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from __future__ import print_function, division, unicode_literals
CopyRight = '''
/*
* Copyright 2015-2019 Advanced Micro Devices, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* on the rights to use, copy, modify, merge, publish, distribute, sub
* license, and/or sell copies of the Software, and to permit persons to whom
* the Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL
* THE AUTHOR(S) AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM,
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
* OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
* USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*/
'''
from collections import defaultdict
import functools
import itertools
import json
import os.path
import re
import sys
AMD_REGISTERS = os.path.abspath(os.path.join(os.path.dirname(sys.argv[0]), "../registers"))
sys.path.append(AMD_REGISTERS)
from regdb import Object, RegisterDatabase
class StringTable:
"""
A class for collecting multiple strings in a single larger string that is
used by indexing (to avoid relocations in the resulting binary)
"""
def __init__(self):
self.table = []
self.length = 0
def add(self, string):
# We might get lucky with string being a suffix of a previously added string
for te in self.table:
if te[0].endswith(string):
idx = te[1] + len(te[0]) - len(string)
te[2].add(idx)
return idx
idx = self.length
self.table.append((string, idx, set((idx,))))
self.length += len(string) + 1
return idx
def emit(self, filp, name, static=True):
"""
Write
[static] const char name[] = "...";
to filp.
"""
fragments = [
'"%s\\0" /* %s */' % (
te[0].encode('unicode_escape').decode(),
', '.join(str(idx) for idx in sorted(te[2]))
)
for te in self.table
]
filp.write('%sconst char %s[] =\n%s;\n' % (
'static ' if static else '',
name,
'\n'.join('\t' + fragment for fragment in fragments)
))
class IntTable:
"""
A class for collecting multiple arrays of integers in a single big array
that is used by indexing (to avoid relocations in the resulting binary)
"""
def __init__(self, typename):
self.typename = typename
self.table = []
self.idxs = set()
def add(self, array):
# We might get lucky and find the array somewhere in the existing data
try:
idx = 0
while True:
idx = self.table.index(array[0], idx, len(self.table) - len(array) + 1)
for i in range(1, len(array)):
if array[i] != self.table[idx + i]:
break
else:
self.idxs.add(idx)
return idx
idx += 1
except ValueError:
pass
idx = len(self.table)
self.table += array
self.idxs.add(idx)
return idx
def emit(self, filp, name, static=True):
"""
Write
[static] const typename name[] = { ... };
to filp.
"""
idxs = sorted(self.idxs) + [len(self.table)]
fragments = [
('\t/* %s */ %s' % (
idxs[i],
' '.join((str(elt) + ',') for elt in self.table[idxs[i]:idxs[i+1]])
))
for i in range(len(idxs) - 1)
]
filp.write('%sconst %s %s[] = {\n%s\n};\n' % (
'static ' if static else '',
self.typename, name,
'\n'.join(fragments)
))
class Field:
def __init__(self, name, bits):
self.name = name
self.bits = bits # [first, last]
self.values = [] # [(name, value), ...]
def format(self, string_table, idx_table):
mask = ((1 << (self.bits[1] - self.bits[0] + 1)) - 1) << self.bits[0]
if len(self.values):
values_offsets = []
for value in self.values:
while value[1] >= len(values_offsets):
values_offsets.append(-1)
values_offsets[value[1]] = string_table.add(value[0])
return '{{{0}, 0x{mask:X}, {1}, {2}}}'.format(
string_table.add(self.name),
len(values_offsets), idx_table.add(values_offsets),
**locals()
)
else:
return '{{{0}, 0x{mask:X}}}'.format(string_table.add(self.name), **locals())
def __eq__(self, other):
return (self.name == other.name and
self.bits[0] == other.bits[0] and self.bits[1] == other.bits[1] and
len(self.values) == len(other.values) and
all(a[0] == b[0] and a[1] == b[1] for a, b, in zip(self.values, other.values)))
def __ne__(self, other):
return not (self == other)
class FieldTable:
"""
A class for collecting multiple arrays of register fields in a single big
array that is used by indexing (to avoid relocations in the resulting binary)
"""
def __init__(self):
self.table = []
self.idxs = set()
self.name_to_idx = defaultdict(lambda: [])
def add(self, array):
"""
Add an array of Field objects, and return the index of where to find
the array in the table.
"""
# Check if we can find the array in the table already
for base_idx in self.name_to_idx.get(array[0].name, []):
if base_idx + len(array) > len(self.table):
continue
for i, a in enumerate(array):
b = self.table[base_idx + i]
if a != b:
break
else:
return base_idx
base_idx = len(self.table)
self.idxs.add(base_idx)
for field in array:
self.name_to_idx[field.name].append(len(self.table))
self.table.append(field)
return base_idx
def emit(self, filp, string_table, idx_table):
"""
Write
static const struct si_field sid_fields_table[] = { ... };
to filp.
"""
idxs = sorted(self.idxs) + [len(self.table)]
filp.write('static const struct si_field sid_fields_table[] = {\n')
for start, end in zip(idxs, idxs[1:]):
filp.write('\t/* %s */\n' % (start))
for field in self.table[start:end]:
filp.write('\t%s,\n' % (field.format(string_table, idx_table)))
filp.write('};\n')
def parse_packet3(filp):
"""
Parse PKT3 commands from the given header file.
"""
packets = []
for line in filp:
if not line.startswith('#define '):
continue
line = line[8:].strip()
if line.startswith('PKT3_') and line.find('0x') != -1 and line.find('(') == -1:
packets.append(line.split()[0])
return packets
class TableWriter(object):
def __init__(self):
self.__strings = StringTable()
self.__strings_offsets = IntTable('int')
self.__fields = FieldTable()
def write(self, regdb, packets, file=sys.stdout):
def out(*args):
print(*args, file=file)
out('/* This file is autogenerated by sid_tables.py from sid.h. Do not edit directly. */')
out()
out(CopyRight.strip())
out('''
#ifndef SID_TABLES_H
#define SID_TABLES_H
struct si_field {
unsigned name_offset;
unsigned mask;
unsigned num_values;
unsigned values_offset; /* offset into sid_strings_offsets */
};
struct si_reg {
unsigned name_offset;
unsigned offset;
unsigned num_fields;
unsigned fields_offset;
};
struct si_packet3 {
unsigned name_offset;
unsigned op;
};
''')
out('static const struct si_packet3 packet3_table[] = {')
for pkt in packets:
out('\t{%s, %s},' % (self.__strings.add(pkt[5:]), pkt))
out('};')
out()
regmaps_by_chip = defaultdict(list)
for regmap in regdb.register_mappings():
for chip in regmap.chips:
regmaps_by_chip[chip].append(regmap)
regtypes = {}
# Sorted iteration over chips for deterministic builds
for chip in sorted(regmaps_by_chip.keys()):
regmaps = regmaps_by_chip[chip]
regmaps.sort(key=lambda regmap: (regmap.map.to, regmap.map.at))
out('static const struct si_reg {chip}_reg_table[] = {{'.format(**locals()))
for regmap in regmaps:
if hasattr(regmap, 'type_ref'):
if not regmap.type_ref in regtypes:
regtype = regdb.register_type(regmap.type_ref)
fields = []
for dbfield in regtype.fields:
field = Field(dbfield.name, dbfield.bits)
if hasattr(dbfield, 'enum_ref'):
enum = regdb.enum(dbfield.enum_ref)
for entry in enum.entries:
field.values.append((entry.name, entry.value))
fields.append(field)
num_fields = len(regtype.fields)
fields_offset = self.__fields.add(fields)
regtypes[regmap.type_ref] = (num_fields, fields_offset)
else:
num_fields, fields_offset = regtypes[regmap.type_ref]
print('\t{{{0}, {regmap.map.at}, {num_fields}, {fields_offset}}},'
.format(self.__strings.add(regmap.name), **locals()))
else:
print('\t{{{0}, {regmap.map.at}}},'
.format(self.__strings.add(regmap.name), **locals()))
out('};\n')
self.__fields.emit(file, self.__strings, self.__strings_offsets)
out()
self.__strings.emit(file, "sid_strings")
out()
self.__strings_offsets.emit(file, "sid_strings_offsets")
out()
out('#endif')
def main():
# Parse PKT3 types
with open(sys.argv[1], 'r') as filp:
packets = parse_packet3(filp)
# Register database parse
regdb = None
for filename in sys.argv[2:]:
with open(filename, 'r') as filp:
try:
db = RegisterDatabase.from_json(json.load(filp))
if regdb is None:
regdb = db
else:
regdb.update(db)
except json.JSONDecodeError as e:
print('Error reading {}'.format(sys.argv[1]), file=sys.stderr)
raise
# The ac_debug code only distinguishes by chip_class
regdb.merge_chips(['gfx8', 'fiji', 'stoney'], 'gfx8')
# Write it all out
w = TableWriter()
w.write(regdb, packets)
if __name__ == '__main__':
main()
# kate: space-indent on; indent-width 4; replace-tabs on;
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