portapack-mayhem/firmware/tools/extract_svf_data_xc2c64a.py

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#!/usr/bin/env python
#
# Copyright (C) 2016 Jared Boone, ShareBrained Technology, Inc.
#
# This file is part of PortaPack.
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2, or (at your option)
# any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program; see the file COPYING. If not, write to
# the Free Software Foundation, Inc., 51 Franklin Street,
# Boston, MA 02110-1301, USA.
#
# Very fragile code to extract data from Xilinx XC2C64A CPLD SVF
import sys
import re
import os.path
import argparse
def crack_variable_path(variable_path):
tmp = args.variable_path.split('::')
namespaces, variable_name = tmp[:-1], tmp[-1]
return namespaces, variable_name
parser = argparse.ArgumentParser()
parser.add_argument('input_file_path', type=str)
parser.add_argument('variable_path', type=str)
# parser.add_argument('header_file_path', type=str)
parser.add_argument('data_file_path', type=str)
args = parser.parse_args()
f = open(args.input_file_path, 'r')
namespaces, variable_name = crack_variable_path(args.variable_path)
def to_hex(value, length_bits):
return ('%x' % value).zfill((length_bits + 3) >> 2)
def long_int_to_bytes(n, bit_count):
byte_count = (bit_count + 7) >> 3
h = ('%x' % n).zfill(byte_count * 2)
return [int(h[n:n+2], 16) for n in range(0, len(h), 2)]
re_sdr = re.compile(r'^(?P<length>\d+)\s*TDI\s*\((?P<tdi>[0-9A-F]+)\)(|\s*SMASK\s*\((?P<smask>[0-9A-F]+)\))(|\s*TDO\s*\((?P<tdo>[0-9A-F]+)\))(|\s*MASK\s*\((?P<mask>[0-9A-F]+)\))\s*;$')
re_sir = re_sdr
class SIR_or_SDR(object):
def __init__(self, name, s):
self.name = name
match = re_sdr.match(s)
self.length = int(match.group('length'))
self.tdi = self._bits(match.group('tdi'))
self.smask = self._optional_bits(match.group('smask'))
self.tdo = self._optional_bits(match.group('tdo'))
self.mask = self._optional_bits(match.group('mask'))
def __repr__(self):
result = [self.name, str(self.length)]
result.append('TDI (%s)' % to_hex(self.tdi, self.length))
if self.smask:
result.append('SMASK (%s)' % to_hex(self.smask, self.length))
if self.tdo:
result.append('TDO (%s)' % to_hex(self.tdo, self.length))
if self.mask:
result.append('MASK (%s)' % to_hex(self.mask, self.length))
result.append(';')
return ' '.join(result)
def _bits(self, matched):
return int(matched, 16)
def _optional_bits(self, matched):
return self._bits(matched) if matched else None
class SDR(SIR_or_SDR):
def __init__(self, s):
SIR_or_SDR.__init__(self, 'SDR', s)
class SIR(SIR_or_SDR):
def __init__(self, s):
SIR_or_SDR.__init__(self, 'SIR', s)
class SVFParser(object):
instruction_parsers = {
'SIR': SIR,
'SDR': SDR,
}
def parse(self, f, instruction_handler_map):
complete_line = ''
for line in f:
line = line.strip().upper()
if line.startswith('//'):
continue
complete_line += line
if not line.endswith(';'):
continue
instruction_name, args_string = complete_line.split(None, 1)
instruction = self.instruction_parser(instruction_name, args_string)
if instruction:
instruction_type = type(instruction)
if instruction_type in instruction_handler_map:
instruction_handler_map[instruction_type](instruction)
if complete_line.endswith(';'):
complete_line = ''
def instruction_parser(self, instruction_name, args_string):
if instruction_name in self.instruction_parsers:
parser = self.instruction_parsers[instruction_name]
return parser(args_string)
else:
return None
class ProgramExtractor(object):
idcode = int('0bXXXX0110111001011XXX000010010011'.replace('X', '0'), 2)
idcode_mask = None
id_bits = 7
block_bits = 274
block_ordinals = frozenset(list(range(64)) + list(range(80, 82)) + list(range(96, 128)))
block_count = len(block_ordinals)
def __init__(self):
self.tap_instruction = None
self.program_data = []
self.verify_data = []
self.sdr_smask = None
self.sdr_mask = None
def map(self):
return {
SIR: self.on_sir,
SDR: self.on_sdr,
}
def on_sir(self, o):
assert(o.length == 8)
if o.tdi == 0x01:
self.tap_instruction = 'idcode'
elif o.tdi == 0xea:
self.tap_instruction = 'program'
self.program_data.append([])
elif o.tdi == 0xee:
self.tap_instruction = 'verify'
self.verify_data.append([])
self.verify_block_id = None
else:
self.tap_instruction = None
def on_sdr(self, o):
if o.smask:
self.sdr_smask = o.smask
if o.mask:
self.sdr_mask = o.mask
if self.tap_instruction == 'idcode':
assert(o.length == 32)
assert(self.sdr_smask == 0xffffffff)
assert((o.tdo & self.sdr_mask) == self.idcode)
if self.idcode_mask is None:
self.idcode_mask = self.sdr_mask
else:
assert(self.idcode_mask == self.sdr_mask)
elif self.tap_instruction == 'program':
assert(o.length == (self.id_bits + self.block_bits))
assert(self.sdr_smask == ((1 << o.length) - 1))
assert(o.tdo is None)
assert(o.mask is None)
block_id = o.tdi >> (o.length - 7)
mask = (1 << (o.length - 7)) - 1
self.program_data[-1].append({
'id': block_id,
'tdi': o.tdi & mask,
'length': o.length - 7,
})
elif self.tap_instruction == 'verify':
assert(o.length in (self.id_bits, self.block_bits))
if o.length == self.id_bits:
assert(o.smask == ((1 << self.id_bits) - 1))
assert(o.tdo is None)
assert(o.mask is None)
self.verify_block_id = o.tdi
elif o.length == self.block_bits:
assert(o.tdi == (1 << o.length) - 1)
assert(o.smask == (1 << o.length) - 1)
self.verify_data[-1].append({
'id': self.verify_block_id,
'tdo': o.tdo,
'mask': o.mask,
'length': o.length,
})
self.verify_block_id = None
program_extractor = ProgramExtractor()
parser = SVFParser()
parser.parse(f, program_extractor.map())
def has_all_blocks(blocks):
ordinals = set()
for block in blocks:
ordinal = int(bin(block['id'])[2:].zfill(7)[::-1], 2)
ordinals.add(ordinal)
return ordinals == program_extractor.block_ordinals
def is_verify_blank(blocks):
for block in blocks:
length = block['length']
mask = (1 << length) - 1
if block['tdo'] != mask:
return False
if block['mask'] != mask:
return False
return True
def deduplicate(passes):
result = [passes[0]]
for this_pass in passes[1:]:
if this_pass != result[0]:
result.append(this_pass)
return result
def program_and_verify_match(program, verify):
for program_block, verify_block in zip(program, verify):
if program_block['tdi'] != verify_block['tdo']:
return False
return True
program_passes = [blocks for blocks in program_extractor.program_data if has_all_blocks(blocks)]
program_done = [blocks for blocks in program_extractor.program_data if len(blocks) == 1][0]
if len(program_passes) == 0:
raise RuntimeError('no complete program passes')
if len(program_passes) > 1:
raise RuntimeError('too many program passes')
program = program_passes[0]
verify_passes = [blocks for blocks in program_extractor.verify_data if has_all_blocks(blocks) and not is_verify_blank(blocks)]
verify_passes = deduplicate(verify_passes)
if len(verify_passes) == 0:
raise RuntimeError('no complete verify passes')
if len(verify_passes) > 1:
raise RuntimeError('too many verify passes')
verify = verify_passes[0]
if not program_and_verify_match(program, verify):
raise RuntimeError('program and verify data do not match')
class FileGen(object):
def comment_header(self):
return ['/*' , ' * WARNING: Auto-generated file. Do not edit.', '*/']
def includes(self, filenames):
return ['#include "%s"' % filename for filename in filenames]
def _namespaces(self, ns_list, line_format):
return [line_format % ns for ns in ns_list]
def namespaces_start(self, ns_list):
return self._namespaces(ns_list, 'namespace %s {')
def namespaces_end(self, ns_list):
return self._namespaces(ns_list, '} /* namespace %s */')
def verify_block(self, block):
tdo_bytes = long_int_to_bytes(block['tdo'], block['length'])
mask_bytes = long_int_to_bytes(block['mask'], block['length'])
tdo_cpp_s = ', '.join(['0x%02x' % b for b in tdo_bytes]);
mask_cpp_s = ', '.join(['0x%02x' % b for b in mask_bytes]);
return '\t{ 0x%02x, { { %s } }, { { %s } } },' % (block['id'], tdo_cpp_s, mask_cpp_s)
def verify_blocks_declaration(self, type_name, variable_name):
return ['extern const %s %s;' % (type_name, variable_name)]
def verify_blocks_definition(self, type_name, variable_name, blocks):
return ['const %s %s { {' % (type_name, variable_name)] \
+ [self.verify_block(block) for block in blocks] \
+ ['} };']
# def cpp_program_t(block):
# tdi_bytes = long_int_to_bytes(block['tdi'], block['length'])
# tdi_cpp_s = ', '.join(['0x%02x' % b for b in tdi_bytes]);
# return '0x%02x, { { %s } }' % (block['id'], tdi_cpp_s)
def __repr__(self):
return '\n'.join(self.lines)
def to_file(self, file_path):
f = open(file_path, 'w')
f.write(str(self))
f.close()
class HeaderGen(FileGen):
def __init__(self, includes, namespaces, type_name, variable_name):
self.lines = self.comment_header() \
+ self.includes(includes) \
+ self.namespaces_start(namespaces) \
+ self.verify_blocks_declaration(type_name, variable_name) \
+ self.namespaces_end(namespaces) \
+ ['']
class DataGen(FileGen):
def __init__(self, includes, namespaces, type_name, variable_name, verify_blocks):
self.lines = self.comment_header() \
+ self.includes(includes) \
+ self.namespaces_start(namespaces) \
+ self.verify_blocks_definition(type_name, variable_name, verify_blocks) \
+ self.namespaces_end(namespaces) \
+ ['']
# Tricky (a.k.a. "brittle") code to set DONE bit
for block in verify:
if block['id'] == 0x05:
block['tdo'] = program_done[0]['tdi']
# header_file_name = os.path.split(args.header_file_path)[1]
header_file_name = 'hackrf_cpld_data.hpp'
# header_includes = ('cpld_xilinx.hpp',)
data_includes = (header_file_name,)
type_name = '::cpld::xilinx::XC2C64A::verify_blocks_t'
# HeaderGen(header_includes, namespaces, type_name, variable_name).to_file(args.header_file_path)
DataGen(data_includes, namespaces, type_name, variable_name, verify).to_file(args.data_file_path)
2017-01-29 01:50:48 -05:00