir, "xics_ics.ys"),
                                "\n".join(ys))
            if subprocess.call([
                    "yosys", "-q", "-m", "ghdl",
                    os.path.join(cdir, "xics_ics.ys")
            ]):
                raise OSError(
                    "Unable to convert Microwatt XICS ICP controller to verilog, please check your GHDL-Yosys-plugin install"
                )
            platform.add_source(os.path.join(cdir, "xics_ics.v"))
        else:
            platform.add_sources(sdir, *sources)
            platform.add_source(
                os.path.join(os.path.dirname(__file__), "xics_wrapper.vhdl"))
Exemplo n.º 55
0
 def build_io_contraints(self):
     # Generate design constraints
     tools.write_to_file(self._build_name + ".xdc", _build_xdc(self.named_sc, self.named_pc))
     return (self._build_name + ".xdc", "XDC")
Exemplo n.º 56
0
def compare_with_reference(content, filename):
    write_to_file(filename, content)
    r = filecmp.cmp(filename, os.path.join("test", "reference", filename))
    os.remove(filename)
    return r
Exemplo n.º 57
0
    def stream(self, port=20000):
        """
        Create a Telnet server to stream data to/from the internal JTAG TAP of the FPGA

        Wire format: 10 bits LSB first
        Host to Target:
          - TX ready : bit 0
          - RX data: : bit 1 to 8
          - RX valid : bit 9

        Target to Host:
          - RX ready : bit 0
          - TX data  : bit 1 to 8
          - TX valid : bit 9
        """
        cfg = """
proc jtagstream_poll {tap tx n} {
    set m [string length $tx]
    set n [expr ($m>$n)?$m:$n]
    set txi [lrepeat $n {10 0x001}]
    set i 0
    foreach txj [split $tx ""] {
        lset txi $i 1 [format 0x%4.4X [expr 0x201 | ([scan $txj %c] << 1)]]
        incr i
    }
    set txi [concat {*}$txi]
    set rxi [split [drscan $tap {*}$txi -endstate DRPAUSE] " "]
    #echo $txi:$rxi
    set rx ""
    set writable 1
    foreach {rxj} $rxi {
        set readable [expr 0x$rxj & 0x200]
        set writable [expr 0x$rxj & $writable]
        if {$readable} {
            append rx [format %c [expr (0x$rxj >> 1) & 0xff]]
        }
    }
    return [list $rx $readable $writable]
}

proc jtagstream_drain {tap tx chunk_rx max_rx} {
    lassign [jtagstream_poll $tap $tx $chunk_rx] rx readable writable
    while {[expr $writable && ($readable > 0) && ([string length $rx] < $max_rx)]} {
        lassign [jtagstream_poll $tap "" $chunk_rx] rxi readable writable
        append rx $rxi
    }
    #if {!$writable} {
    #    echo "write overflow"
    #}
    return $rx
}

proc jtagstream_rxtx {tap client is_poll} {
    if {![$client eof]} {
        if {!$is_poll} {
            set tx [$client gets]
        } else {
            set tx ""
        }
        set rx [jtagstream_drain $tap $tx 64 4096]
        if {[string length $rx]} {
            $client puts -nonewline $rx
        }
        if {$is_poll} {
            after 1 [list jtagstream_rxtx $tap $client 1]
        }
    } else {
        $client readable {}
        $client onexception {}
        $client close
    }
}

proc jtagstream_client {tap sock} {
    set client [$sock accept]
    fconfigure $client -buffering none
    $client readable [list jtagstream_rxtx $tap $client 0]
    $client onexception [list $client close]
    after 1 [list jtagstream_rxtx $tap $client 1]
}

proc jtagstream_exit {sock} {
    stdin readable {}
    $sock readable {}
}

proc jtagstream_serve {tap port} {
    set sock [socket stream.server $port]
    $sock readable [list jtagstream_client $tap $sock]
    stdin readable [list jtagstream_exit $sock]
    vwait forever
    $sock close
}
"""
        write_to_file("stream.cfg", cfg)
        script = "; ".join([
            "init",
            "irscan $_CHIPNAME.tap $_USER1",
            "jtagstream_serve $_CHIPNAME.tap {:d}".format(port),
            "exit",
        ])
        config = self.find_config()
        self.call(["openocd", "-f", config, "-f", "stream.cfg", "-c", script])
Exemplo n.º 58
0
    def add_sources(platform, use_ghdl_yosys_plugin=False):
        sources = [
            # Common / Types / Helpers
            "decode_types.vhdl",
            "wishbone_types.vhdl",
            "utils.vhdl",
            "common.vhdl",
            "helpers.vhdl",

            # Fetch
            "fetch1.vhdl",
            "fetch2.vhdl",

            # Instruction/Data Cache
            "cache_ram.vhdl",
            "plru.vhdl",
            "dcache.vhdl",
            "icache.vhdl",

            # Decode
            "insn_helpers.vhdl",
            "decode1.vhdl",
            "gpr_hazard.vhdl",
            "cr_hazard.vhdl",
            "control.vhdl",
            "decode2.vhdl",

            # Register/CR File
            "register_file.vhdl",
            "crhelpers.vhdl",
            "cr_file.vhdl",

            # Execute
            "ppc_fx_insns.vhdl",
            "logical.vhdl",
            "rotator.vhdl",
            "countzero.vhdl",
            "execute1.vhdl",

            # Load/Store
            "loadstore1.vhdl",

            # Multiply/Divide
            "multiply.vhdl",
            "divider.vhdl",

            # Writeback
            "writeback.vhdl",

            # MMU
            "mmu.vhdl",

            # Core
            "core_debug.vhdl",
            "core.vhdl",
        ]
        sdir = get_data_mod("cpu", "microwatt").data_location
        cdir = os.path.dirname(__file__)
        if use_ghdl_yosys_plugin:
            from litex.build import tools
            import subprocess
            ys = []
            ys.append(
                "ghdl --ieee=synopsys -fexplicit -frelaxed-rules --std=08 \\")
            for source in sources:
                ys.append(os.path.join(sdir, source) + " \\")
            ys.append(
                os.path.join(os.path.dirname(__file__),
                             "microwatt_wrapper.vhdl") + " \\")
            ys.append("-e microwatt_wrapper")
            ys.append("chformal -assert -remove")
            ys.append("write_verilog {}".format(
                os.path.join(cdir, "microwatt.v")))
            tools.write_to_file(os.path.join(cdir, "microwatt.ys"),
                                "\n".join(ys))
            if subprocess.call([
                    "yosys", "-q", "-m", "ghdl",
                    os.path.join(cdir, "microwatt.ys")
            ]):
                raise OSError(
                    "Unable to convert Microwatt CPU to verilog, please check your GHDL-Yosys-plugin install"
                )
            platform.add_source(os.path.join(cdir, "microwatt.v"))
        else:
            platform.add_sources(sdir, *sources)
            platform.add_source(
                os.path.join(os.path.dirname(__file__),
                             "microwatt_wrapper.vhdl"))
Exemplo n.º 59
0
 def _generate_mem_region_map(self):
     if self.memory_x is not None:
         memory_x_dir = os.path.dirname(os.path.realpath(self.memory_x))
         os.makedirs(memory_x_dir, exist_ok=True)
         write_to_file(self.memory_x, export.get_memory_x(self.soc))
Exemplo n.º 60
0
    def _generate_includes(self):
        cpu_type = self.soc.cpu_type
        memory_regions = self.soc.get_memory_regions()
        flash_boot_address = getattr(self.soc, "flash_boot_address", None)
        shadow_base = getattr(self.soc, "shadow_base", None)
        csr_regions = self.soc.get_csr_regions()
        constants = self.soc.get_constants()

        buildinc_dir = os.path.join(self.output_dir, "software", "include")
        generated_dir = os.path.join(buildinc_dir, "generated")
        os.makedirs(generated_dir, exist_ok=True)

        variables_contents = []
        def define(k, v):
            variables_contents.append("{}={}\n".format(k, _makefile_escape(v)))
        for k, v in cpu_interface.get_cpu_mak(self.soc.cpu):
            define(k, v)
        # Distinguish between LiteX and MiSoC.
        define("LITEX", "1")
        # Distinguish between applications running from main RAM and
        # flash for user-provided software packages.
        exec_profiles = {
            "COPY_TO_MAIN_RAM" : "0",
            "EXECUTE_IN_PLACE" : "0"
        }
        if "main_ram" in (m[0] for m in memory_regions):
            exec_profiles["COPY_TO_MAIN_RAM"] = "1"
        else:
            exec_profiles["EXECUTE_IN_PLACE"] = "1"
        for k, v in exec_profiles.items():
            define(k, v)
        define("SOC_DIRECTORY", soc_directory)
        variables_contents.append("export BUILDINC_DIRECTORY\n")
        define("BUILDINC_DIRECTORY", buildinc_dir)
        for name, src_dir in self.software_packages:
            define(name.upper() + "_DIRECTORY", src_dir)
        write_to_file(
            os.path.join(generated_dir, "variables.mak"),
            "".join(variables_contents))
        write_to_file(
            os.path.join(generated_dir, "output_format.ld"),
            cpu_interface.get_linker_output_format(self.soc.cpu))
        write_to_file(
            os.path.join(generated_dir, "regions.ld"),
            cpu_interface.get_linker_regions(memory_regions))
        write_to_file(
            os.path.join(generated_dir, "mem.h"),
            cpu_interface.get_mem_header(memory_regions, flash_boot_address, shadow_base))
        write_to_file(
            os.path.join(generated_dir, "csr.h"),
            cpu_interface.get_csr_header(csr_regions, constants))
        write_to_file(
            os.path.join(generated_dir, "git.h"),
            cpu_interface.get_git_header()
        )

        if isinstance(self.soc, soc_sdram.SoCSDRAM):
            if hasattr(self.soc, "sdram"):
                write_to_file(
                    os.path.join(generated_dir, "sdram_phy.h"),
                    sdram_init.get_sdram_phy_c_header(
                        self.soc.sdram.controller.settings.phy,
                        self.soc.sdram.controller.settings.timing))