blob: 2db8615f4ee0f05cd7873c26c27af4f359be38f4 [file] [log] [blame] [edit]
#!/usr/bin/env python3
# Copyright lowRISC contributors.
# Licensed under the Apache License, Version 2.0, see LICENSE for details.
# SPDX-License-Identifier: Apache-2.0
r"""Top Module Generator
"""
import argparse
import logging as log
import os
import random
import shutil
import sys
import tempfile
from collections import OrderedDict
from copy import deepcopy
from io import StringIO
from pathlib import Path
from typing import Dict, List, Optional, Tuple
from itertools import chain
import hjson
import tlgen
from ipgen import (IpBlockRenderer, IpConfig, IpDescriptionOnlyRenderer,
IpTemplate, TemplateRenderError)
from mako import exceptions
from mako.template import Template
from reggen import access, gen_rtl, gen_sec_cm_testplan, window
from reggen.inter_signal import InterSignal
from reggen.ip_block import IpBlock
from reggen.countermeasure import CounterMeasure
from reggen.lib import check_list
from topgen import entropy_buffer_generator as ebg
from topgen import get_hjsonobj_xbars
from topgen import intermodule as im
from topgen import lib as lib
from topgen import merge_top, search_ips, strong_random, validate_top
from topgen.c_test import TopGenCTest
from topgen.rust import TopGenRust
from topgen.clocks import Clocks
from topgen.gen_dv import gen_dv
from topgen.gen_top_docs import gen_top_docs
from topgen.merge import connect_clocks, create_alert_lpgs, extract_clocks
from topgen.resets import Resets
from topgen.top import Top
# Common header for generated files
warnhdr = """//
// ------------------- W A R N I N G: A U T O - G E N E R A T E D C O D E !! -------------------//
// PLEASE DO NOT HAND-EDIT THIS FILE. IT HAS BEEN AUTO-GENERATED WITH THE FOLLOWING COMMAND:
"""
genhdr = """// Copyright lowRISC contributors.
// Licensed under the Apache License, Version 2.0, see LICENSE for details.
// SPDX-License-Identifier: Apache-2.0
""" + warnhdr
GENCMD = ("// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson\n"
"// -o hw/top_{topname}")
SRCTREE_TOP = Path(__file__).parent.parent.resolve()
TOPGEN_TEMPLATE_PATH = Path(__file__).parent / "topgen/templates"
# Size and path to the entropy buffer.
# This buffer is generated using Mersenne Twister PRNG seeded with rnd_cnst_seed
# and deleted in the end."
# This buffer will not be created If a different one is provided by args.entropy_buffer.
# Module strong_random fetches entropy from the buffer to generate random bit-vectors
# and permutations.
BUFFER_SIZE = 20000
PATH_TO_BUFFER = "util/topgen/entropy_buffer.txt"
def ipgen_render(template_name: str, topname: str, params: Dict,
out_path: Path):
""" Render an IP template for a specific toplevel using ipgen.
The generated IP block is placed in the "ip_autogen" directory of the
toplevel.
Aborts the program execution in case of an error.
"""
module_name = params.get("module_instance_name", template_name)
instance_name = f"top_{topname}_{module_name}"
ip_template = IpTemplate.from_template_path(
SRCTREE_TOP / "hw/ip_templates" / template_name)
try:
ip_config = IpConfig(ip_template.params, instance_name, params)
except ValueError as e:
log.error(f"Unable to render IP template {template_name!r}: {str(e)}")
sys.exit(1)
try:
renderer = IpBlockRenderer(ip_template, ip_config)
renderer.render(out_path / "ip_autogen" / module_name,
overwrite_output_dir=True)
except TemplateRenderError as e:
log.error(e.verbose_str())
sys.exit(1)
def generate_top(top, name_to_block, tpl_filename, **kwargs):
top_tpl = Template(filename=tpl_filename)
try:
return top_tpl.render(top=top, name_to_block=name_to_block, **kwargs)
except: # noqa: E722
log.error(exceptions.text_error_template().render())
return ""
def generate_xbars(top, out_path):
topname = top["name"]
gencmd = ("// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson "
"-o hw/top_{topname}/\n\n".format(topname=topname))
for obj in top["xbar"]:
xbar_path = out_path / "ip/xbar_{}/data/autogen".format(obj["name"])
xbar_path.mkdir(parents=True, exist_ok=True)
xbar = tlgen.validate(obj)
xbar.ip_path = "hw/top_" + top["name"] + "/ip/{dut}"
# Generate output of crossbar with complete fields
xbar_hjson_path = xbar_path / "xbar_{}.gen.hjson".format(xbar.name)
xbar_hjson_path.write_text(genhdr + gencmd +
hjson.dumps(obj, for_json=True) + '\n')
if not tlgen.elaborate(xbar):
log.error("Elaboration failed." + repr(xbar))
try:
results = tlgen.generate(xbar, "top_" + top["name"])
except: # noqa: E722
log.error(exceptions.text_error_template().render())
ip_path = out_path / "ip/xbar_{}".format(obj["name"])
for filename, filecontent in results:
filepath = ip_path / filename
filepath.parent.mkdir(parents=True, exist_ok=True)
with filepath.open(mode="w", encoding="UTF-8") as fout:
fout.write(filecontent)
dv_path = out_path / "ip/xbar_{}/dv/autogen".format(obj["name"])
dv_path.mkdir(parents=True, exist_ok=True)
# generate testbench for xbar
tlgen.generate_tb(xbar, dv_path, "top_" + top["name"])
# Read back the comportable IP and amend to Xbar
xbar_ipfile = ip_path / ("data/autogen/xbar_%s.hjson" % obj["name"])
with xbar_ipfile.open() as fxbar:
xbar_ipobj = hjson.load(fxbar,
use_decimal=True,
object_pairs_hook=OrderedDict)
r_inter_signal_list = check_list(
xbar_ipobj.get("inter_signal_list", []),
"inter_signal_list field")
obj["inter_signal_list"] = [
InterSignal.from_raw(
"entry {} of the inter_signal_list field".format(idx + 1),
entry) for idx, entry in enumerate(r_inter_signal_list)
]
def generate_alert_handler(top, out_path):
topname = top["name"]
# default values
esc_cnt_dw = 32
accu_cnt_dw = 16
async_on = []
# leave this constant
n_classes = 4
# low power groups
n_lpg = 1
lpg_map = []
# Count number of alerts and LPGs
n_alerts = sum([x["width"] if "width" in x else 1 for x in top["alert"]])
n_lpg = len(top["alert_lpgs"])
n_lpg_width = n_lpg.bit_length()
# format used to print out indices in binary format
async_on_format = "1'b{:01b}"
lpg_idx_format = str(n_lpg_width) + "'d{:d}"
# Double check that all these values are greated than 0
if esc_cnt_dw < 1:
raise ValueError("esc_cnt_dw must be larger than 0")
if accu_cnt_dw < 1:
raise ValueError("accu_cnt_dw must be larger than 0")
if n_lpg < 1:
raise ValueError("n_lpg must be larger than 0")
if n_alerts < 1:
# set number of alerts to 1 such that the config is still valid
# that input will be tied off
n_alerts = 1
log.warning("no alerts are defined in the system")
else:
async_on = []
lpg_map = []
for alert in top["alert"]:
for k in range(alert["width"]):
async_on.append(async_on_format.format(int(alert["async"])))
lpg_map.append(lpg_idx_format.format(int(alert["lpg_idx"])))
params = {
"n_alerts": n_alerts,
"esc_cnt_dw": esc_cnt_dw,
"accu_cnt_dw": accu_cnt_dw,
"async_on": async_on,
"n_classes": n_classes,
"n_lpg": n_lpg,
"lpg_map": lpg_map,
}
ipgen_render("alert_handler", topname, params, out_path)
def generate_plic(top, out_path):
topname = top["name"]
params = {}
# Count number of interrupts
# Interrupt source 0 is tied to 0 to conform RISC-V PLIC spec.
# So, total number of interrupts are the number of entries in the list + 1
params["src"] = sum(
[x["width"] if "width" in x else 1 for x in top["interrupt"]]) + 1
# Target and priority: Currently fixed
params["target"] = int(top["num_cores"], 0) if "num_cores" in top else 1
params["prio"] = 3
ipgen_render("rv_plic", topname, params, out_path)
# TODO: For generated IPs that are generated legacy style (i.e., without IPgen)
# we have to search both the source and destination RTL directories, since not
# all files are copied over. This is a workaround which can be removed once
# all generated IPs have transitioned to IPgen.
def generate_regfile_from_path(hjson_path: Path,
generated_rtl_path: Path,
original_rtl_path: Path = None):
"""Generate RTL register file from path and check countermeasure labels"""
obj = IpBlock.from_path(str(hjson_path), [])
# If this block has countermeasures, we grep for RTL annotations in
# all .sv implementation files and check whether they match up
# with what is defined inside the Hjson.
sv_files = generated_rtl_path.glob("*.sv")
if original_rtl_path is not None:
sv_files = chain(sv_files, original_rtl_path.glob("*.sv"))
rtl_names = CounterMeasure.search_rtl_files(sv_files)
obj.check_cm_annotations(rtl_names, str(hjson_path))
gen_rtl.gen_rtl(obj, str(generated_rtl_path))
if gen_sec_cm_testplan.gen_sec_cm_testplan(obj, hjson_path.parent):
sys.exit(1)
def generate_pinmux(top, out_path):
topname = top["name"]
pinmux = top["pinmux"]
# Generation without pinmux and pinout configuration is not supported.
assert "pinmux" in top
assert "pinout" in top
# Get number of wakeup detectors
if "num_wkup_detect" in pinmux:
num_wkup_detect = pinmux["num_wkup_detect"]
else:
num_wkup_detect = 1
if num_wkup_detect <= 0:
# TODO: add support for no wakeup counter case
log.error("Topgen does currently not support generation of a top " +
"without DIOs.")
return
if "wkup_cnt_width" in pinmux:
wkup_cnt_width = pinmux["wkup_cnt_width"]
else:
wkup_cnt_width = 8
if wkup_cnt_width <= 1:
log.error("Wakeup counter width must be greater equal 2.")
return
# MIO Pads
n_mio_pads = pinmux["io_counts"]["muxed"]["pads"]
# Total inputs/outputs
# Reuse the counts from the merge phase
n_mio_periph_in = (pinmux["io_counts"]["muxed"]["inouts"] +
pinmux["io_counts"]["muxed"]["inputs"])
n_mio_periph_out = (pinmux["io_counts"]["muxed"]["inouts"] +
pinmux["io_counts"]["muxed"]["outputs"])
n_dio_periph_in = (pinmux["io_counts"]["dedicated"]["inouts"] +
pinmux["io_counts"]["dedicated"]["inputs"])
n_dio_periph_out = (pinmux["io_counts"]["dedicated"]["inouts"] +
pinmux["io_counts"]["dedicated"]["outputs"])
n_dio_pads = (pinmux["io_counts"]["dedicated"]["inouts"] +
pinmux["io_counts"]["dedicated"]["inputs"] +
pinmux["io_counts"]["dedicated"]["outputs"])
# TODO: derive this value
attr_dw = 13
# Generation with zero MIO/DIO pads is currently not supported.
assert (n_mio_pads > 0)
assert (n_dio_pads > 0)
log.info("Generating pinmux with following info from hjson:")
log.info("attr_dw: %d" % attr_dw)
log.info("num_wkup_detect: %d" % num_wkup_detect)
log.info("wkup_cnt_width: %d" % wkup_cnt_width)
log.info("n_mio_periph_in: %d" % n_mio_periph_in)
log.info("n_mio_periph_out: %d" % n_mio_periph_out)
log.info("n_dio_periph_in: %d" % n_dio_periph_in)
log.info("n_dio_periph_out: %d" % n_dio_periph_out)
log.info("n_dio_pads: %d" % n_dio_pads)
# Target path
# rtl: pinmux_reg_pkg.sv & pinmux_reg_top.sv
# data: pinmux.hjson
rtl_path = out_path / "ip/pinmux/rtl/autogen"
rtl_path.mkdir(parents=True, exist_ok=True)
data_path = out_path / "ip/pinmux/data/autogen"
data_path.mkdir(parents=True, exist_ok=True)
# Template path
tpl_path = Path(
__file__).resolve().parent / "../hw/ip/pinmux/data/pinmux.hjson.tpl"
original_rtl_path = Path(
__file__).resolve().parent / "../hw/ip/pinmux/rtl"
# Generate register package and RTLs
gencmd = ("// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson "
"-o hw/top_{topname}/\n\n".format(topname=topname))
hjson_gen_path = data_path / "pinmux.hjson"
out = StringIO()
with tpl_path.open(mode="r", encoding="UTF-8") as fin:
hjson_tpl = Template(fin.read())
try:
out = hjson_tpl.render(
n_mio_periph_in=n_mio_periph_in,
n_mio_periph_out=n_mio_periph_out,
n_mio_pads=n_mio_pads,
# each DIO has in, out and oe wires
# some of these have to be tied off in the
# top, depending on the type.
n_dio_periph_in=n_dio_pads,
n_dio_periph_out=n_dio_pads,
n_dio_pads=n_dio_pads,
attr_dw=attr_dw,
n_wkup_detect=num_wkup_detect,
wkup_cnt_width=wkup_cnt_width)
except: # noqa: E722
log.error(exceptions.text_error_template().render())
log.info("PINMUX HJSON: %s" % out)
if out == "":
log.error("Cannot generate pinmux HJSON")
return
with hjson_gen_path.open(mode="w", encoding="UTF-8") as fout:
fout.write(genhdr + gencmd + out)
# Generate reg file
generate_regfile_from_path(hjson_gen_path, rtl_path, original_rtl_path)
def generate_clkmgr(top, cfg_path, out_path):
# Target paths
rtl_path = out_path / "ip/clkmgr/rtl/autogen"
rtl_path.mkdir(parents=True, exist_ok=True)
data_path = out_path / "ip/clkmgr/data/autogen"
data_path.mkdir(parents=True, exist_ok=True)
# Template paths
hjson_tpl = cfg_path / "../ip/clkmgr/data/clkmgr.hjson.tpl"
rtl_tpl = cfg_path / "../ip/clkmgr/data/clkmgr.sv.tpl"
pkg_tpl = cfg_path / "../ip/clkmgr/data/clkmgr_pkg.sv.tpl"
original_rtl_path = cfg_path / "../ip/clkmgr/rtl"
hjson_out = data_path / "clkmgr.hjson"
rtl_out = rtl_path / "clkmgr.sv"
pkg_out = rtl_path / "clkmgr_pkg.sv"
tpls = [hjson_tpl, rtl_tpl, pkg_tpl]
outputs = [hjson_out, rtl_out, pkg_out]
names = ["clkmgr.hjson", "clkmgr.sv", "clkmgr_pkg.sv"]
clocks = top["clocks"]
assert isinstance(clocks, Clocks)
typed_clocks = clocks.typed_clocks()
hint_names = typed_clocks.hint_names()
for idx, tpl in enumerate(tpls):
out = ""
with tpl.open(mode="r", encoding="UTF-8") as fin:
tpl = Template(fin.read())
try:
out = tpl.render(cfg=top,
clocks=clocks,
typed_clocks=typed_clocks,
hint_names=hint_names)
except: # noqa: E722
log.error(exceptions.text_error_template().render())
if out == "":
log.error("Cannot generate {}".format(names[idx]))
return
with outputs[idx].open(mode="w", encoding="UTF-8") as fout:
fout.write(genhdr + out)
# Generate reg files
generate_regfile_from_path(hjson_out, rtl_path, original_rtl_path)
# generate pwrmgr
def generate_pwrmgr(top, out_path):
log.info("Generating pwrmgr")
# Count number of wakeups
n_wkups = len(top["wakeups"])
log.info("Found {} wakeup signals".format(n_wkups))
# Count number of reset requests
n_rstreqs = len(top["reset_requests"]["peripheral"])
log.info("Found {} reset request signals".format(n_rstreqs))
if n_wkups < 1:
n_wkups = 1
log.warning(
"The design has no wakeup sources. Low power not supported.")
if n_rstreqs < 1:
n_rstreqs = 1
log.warning("The design has no reset request sources. "
"Reset requests are not supported.")
# Define target path
rtl_path = out_path / "ip/pwrmgr/rtl/autogen"
rtl_path.mkdir(parents=True, exist_ok=True)
doc_path = out_path / "ip/pwrmgr/data/autogen"
doc_path.mkdir(parents=True, exist_ok=True)
# So, read template files from ip directory.
tpl_path = Path(__file__).resolve().parent / "../hw/ip/pwrmgr/data"
hjson_tpl_path = tpl_path / "pwrmgr.hjson.tpl"
original_rtl_path = Path(__file__).resolve().parent / "../hw/ip/pwrmgr/rtl"
# Render and write out hjson
out = StringIO()
with hjson_tpl_path.open(mode="r", encoding="UTF-8") as fin:
hjson_tpl = Template(fin.read())
try:
out = hjson_tpl.render(NumWkups=n_wkups,
Wkups=top["wakeups"],
rst_reqs=top["reset_requests"],
NumRstReqs=n_rstreqs)
except: # noqa: E722
log.error(exceptions.text_error_template().render())
log.info("pwrmgr hjson: %s" % out)
if out == "":
log.error("Cannot generate pwrmgr config file")
return
hjson_path = doc_path / "pwrmgr.hjson"
with hjson_path.open(mode="w", encoding="UTF-8") as fout:
fout.write(genhdr + out)
# Generate reg files
generate_regfile_from_path(hjson_path, rtl_path, original_rtl_path)
def get_rst_ni(top):
rstmgrs = [m for m in top['module'] if m['type'] == 'rstmgr']
return rstmgrs[0]["reset_connections"]
# generate rstmgr
def generate_rstmgr(topcfg, out_path):
log.info("Generating rstmgr")
# Define target path
rtl_path = out_path / "ip/rstmgr/rtl/autogen"
rtl_path.mkdir(parents=True, exist_ok=True)
doc_path = out_path / "ip/rstmgr/data/autogen"
doc_path.mkdir(parents=True, exist_ok=True)
tpl_path = Path(__file__).resolve().parent / "../hw/ip/rstmgr/data"
original_rtl_path = Path(__file__).resolve().parent / "../hw/ip/rstmgr/rtl"
# Read template files from ip directory.
tpls = []
outputs = []
names = ["rstmgr.hjson", "rstmgr.sv", "rstmgr_pkg.sv"]
for x in names:
tpls.append(tpl_path / Path(x + ".tpl"))
if "hjson" in x:
outputs.append(doc_path / Path(x))
else:
outputs.append(rtl_path / Path(x))
# Parameters needed for generation
reset_obj = topcfg["resets"]
# The original resets dict is transformed to the reset class
assert isinstance(reset_obj, Resets)
# unique clocks
clks = reset_obj.get_clocks()
# resets sent to reset struct
output_rsts = reset_obj.get_top_resets()
# sw controlled resets
sw_rsts = reset_obj.get_sw_resets()
# rst_ni
rst_ni = get_rst_ni(topcfg)
# leaf resets
leaf_rsts = reset_obj.get_generated_resets()
# Number of reset requests
n_rstreqs = len(topcfg["reset_requests"]["peripheral"])
# Generate templated files
for idx, t in enumerate(tpls):
out = StringIO()
with t.open(mode="r", encoding="UTF-8") as fin:
tpl = Template(fin.read())
try:
out = tpl.render(clks=clks,
reqs=topcfg["reset_requests"],
power_domains=topcfg["power"]["domains"],
num_rstreqs=n_rstreqs,
sw_rsts=sw_rsts,
output_rsts=output_rsts,
leaf_rsts=leaf_rsts,
rst_ni = rst_ni['rst_ni']['name'],
export_rsts=topcfg["exported_rsts"],
reset_obj=topcfg["resets"])
except: # noqa: E722
log.error(exceptions.text_error_template().render())
if out == "":
log.error("Cannot generate {}".format(names[idx]))
return
with outputs[idx].open(mode="w", encoding="UTF-8") as fout:
fout.write(genhdr + out)
# Generate reg files
hjson_path = outputs[0]
generate_regfile_from_path(hjson_path, rtl_path, original_rtl_path)
# generate flash
def generate_flash(topcfg, out_path):
log.info("Generating flash")
# Define target path
rtl_path = out_path / "ip/flash_ctrl/rtl/autogen"
rtl_path.mkdir(parents=True, exist_ok=True)
doc_path = out_path / "ip/flash_ctrl/data/autogen"
doc_path.mkdir(parents=True, exist_ok=True)
tpl_path = Path(__file__).resolve().parent / "../hw/ip/flash_ctrl/data"
original_rtl_path = Path(
__file__).resolve().parent / "../hw/ip/flash_ctrl/rtl"
# Read template files from ip directory.
tpls = []
outputs = []
names = [
"flash_ctrl.hjson", "flash_ctrl.sv", "flash_ctrl_pkg.sv",
"flash_ctrl_region_cfg.sv"
]
for x in names:
tpls.append(tpl_path / Path(x + ".tpl"))
if "hjson" in x:
outputs.append(doc_path / Path(x))
else:
outputs.append(rtl_path / Path(x))
# Parameters needed for generation
flash_mems = [
module for module in topcfg["module"] if module["type"] == "flash_ctrl"
]
if len(flash_mems) > 1:
log.error("This design does not currently support multiple flashes")
return
cfg = flash_mems[0]["memory"]["mem"]["config"]
# Generate templated files
for idx, t in enumerate(tpls):
out = StringIO()
with t.open(mode="r", encoding="UTF-8") as fin:
tpl = Template(fin.read())
try:
out = tpl.render(cfg=cfg)
except: # noqa: E722
log.error(exceptions.text_error_template().render())
if out == "":
log.error("Cannot generate {}".format(names[idx]))
return
with outputs[idx].open(mode="w", encoding="UTF-8") as fout:
fout.write(genhdr + out)
# Generate reg files
hjson_path = outputs[0]
generate_regfile_from_path(hjson_path, rtl_path, original_rtl_path)
def generate_top_only(top_only_dict, out_path, topname, alt_hjson_path):
log.info("Generating top only modules")
for ip, reggen_only in top_only_dict.items():
if reggen_only and alt_hjson_path is not None:
hjson_dir = Path(alt_hjson_path)
else:
hjson_dir = Path(__file__).resolve(
).parent / f"../hw/top_{topname}/ip/{ip}/data/"
hjson_path = hjson_dir / f"{ip}.hjson"
genrtl_dir = out_path / "ip/{}/rtl".format(ip)
genrtl_dir.mkdir(parents=True, exist_ok=True)
log.info("Generating top modules {}, hjson: {}, output: {}".format(
ip, hjson_path, genrtl_dir))
# Generate reg files
generate_regfile_from_path(hjson_path, genrtl_dir)
def generate_top_ral(top: Dict[str, object], name_to_block: Dict[str, IpBlock],
dv_base_names: List[str], out_path: str):
# construct top ral block
regwidth = int(top["datawidth"])
assert regwidth % 8 == 0
addrsep = regwidth // 8
# Generate a map from instance name to the block that it instantiates,
# together with a map of interface addresses.
inst_to_block = {} # type: Dict[str, str]
if_addrs = {} # type: Dict[Tuple[str, Optional[str]], int]
attrs = {} # type: Dict[str, str]
for module in top["module"]:
inst_name = module["name"]
block_name = module["type"]
block = name_to_block[block_name]
if "attr" in module:
if module["attr"] not in ["templated", "ipgen", "reggen_top",
"reggen_only"]:
raise ValueError("Unsupported value for attr field of {}: {!r}"
.format(inst_name, module["attr"]))
attrs[inst_name] = module["attr"]
inst_to_block[inst_name] = block_name
for if_name in block.reg_blocks.keys():
if_addr = int(module["base_addrs"][if_name], 0)
if_addrs[(inst_name, if_name)] = if_addr
# Collect up the memories to add
mems = []
for item in list(top.get("memory", [])):
mems.append(create_mem(item, addrsep, regwidth))
# Top-level may override the mem setting. Store the new type to name_to_block
# If no other instance uses the orignal type, delete it
original_types = set()
for module in top["module"]:
if "memory" in module.keys() and len(module["memory"]) > 0:
newtype = "{}_{}".format(module["type"], module["name"])
assert newtype not in name_to_block
block = deepcopy(name_to_block[module["type"]])
name_to_block[newtype] = block
inst_to_block[module["name"]] = newtype
original_types.add(module["type"])
for mem_name, item in module["memory"].items():
assert block.reg_blocks[mem_name]
assert len(block.reg_blocks[mem_name].windows) <= 1
item["name"] = mem_name
win = create_mem(item, addrsep, regwidth)
if len(block.reg_blocks[mem_name].windows) > 0:
blk_win = block.reg_blocks[mem_name].windows[0]
# Top can only add new info for mem, shouldn't overwrite
# existing configuration
assert win.items == blk_win.items
assert win.byte_write == blk_win.byte_write
assert win.data_intg_passthru == blk_win.data_intg_passthru
block.reg_blocks[mem_name].windows[0] = win
else:
block.reg_blocks[mem_name].windows.append(win)
for t in original_types:
if t not in inst_to_block.values():
del name_to_block[t]
chip = Top(regwidth, name_to_block, inst_to_block, if_addrs, mems, attrs)
# generate the top ral model with template
return gen_dv(chip, dv_base_names, str(out_path))
def create_mem(item, addrsep, regwidth):
byte_write = ("byte_write" in item and
item["byte_write"].lower() == "true")
data_intg_passthru = ("data_intg_passthru" in item and
item["data_intg_passthru"].lower() == "true")
size_in_bytes = int(item["size"], 0)
num_regs = size_in_bytes // addrsep
swaccess = access.SWAccess("top-level memory", item.get("swaccess", "rw"))
return window.Window(name=item["name"],
desc="(generated from top-level)",
unusual=False,
byte_write=byte_write,
data_intg_passthru=data_intg_passthru,
validbits=regwidth,
items=num_regs,
size_in_bytes=size_in_bytes,
offset=int(item.get("base_addr", "0"), 0),
swaccess=swaccess)
def _process_top(topcfg, args, cfg_path, out_path, pass_idx):
# Create generated list
# These modules are generated through topgen
templated_list = lib.get_templated_modules(topcfg)
log.info("Templated list is {}".format(templated_list))
ipgen_list = lib.get_ipgen_modules(topcfg)
log.info("Ip gen list is {}".format(ipgen_list))
generated_list = templated_list + ipgen_list
# These modules are NOT generated but belong to a specific top
# and therefore not part of "hw/ip"
top_only_dict = {
module["type"]: lib.is_reggen_only(module)
for module in topcfg["module"] if lib.is_top_reggen(module)
}
log.info("Filtered dict is {}".format(top_only_dict))
topname = topcfg["name"]
# Sweep the IP directory and gather the config files
ip_dir = Path(__file__).parents[1] / "hw/ip"
ips = search_ips(ip_dir)
# exclude filtered IPs (to use top_${topname} one) and
exclude_list = generated_list + list(top_only_dict.keys())
ips = [x for x in ips if not x.parents[1].name in exclude_list]
# Hack alert
# Generate clkmgr.hjson here so that it can be included below
# Unlike other generated hjsons, clkmgr thankfully does not require
# ip.hjson information. All the information is embedded within
# the top hjson file
topcfg["clocks"] = Clocks(topcfg["clocks"])
extract_clocks(topcfg)
generate_clkmgr(topcfg, cfg_path, out_path)
# It may require two passes to check if the module is needed.
# TODO: first run of topgen will fail due to the absent of rv_plic.
# It needs to run up to amend_interrupt in merge_top function
# then creates rv_plic.hjson then run xbar generation.
hjson_dir = Path(args.topcfg).parent
for ip in generated_list:
# For modules that are generated prior to gathering, we need to take it from
# the output path. For modules not generated before, it may exist in a
# pre-defined area already.
log.info("Appending {}".format(ip))
if ip in ipgen_list:
ip_relpath = "ip_autogen"
desc_file_relpath = "data"
else:
ip_relpath = "ip"
desc_file_relpath = "data/autogen"
if ip == "clkmgr" or (pass_idx > 0):
ip_hjson = (Path(out_path) / ip_relpath / ip / desc_file_relpath /
f"{ip}.hjson")
else:
ip_hjson = (hjson_dir.parent / ip_relpath / ip /
desc_file_relpath / f"{ip}.hjson")
ips.append(ip_hjson)
for ip, reggen_only in top_only_dict.items():
log.info("Appending {}".format(ip))
if reggen_only and args.hjson_path:
ip_hjson = Path(args.hjson_path) / f"{ip}.hjson"
else:
ip_hjson = hjson_dir.parent / f"ip/{ip}/data/{ip}.hjson"
ips.append(ip_hjson)
# load Hjson and pass validate from reggen
try:
ip_objs = []
for ip_desc_file in ips:
ip_name = ip_desc_file.stem
# Skip if it is not in the module list
if ip_name not in [ip["type"] for ip in topcfg["module"]]:
log.info("Skip module %s as it isn't in the top module list" %
ip_name)
continue
# The auto-generated hjson might not yet exist. It will be created
# later, see generate_{ip_name}() calls below. For the initial
# validation, use the Hjson file with default values.
# TODO: All of this is a rather ugly hack that we need to get rid
# of as soon as we don't arbitrarily template IP description Hjson
# files any more.
if ip_name in generated_list and not ip_desc_file.is_file():
if ip_name in ipgen_list:
log.info(
"To-be-auto-generated Hjson %s does not yet exist. "
"Falling back to the default configuration of template "
"%s for initial validation." % (ip_desc_file, ip_name))
tpl_path = SRCTREE_TOP / "hw/ip_templates" / ip_name
ip_template = IpTemplate.from_template_path(tpl_path)
ip_config = IpConfig(ip_template.params,
f"top_{topname}_{ip_name}")
try:
ip_desc = IpDescriptionOnlyRenderer(
ip_template, ip_config).render()
except TemplateRenderError as e:
log.error(e.verbose_str())
sys.exit(1)
s = "default description of IP template {}".format(ip_name)
ip_objs.append(IpBlock.from_text(ip_desc, [], s))
else:
# TODO: Remove this block as soon as all IP templates use
# ipgen.
template_hjson_file = ip_dir / "{}/data/{}.hjson".format(
ip_name, ip_name)
log.info(
"To-be-auto-generated Hjson %s does not yet exist. "
"Falling back to Hjson description file %s shipped "
"with the IP template for initial validation." %
(ip_desc_file, template_hjson_file))
ip_objs.append(
IpBlock.from_path(str(template_hjson_file), []))
else:
ip_objs.append(IpBlock.from_path(str(ip_desc_file), []))
except ValueError:
raise SystemExit(sys.exc_info()[1])
name_to_block = {} # type: Dict[str, IpBlock]
for block in ip_objs:
lblock = block.name.lower()
assert lblock not in name_to_block
name_to_block[lblock] = block
# Read in alias files one-by-one, peek inside to figure out which IP block
# they belong to and apply the alias file to that IP block.
if args.alias_files:
for alias in args.alias_files:
with open(alias, 'r', encoding='utf-8') as handle:
raw = hjson.loads(handle.read(), use_decimal=True)
if 'alias_target' not in raw:
raise ValueError('Missing alias_target key '
'in alias file {}.'.format(alias))
alias_target = raw['alias_target'].lower()
if alias_target not in name_to_block:
raise ValueError('Alias target {} is not defined.'
.format(alias_target))
where = 'alias file at {}'.format(alias)
name_to_block[alias_target].alias_from_raw(False, raw, where)
connect_clocks(topcfg, name_to_block)
# Read the crossbars under the top directory
xbar_objs = get_hjsonobj_xbars(hjson_dir)
log.info("Detected crossbars: %s" %
(", ".join([x["name"] for x in xbar_objs])))
topcfg, error = validate_top(topcfg, ip_objs, xbar_objs)
if error != 0:
raise SystemExit("Error occured while validating top.hjson")
completecfg = merge_top(topcfg, name_to_block, xbar_objs)
# Generate flash controller and flash memory
generate_flash(topcfg, out_path)
# Generate PLIC
if not args.no_plic and \
not args.alert_handler_only and \
not args.xbar_only:
generate_plic(completecfg, out_path)
if args.plic_only:
sys.exit()
# Create Alert Handler LPGs before
# generating the Alert Handler
create_alert_lpgs(topcfg, name_to_block)
# Generate Alert Handler
if not args.xbar_only:
generate_alert_handler(completecfg, out_path)
if args.alert_handler_only:
sys.exit()
# Generate Pinmux
generate_pinmux(completecfg, out_path)
# Generate Pwrmgr
generate_pwrmgr(completecfg, out_path)
# Generate rstmgr
generate_rstmgr(completecfg, out_path)
# Generate top only modules
# These modules are not templated, but are not in hw/ip
generate_top_only(top_only_dict, out_path, topname, args.hjson_path)
return completecfg, name_to_block
def main():
parser = argparse.ArgumentParser(prog="topgen")
parser.add_argument("--topcfg",
"-t",
required=True,
help="`top_{name}.hjson` file.")
parser.add_argument(
"--outdir",
"-o",
help="""Target TOP directory.
Module is created under rtl/. (default: dir(topcfg)/..)
""") # yapf: disable
parser.add_argument(
"--hjson-path",
help="""
If defined, topgen uses supplied path to search for ip hjson.
This applies only to ip's with the `reggen_only` attribute.
If an hjson is located both in the conventional path and the alternate
path, the alternate path has priority.
""")
parser.add_argument("--verbose", "-v", action="store_true", help="Verbose")
# Generator options: 'no' series. cannot combined with 'only' series
parser.add_argument(
"--no-top",
action="store_true",
help="If defined, topgen doesn't generate top_{name} RTLs.")
parser.add_argument(
"--no-xbar",
action="store_true",
help="If defined, topgen doesn't generate crossbar RTLs.")
parser.add_argument(
"--no-plic",
action="store_true",
help="If defined, topgen doesn't generate the interrup controller RTLs."
)
# Generator options: 'only' series. cannot combined with 'no' series
parser.add_argument(
"--top-only",
action="store_true",
help="If defined, the tool generates top RTL only") # yapf:disable
parser.add_argument(
"--xbar-only",
action="store_true",
help="If defined, the tool generates crossbar RTLs only")
parser.add_argument(
"--plic-only",
action="store_true",
help="If defined, the tool generates RV_PLIC RTL and Hjson only")
parser.add_argument(
"--alert-handler-only",
action="store_true",
help="If defined, the tool generates alert handler hjson only")
# Generator options: generate dv ral model
parser.add_argument(
"--top_ral",
"-r",
default=False,
action="store_true",
help="If set, the tool generates top level RAL model for DV")
parser.add_argument(
"--alias-files",
nargs="+",
type=Path,
default=None,
help="""
If defined, topgen uses supplied alias hjson file(s) to override the
generic register definitions when building the RAL model. This
argument is only relevant in conjunction with the `--top_ral` switch.
""")
parser.add_argument(
"--dv-base-names",
nargs="+",
help="Names or prefix for the DV register classes from which "
"the register models are derived.")
# Generator options for compile time random netlist constants
parser.add_argument(
"--rnd_cnst_seed",
type=int,
metavar="<seed>",
help="Custom seed for RNG to compute netlist constants.")
parser.add_argument(
"--entropy_buffer",
help="A file with entropy.")
# Miscellaneous: only return the list of blocks and exit.
parser.add_argument("--get_blocks",
default=False,
action="store_true",
help="Only return the list of blocks and exit.")
args = parser.parse_args()
# check combinations
if args.top_ral:
args.no_top = True
if (args.no_top or args.no_xbar or
args.no_plic) and (args.top_only or args.xbar_only or
args.plic_only or args.alert_handler_only):
log.error(
"'no' series options cannot be used with 'only' series options")
raise SystemExit(sys.exc_info()[1])
# Don't print warnings when querying the list of blocks.
log_level = (log.ERROR
if args.get_blocks else log.DEBUG if args.verbose else None)
log.basicConfig(format="%(levelname)s: %(message)s", level=log_level)
if not args.outdir:
outdir = Path(args.topcfg).parent / ".."
log.info("TOP directory not given. Use %s", (outdir))
elif not Path(args.outdir).is_dir():
log.error("'--outdir' should point to writable directory")
raise SystemExit(sys.exc_info()[1])
else:
outdir = Path(args.outdir)
if args.hjson_path is not None:
log.info(f"Alternate hjson path is {args.hjson_path}")
out_path = Path(outdir)
cfg_path = Path(args.topcfg).parents[1]
try:
with open(args.topcfg, "r") as ftop:
topcfg = hjson.load(ftop,
use_decimal=True,
object_pairs_hook=OrderedDict)
except ValueError:
raise SystemExit(sys.exc_info()[1])
# Initialize RNG for compile-time netlist constants.
if args.entropy_buffer:
if args.rnd_cnst_seed:
log.error("'entropy_buffer' option cannot be used with 'rnd_cnst_seed option'")
# error out
raise SystemExit(sys.exc_info()[1])
else:
# generate entropy from a buffer
strong_random.load(SRCTREE_TOP / args.entropy_buffer)
else:
# If specified, override the seed for random netlist constant computation.
if args.rnd_cnst_seed:
log.warning("Commandline override of rnd_cnst_seed with {}.".format(
args.rnd_cnst_seed))
topcfg["rnd_cnst_seed"] = args.rnd_cnst_seed
# Otherwise, we either take it from the top_{topname}.hjson if present, or
# randomly generate a new seed if not.
else:
random.seed()
new_seed = random.getrandbits(64)
if topcfg.setdefault("rnd_cnst_seed", new_seed) == new_seed:
log.warning(
"No rnd_cnst_seed specified, setting to {}.".format(new_seed))
ebg.gen_buffer(BUFFER_SIZE, SRCTREE_TOP / PATH_TO_BUFFER, False, topcfg["rnd_cnst_seed"])
strong_random.load(SRCTREE_TOP / PATH_TO_BUFFER)
# TODO, long term, the levels of dependency should be automatically determined instead
# of hardcoded. The following are a few examples:
# Example 1: pinmux depends on amending all modules before calculating the correct number of
# pins.
# This would be 1 level of dependency and require 2 passes.
# Example 2: pinmux depends on amending all modules, and pwrmgr depends on pinmux generation to
# know correct number of wakeups. This would be 2 levels of dependency and require 3
# passes.
#
# How does mulit-pass work?
# In example 1, the first pass gathers all modules and merges them. However, the merge process
# uses a stale pinmux. The correct pinmux is then generated using the merged configuration. The
# second pass now merges all the correct modules (including the generated pinmux) and creates
# the final merged config.
#
# In example 2, the first pass gathers all modules and merges them. However, the merge process
# uses a stale pinmux and pwrmgr. The correct pinmux is then generated using the merged
# configuration. However, since pwrmgr is dependent on this new pinmux, it is still generated
# incorrectly. The second pass merge now has an updated pinmux but stale pwrmgr. The correct
# pwrmgr can now be generated. The final pass then merges all the correct modules and creates
# the final configuration.
#
# This fix is related to #2083
process_dependencies = 1
# topgen generates IP blocks and associated Hjson configuration in multiple
# steps. After each step, the IP Hjson configuration is read back and then
# combined into the toplevel configuration. To generate the chip-level RAL,
# we need to run the full generation step, but ultimately only care about
# the toplevel configuration (a single Hjson file). Since we don't have a
# better way at the moment dump all output into a temporary directory, and
# delete it after the fact, retaining only the toplevel configuration.
if args.top_ral:
out_path_gen = Path(tempfile.mkdtemp())
else:
out_path_gen = out_path
for pass_idx in range(process_dependencies + 1):
log.debug("Generation pass {}".format(pass_idx))
if pass_idx < process_dependencies:
cfg_copy = deepcopy(topcfg)
_process_top(cfg_copy, args, cfg_path, out_path_gen, pass_idx)
else:
completecfg, name_to_block = _process_top(topcfg, args, cfg_path,
out_path_gen, pass_idx)
topname = topcfg["name"]
if not args.entropy_buffer:
# Delete entropy buffer since it is no longer needed.
# This buffer can always be re-generated from the seed using entropy_buffer_generator
os.remove(SRCTREE_TOP / PATH_TO_BUFFER)
# Create the chip-level RAL only
if args.top_ral:
# See above: we only need `completeconfig` and `name_to_block`, not all
# the other files (e.g. RTL files) generated through topgen.
shutil.rmtree(out_path_gen, ignore_errors=True)
exit_code = generate_top_ral(completecfg, name_to_block,
args.dv_base_names, out_path)
sys.exit(exit_code)
if args.get_blocks:
print("\n".join(name_to_block.keys()))
sys.exit(0)
# Generate xbars
if not args.no_xbar or args.xbar_only:
generate_xbars(completecfg, out_path)
# All IPs are generated. Connect phase now
# Find {memory, module} <-> {xbar} connections first.
im.autoconnect(completecfg, name_to_block)
# Generic Inter-module connection
im.elab_intermodule(completecfg)
# Generate top.gen.hjson right before rendering
genhjson_dir = out_path / "data/autogen"
genhjson_dir.mkdir(parents=True, exist_ok=True)
genhjson_path = genhjson_dir / ("top_%s.gen.hjson" % completecfg["name"])
# Header for HJSON
if args.entropy_buffer:
gencmd = """//
// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson \\
// -o hw/top_{topname}/ \\
// --hjson-only \\
// --entropy-buffer {path}
""".format(topname=topname, path = args.entropy_buffer)
else:
gencmd = """//
// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson \\
// -o hw/top_{topname}/ \\
// --hjson-only \\
// --rnd_cnst_seed {seed}
""".format(topname=topname, seed=completecfg["rnd_cnst_seed"])
genhjson_path.write_text(genhdr + gencmd +
hjson.dumps(completecfg, for_json=True) + '\n')
if not args.no_top or args.top_only:
def render_template(template_path: str, rendered_path: Path,
**other_info):
template_contents = generate_top(completecfg, name_to_block,
str(template_path), **other_info)
rendered_path.parent.mkdir(exist_ok=True, parents=True)
with rendered_path.open(mode="w", encoding="UTF-8") as fout:
fout.write(template_contents)
# Header for SV files
if args.entropy_buffer:
gencmd = warnhdr + """//
// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson \\
// -o hw/top_{topname}/ \\
// --entropy-buffer {path}
""".format(topname=topname, path = args.entropy_buffer)
else:
gencmd = warnhdr + """//
// util/topgen.py -t hw/top_{topname}/data/top_{topname}.hjson \\
// -o hw/top_{topname}/ \\
// --rnd_cnst_seed {seed}
""".format(topname=topname, seed=completecfg["rnd_cnst_seed"])
# SystemVerilog Top:
# "toplevel.sv.tpl" -> "rtl/autogen/top_{topname}.sv"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel.sv.tpl",
out_path / f"rtl/autogen/top_{topname}.sv",
gencmd=gencmd)
# Multiple chip-levels (ASIC, FPGA, Verilator, etc)
for target in topcfg["targets"]:
target_name = target["name"]
render_template(TOPGEN_TEMPLATE_PATH / "chiplevel.sv.tpl",
out_path /
f"rtl/autogen/chip_{topname}_{target_name}.sv",
gencmd=gencmd,
target=target)
# The C / SV file needs some complex information, so we initialize this
# object to store it.
c_helper = TopGenCTest(completecfg, name_to_block)
# The Rust file needs some complex information, so we initialize this
# object to store it.
rs_helper = TopGenRust(completecfg, name_to_block)
# "toplevel_pkg.sv.tpl" -> "rtl/autogen/top_{topname}_pkg.sv"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_pkg.sv.tpl",
out_path / f"rtl/autogen/top_{topname}_pkg.sv",
helper=c_helper,
gencmd=gencmd)
# compile-time random netlist constants
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_rnd_cnst_pkg.sv.tpl",
out_path /
f"rtl/autogen/top_{topname}_rnd_cnst_pkg.sv",
gencmd=gencmd)
# C Header + C File + Clang-format file
# Since SW does not use FuseSoC and instead expects those files always
# to be in hw/top_{topname}/sw/autogen, we currently create these files
# twice:
# - Once under out_path/sw/autogen
# - Once under hw/top_{topname}/sw/autogen
root_paths = [out_path.resolve(), SRCTREE_TOP]
out_paths = [
out_path.resolve(),
(SRCTREE_TOP / "hw/top_{}/".format(topname)).resolve()
]
for idx, path in enumerate(out_paths):
# "clang-format" -> "sw/autogen/.clang-format"
cformat_tplpath = TOPGEN_TEMPLATE_PATH / "clang-format"
cformat_dir = path / "sw/autogen"
cformat_dir.mkdir(parents=True, exist_ok=True)
cformat_path = cformat_dir / ".clang-format"
cformat_path.write_text(cformat_tplpath.read_text())
# Save the header macro prefix into `c_helper`
rel_header_dir = cformat_dir.relative_to(root_paths[idx])
c_helper.header_macro_prefix = (
"OPENTITAN_" + str(rel_header_dir).replace("/", "_").upper())
# "top_{topname}.h.tpl" -> "sw/autogen/top_{topname}.h"
cheader_path = cformat_dir / f"top_{topname}.h"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel.h.tpl",
cheader_path,
helper=c_helper)
# Save the relative header path into `c_helper`
rel_header_path = cheader_path.relative_to(root_paths[idx])
c_helper.header_path = str(rel_header_path)
# "toplevel.c.tpl" -> "sw/autogen/top_{topname}.c"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel.c.tpl",
cformat_dir / f"top_{topname}.c",
helper=c_helper)
# "toplevel_memory.ld.tpl" -> "sw/autogen/top_{topname}_memory.ld"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_memory.ld.tpl",
cformat_dir / f"top_{topname}_memory.ld")
# "toplevel_memory.h.tpl" -> "sw/autogen/top_{topname}_memory.h"
memory_cheader_path = cformat_dir / f"top_{topname}_memory.h"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_memory.h.tpl",
memory_cheader_path,
helper=c_helper)
# Rust File + Clang-format file
# Since SW does not use FuseSoC and instead expects those files always
# to be in hw/top_{topname}/sw/autogen, we currently create these files
# twice:
# - Once under out_path/sw/autogen
# - Once under hw/top_{topname}/sw/autogen
root_paths = [out_path.resolve(), SRCTREE_TOP]
out_paths = [
out_path.resolve(),
(SRCTREE_TOP / "hw/top_{}/".format(topname)).resolve()
]
for idx, path in enumerate(out_paths):
# "clang-format" -> "sw/autogen/.clang-format"
cformat_tplpath = TOPGEN_TEMPLATE_PATH / "clang-format"
cformat_dir = path / "sw/autogen"
cformat_dir.mkdir(parents=True, exist_ok=True)
cformat_path = cformat_dir / ".clang-format"
cformat_path.write_text(cformat_tplpath.read_text())
# Save the header macro prefix into `rs_helper`
rel_header_dir = cformat_dir.relative_to(root_paths[idx])
rs_helper.header_macro_prefix = (
"OPENTITAN_" + str(rel_header_dir).replace("/", "_").upper())
# "top_{topname}.rs.tpl" -> "sw/autogen/top_{topname}.rs"
cheader_path = cformat_dir / f"top_{topname}.rs"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel.rs.tpl",
cheader_path,
helper=rs_helper)
# TODO Rust don't have header this path
# should be used to generate rust modules.
# Save the relative header path into `rs_helper`
rel_header_path = cheader_path.relative_to(root_paths[idx])
rs_helper.header_path = str(rel_header_path)
# "toplevel_memory.ld.tpl" -> "sw/autogen/top_{topname}_memory.ld"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_memory.ld.tpl",
cformat_dir / f"top_{topname}_memory.ld")
# TODO megre to one memmory file
# "toplevel_memory.rs.tpl" -> "sw/autogen/top_{topname}_memory.rs.h"
memory_cheader_path = cformat_dir / f"top_{topname}_memory.rs"
render_template(TOPGEN_TEMPLATE_PATH / "toplevel_memory.rs.tpl",
memory_cheader_path,
helper=rs_helper)
# generate chip level xbar and alert_handler TB
tb_files = [
"xbar_env_pkg__params.sv", "tb__xbar_connect.sv",
"tb__alert_handler_connect.sv", "xbar_tgl_excl.cfg",
"rstmgr_tgl_excl.cfg"
]
for fname in tb_files:
tpl_fname = "%s.tpl" % (fname)
xbar_chip_data_path = TOPGEN_TEMPLATE_PATH / tpl_fname
template_contents = generate_top(completecfg, name_to_block,
str(xbar_chip_data_path), gencmd=gencmd)
rendered_dir = out_path / "dv/autogen"
rendered_dir.mkdir(parents=True, exist_ok=True)
rendered_path = rendered_dir / fname
with rendered_path.open(mode="w", encoding="UTF-8") as fout:
fout.write(template_contents)
# generate parameters for chip-level environment package
tpl_fname = "chip_env_pkg__params.sv.tpl"
alert_handler_chip_data_path = TOPGEN_TEMPLATE_PATH / tpl_fname
template_contents = generate_top(completecfg, name_to_block,
str(alert_handler_chip_data_path))
rendered_dir = out_path / "dv/env/autogen"
rendered_dir.mkdir(parents=True, exist_ok=True)
rendered_path = rendered_dir / "chip_env_pkg__params.sv"
with rendered_path.open(mode="w", encoding="UTF-8") as fout:
fout.write(template_contents)
# generate documentation for toplevel
gen_top_docs(completecfg, c_helper, out_path)
# Auto-generate tests in "sw/device/tests/autogen" area.
gencmd = warnhdr + GENCMD.format(topname=topname)
for fname in ["plic_all_irqs_test.c", "alert_test.c", "BUILD"]:
outfile = SRCTREE_TOP / "sw/device/tests/autogen" / fname
render_template(TOPGEN_TEMPLATE_PATH / f"{fname}.tpl",
outfile,
helper=c_helper,
gencmd=gencmd)
if __name__ == "__main__":
main()