You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.

337 lines
10 KiB

"""
This script reads in the given CMSIS device include file (eg stm32f405xx.h),
extracts relevant peripheral constants, and creates qstrs, mpz's and constants
for the stm module.
"""
from __future__ import print_function
import argparse
import re
# Python 2/3 compatibility
import platform
if platform.python_version_tuple()[0] == "2":
def convert_bytes_to_str(b):
return b
elif platform.python_version_tuple()[0] == "3":
def convert_bytes_to_str(b):
try:
return str(b, "utf8")
except ValueError:
# some files have invalid utf8 bytes, so filter them out
return "".join(chr(l) for l in b if l <= 126)
# end compatibility code
# given a list of (name,regex) pairs, find the first one that matches the given line
def re_match_first(regexs, line):
for name, regex in regexs:
match = re.match(regex, line)
if match:
return name, match
return None, None
class LexerError(Exception):
def __init__(self, line):
self.line = line
class Lexer:
re_io_reg = r"__IO uint(?P<bits>8|16|32)_t +(?P<reg>[A-Z0-9]+)"
re_comment = r"(?P<comment>[A-Za-z0-9 \-/_()&:\[\]]+)"
re_addr_offset = r"Address offset: (?P<offset>0x[0-9A-Z]{2,3})"
regexs = (
(
"#define hex",
re.compile(
r"#define +(?P<id>[A-Z0-9_]+) +\(?(\(uint32_t\))?(?P<hex>0x[0-9A-F]+)U?L?\)?($| */\*)"
),
),
("#define X", re.compile(r"#define +(?P<id>[A-Z0-9_]+) +(?P<id2>[A-Z0-9_]+)($| +/\*)")),
(
"#define X+hex",
re.compile(
r"#define +(?P<id>[A-Za-z0-9_]+) +\(?(?P<id2>[A-Z0-9_]+) \+ (?P<hex>0x[0-9A-F]+)U?L?\)?($| +/\*)"
),
),
(
"#define typedef",
re.compile(
stm32/fdcan: Fix FIFO1 usage and handling of error interrupts. The original code used a independent state with regards to the interrupt. During heavy bus error conditions the internal state could become out-of-sync with the interrupts. Further explanation: during the development of an application using CAN communication, a interrupt-run-away was found in some situations. It was found that the error interrupt triggered (Warning, Passive or Bus-Off, all triggered it) the run-away. The only recovery was a reset. Two problems were found: - the error interrupt is enabled but not cleared in the interrupt routine; - an internal variable &#39;State&#39; that was used to track the message received state (empty, new, full, overflow) that was not directly related to interrupt that indicated the state. In this commit these issues are fixed by adding more values for the interrupt reason (warning, passive, bus off) and clearing the error interrupts, and making the internal state directly dependent on the interrupt state for received messages. Furthermore, introducing the FIFO1 in the CAN receive stage, another issue existed. Even if the messages are received into the FIFO1 (by selecting message filtering for FIFO0 and FIFO1), the interrupt firing was indicating FIFO0 Rx. The configuration of the interrupts for this is now also fixed. The CAN peripheral has 2 interrupt lines going into the NVIC controller. The assignment of the interrupt reasons to these 2 interrupt lines was missing. Now the reception of FIFO1 messages triggers the second interrupt line. Other interrupts (Rx FIFO0 and bus error) are assigned to the first interrupt line. Tested on a Nucleo-G474, and also checked the HAL function to work with the H7 family.
3 years ago
r"#define +(?P<id>[A-Z0-9_]+(ext)?) +\(\([A-Za-z0-9_]+_(Global)?TypeDef \*\) (?P<id2>[A-Za-z0-9_]+)\)($| +/\*)"
),
),
("typedef struct", re.compile(r"typedef struct$")),
("{", re.compile(r"{$")),
("}", re.compile(r"}$")),
(
"} TypeDef",
re.compile(r"} *(?P<id>[A-Z][A-Za-z0-9_]+)_(?P<global>([A-Za-z0-9_]+)?)TypeDef;$"),
),
(
"IO reg",
re.compile(
re_io_reg + r" *; */\*!< *" + re_comment + r",? +" + re_addr_offset + r" *\*/"
),
),
(
"IO reg array",
re.compile(
re_io_reg
+ r"\[(?P<array>[2-8])\] *; */\*!< *"
+ re_comment
+ r",? +"
+ re_addr_offset
+ r"-(0x[0-9A-Z]{2,3}) *\*/"
),
),
)
def __init__(self, filename):
self.file = open(filename, "rb")
self.line_number = 0
def next_match(self, strictly_next=False):
while True:
line = self.file.readline()
line = convert_bytes_to_str(line)
self.line_number += 1
if len(line) == 0:
return ("EOF", None)
match = re_match_first(Lexer.regexs, line.strip())
if strictly_next or match[0] is not None:
return match
def must_match(self, kind):
match = self.next_match(strictly_next=True)
if match[0] != kind:
raise LexerError(self.line_number)
return match
def parse_file(filename):
lexer = Lexer(filename)
reg_defs = {}
consts = {}
periphs = []
while True:
m = lexer.next_match()
if m[0] == "EOF":
break
elif m[0] == "#define hex":
d = m[1].groupdict()
consts[d["id"]] = int(d["hex"], base=16)
elif m[0] == "#define X":
d = m[1].groupdict()
if d["id2"] in consts:
consts[d["id"]] = consts[d["id2"]]
elif m[0] == "#define X+hex":
d = m[1].groupdict()
if d["id2"] in consts:
consts[d["id"]] = consts[d["id2"]] + int(d["hex"], base=16)
elif m[0] == "#define typedef":
d = m[1].groupdict()
if d["id2"] in consts:
periphs.append((d["id"], consts[d["id2"]]))
elif m[0] == "typedef struct":
lexer.must_match("{")
m = lexer.next_match()
regs = []
while m[0] in ("IO reg", "IO reg array"):
d = m[1].groupdict()
reg = d["reg"]
offset = int(d["offset"], base=16)
bits = int(d["bits"])
comment = d["comment"]
if m[0] == "IO reg":
regs.append((reg, offset, bits, comment))
else:
for i in range(int(d["array"])):
regs.append((reg + str(i), offset + i * bits // 8, bits, comment))
m = lexer.next_match()
if m[0] == "}":
pass
elif m[0] == "} TypeDef":
d = m[1].groupdict()
n = d["id"]
g = d["global"]
if n not in reg_defs or not g:
reg_defs[n] = regs
else:
raise LexerError(lexer.line_number)
return periphs, reg_defs
def print_int_obj(val, needed_mpzs):
if -0x40000000 <= val < 0x40000000:
print("MP_ROM_INT(%#x)" % val, end="")
else:
print("MP_ROM_PTR(&mpz_%08x)" % val, end="")
needed_mpzs.add(val)
def print_periph(periph_name, periph_val, needed_qstrs, needed_mpzs):
qstr = periph_name.upper()
print("{ MP_ROM_QSTR(MP_QSTR_%s), " % qstr, end="")
print_int_obj(periph_val, needed_mpzs)
print(" },")
needed_qstrs.add(qstr)
def print_regs(reg_name, reg_defs, needed_qstrs, needed_mpzs):
reg_name = reg_name.upper()
for r in reg_defs:
qstr = reg_name + "_" + r[0]
print("{ MP_ROM_QSTR(MP_QSTR_%s), " % qstr, end="")
print_int_obj(r[1], needed_mpzs)
print(" }, // %s-bits, %s" % (r[2], r[3]))
needed_qstrs.add(qstr)
# This version of print regs groups registers together into submodules (eg GPIO submodule).
# This makes the qstrs shorter, and makes the list of constants more manageable (since
# they are not all in one big module) but it is then harder to compile the constants, and
# is more cumbersome to access.
# As such, we don't use this version.
# And for the number of constants we have, this function seems to use about the same amount
# of ROM as print_regs.
def print_regs_as_submodules(reg_name, reg_defs, modules, needed_qstrs):
mod_name_lower = reg_name.lower() + "_"
mod_name_upper = mod_name_lower.upper()
modules.append((mod_name_lower, mod_name_upper))
print(
"""
STATIC const mp_rom_map_elem_t stm_%s_globals_table[] = {
{ MP_ROM_QSTR(MP_QSTR___name__), MP_ROM_QSTR(MP_QSTR_%s) },
"""
% (mod_name_lower, mod_name_upper)
)
needed_qstrs.add(mod_name_upper)
for r in reg_defs:
print(
" { MP_ROM_QSTR(MP_QSTR_%s), MP_ROM_INT(%#x) }, // %s-bits, %s"
% (r[0], r[1], r[2], r[3])
)
needed_qstrs.add(r[0])
print(
"""};
STATIC MP_DEFINE_CONST_DICT(stm_%s_globals, stm_%s_globals_table);
const mp_obj_module_t stm_%s_obj = {
.base = { &mp_type_module },
.name = MP_QSTR_%s,
.globals = (mp_obj_dict_t*)&stm_%s_globals,
};
"""
% (mod_name_lower, mod_name_lower, mod_name_lower, mod_name_upper, mod_name_lower)
)
def main():
cmd_parser = argparse.ArgumentParser(description="Extract ST constants from a C header file.")
cmd_parser.add_argument("file", nargs=1, help="input file")
cmd_parser.add_argument(
"-q",
"--qstr",
dest="qstr_filename",
default="build/stmconst_qstr.h",
help="Specified the name of the generated qstr header file",
)
cmd_parser.add_argument(
"--mpz",
dest="mpz_filename",
default="build/stmconst_mpz.h",
help="the destination file of the generated mpz header",
)
args = cmd_parser.parse_args()
periphs, reg_defs = parse_file(args.file[0])
# add legacy GPIO constants that were removed when upgrading CMSIS
if "GPIO" in reg_defs and "stm32f4" in args.file[0]:
reg_defs["GPIO"].append(["BSRRL", 0x18, 16, "legacy register"])
reg_defs["GPIO"].append(["BSRRH", 0x1A, 16, "legacy register"])
modules = []
needed_qstrs = set()
needed_mpzs = set()
print("// Automatically generated from %s by make-stmconst.py" % args.file[0])
print("")
for periph_name, periph_val in periphs:
print_periph(periph_name, periph_val, needed_qstrs, needed_mpzs)
for reg in (
"ADC",
#'ADC_Common',
#'CAN_TxMailBox',
#'CAN_FIFOMailBox',
#'CAN_FilterRegister',
#'CAN',
stm32/fdcan: Fix FIFO1 usage and handling of error interrupts. The original code used a independent state with regards to the interrupt. During heavy bus error conditions the internal state could become out-of-sync with the interrupts. Further explanation: during the development of an application using CAN communication, a interrupt-run-away was found in some situations. It was found that the error interrupt triggered (Warning, Passive or Bus-Off, all triggered it) the run-away. The only recovery was a reset. Two problems were found: - the error interrupt is enabled but not cleared in the interrupt routine; - an internal variable &#39;State&#39; that was used to track the message received state (empty, new, full, overflow) that was not directly related to interrupt that indicated the state. In this commit these issues are fixed by adding more values for the interrupt reason (warning, passive, bus off) and clearing the error interrupts, and making the internal state directly dependent on the interrupt state for received messages. Furthermore, introducing the FIFO1 in the CAN receive stage, another issue existed. Even if the messages are received into the FIFO1 (by selecting message filtering for FIFO0 and FIFO1), the interrupt firing was indicating FIFO0 Rx. The configuration of the interrupts for this is now also fixed. The CAN peripheral has 2 interrupt lines going into the NVIC controller. The assignment of the interrupt reasons to these 2 interrupt lines was missing. Now the reception of FIFO1 messages triggers the second interrupt line. Other interrupts (Rx FIFO0 and bus error) are assigned to the first interrupt line. Tested on a Nucleo-G474, and also checked the HAL function to work with the H7 family.
3 years ago
"FDCAN",
"CRC",
"DAC",
"DBGMCU",
"DMA_Stream",
"DMA",
"EXTI",
"FLASH",
"GPIO",
"SYSCFG",
"I2C",
"IWDG",
"PWR",
"RCC",
"RTC",
#'SDIO',
"SPI",
"TIM",
"USART",
"WWDG",
"RNG",
"IPCC",
):
if reg in reg_defs:
print_regs(reg, reg_defs[reg], needed_qstrs, needed_mpzs)
# print_regs_as_submodules(reg, reg_defs[reg], modules, needed_qstrs)
# print("#define MOD_STM_CONST_MODULES \\")
# for mod_lower, mod_upper in modules:
# print(" { MP_ROM_QSTR(MP_QSTR_%s), MP_ROM_PTR(&stm_%s_obj) }, \\" % (mod_upper, mod_lower))
print("")
with open(args.qstr_filename, "wt") as qstr_file:
print("#if MICROPY_PY_STM", file=qstr_file)
for qstr in sorted(needed_qstrs):
print("Q({})".format(qstr), file=qstr_file)
print("#endif // MICROPY_PY_STM", file=qstr_file)
with open(args.mpz_filename, "wt") as mpz_file:
for mpz in sorted(needed_mpzs):
assert 0 <= mpz <= 0xFFFFFFFF
print(
"STATIC const mp_obj_int_t mpz_%08x = {{&mp_type_int}, "
"{.neg=0, .fixed_dig=1, .alloc=2, .len=2, "
".dig=(uint16_t*)(const uint16_t[]){%#x, %#x}}};"
% (mpz, mpz & 0xFFFF, (mpz >> 16) & 0xFFFF),
file=mpz_file,
)
if __name__ == "__main__":
main()