#encoding=utf-8 import argparse import ast import intel_genxml import re import sys import copy import textwrap from util import * license = """/* * Copyright (C) 2016 Intel Corporation * * 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 * the rights to use, copy, modify, merge, publish, distribute, sublicense, * 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 NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS 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. */ """ pack_header = """%(license)s /* Instructions, enums and structures for %(platform)s. * * This file has been generated, do not hand edit. */ #ifndef %(guard)s #define %(guard)s #ifndef __OPENCL_VERSION__ #include #include "util/bitpack_helpers.h" #include "genX_helpers.h" #else #include "genX_cl_helpers.h" #endif """ def num_from_str(num_str): if num_str.lower().startswith('0x'): return int(num_str, base=16) assert not num_str.startswith('0'), 'octals numbers not allowed' return int(num_str) def bool_from_str(bool_str): options = { "true": True, "false": False } return options[bool_str]; class Field(object): ufixed_pattern = re.compile(r"u(\d+)\.(\d+)") sfixed_pattern = re.compile(r"s(\d+)\.(\d+)") def __init__(self, parser, attrs): self.parser = parser if "name" in attrs: self.name = safe_name(attrs["name"]) self.start = int(attrs["start"]) self.end = int(attrs["end"]) self.type = attrs["type"] self.nonzero = bool_from_str(attrs.get("nonzero", "false")) self.prefix = attrs["prefix"] if "prefix" in attrs else None assert self.start <= self.end, \ 'field {} has end ({}) < start ({})'.format(self.name, self.end, self.start) if self.type == 'bool': assert self.end == self.start, \ 'bool field ({}) is too wide'.format(self.name) if "default" in attrs: # Base 0 recognizes 0x, 0o, 0b prefixes in addition to decimal ints. self.default = int(attrs["default"], base=0) else: self.default = None ufixed_match = Field.ufixed_pattern.match(self.type) if ufixed_match: self.type = 'ufixed' self.fractional_size = int(ufixed_match.group(2)) sfixed_match = Field.sfixed_pattern.match(self.type) if sfixed_match: self.type = 'sfixed' self.fractional_size = int(sfixed_match.group(2)) def is_builtin_type(self): builtins = [ 'address', 'bool', 'float', 'ufixed', 'offset', 'sfixed', 'offset', 'int', 'uint', 'mbo', 'mbz' ] return self.type in builtins def is_struct_type(self): return self.type in self.parser.structs def is_enum_type(self): return self.type in self.parser.enums def emit_template_struct(self, dim): if self.type == 'address': type = 'uint64_t' if self.parser.opencl else '__gen_address_type' elif self.type == 'bool': type = 'bool' elif self.type == 'float': type = 'float' elif self.type == 'ufixed': type = 'float' elif self.type == 'sfixed': type = 'float' elif self.type == 'uint' and self.end - self.start > 32: type = 'uint64_t' elif self.type == 'offset': type = 'uint64_t' elif self.type == 'int': type = 'int32_t' elif self.type == 'uint': type = 'uint32_t' elif self.is_struct_type(): type = 'struct ' + self.parser.gen_prefix(safe_name(self.type)) elif self.is_enum_type(): type = 'enum ' + self.parser.gen_prefix(safe_name(self.type)) elif self.type == 'mbo' or self.type == 'mbz': return else: print("#error unhandled type: %s" % self.type) return print(" %-36s %s%s;" % (type, self.name, dim)) prefix = self.prefix + '_' if self.prefix else '' for value in self.values: name = value.name if self.prefix and value.name[0] == '_': name = name[1:] print("#define %-40s %d" % (prefix + name, value.value)) class Group(object): def __init__(self, parser, parent, start, count, size): self.parser = parser self.parent = parent self.start = start self.count = count self.size = size self.fields = [] def emit_template_struct(self, dim): if self.count == 0: print(" /* variable length fields follow */") else: if self.count > 1: dim = "%s[%d]" % (dim, self.count) for field in self.fields: field.emit_template_struct(dim) class DWord: def __init__(self): self.size = 32 self.fields = [] self.address = None def collect_dwords(self, dwords, start, dim): for field in self.fields: if isinstance(field, Group): if field.count == 1: field.collect_dwords(dwords, start + field.start, dim) else: for i in range(field.count): field.collect_dwords(dwords, start + field.start + i * field.size, "%s[%d]" % (dim, i)) continue index = (start + field.start) // 32 if not index in dwords: dwords[index] = self.DWord() clone = copy.copy(field) clone.start = clone.start + start clone.end = clone.end + start clone.dim = dim dwords[index].fields.append(clone) if field.type == "address": # assert dwords[index].address == None dwords[index].address = clone # Coalesce all the dwords covered by this field. The two cases we # handle are where multiple fields are in a 64 bit word (typically # and address and a few bits) or where a single struct field # completely covers multiple dwords. while index < (start + field.end) // 32: if index + 1 in dwords and not dwords[index] == dwords[index + 1]: dwords[index].fields.extend(dwords[index + 1].fields) dwords[index].size = 64 dwords[index + 1] = dwords[index] index = index + 1 def collect_dwords_and_length(self, repack=False): dwords = {} self.collect_dwords(dwords, 0, "") # Determine number of dwords in this group. If we have a size, use # that, since that'll account for MBZ dwords at the end of a group # (like dword 8 on BDW+ 3DSTATE_HS). Otherwise, use the largest dword # index we've seen plus one. if self.size > 0: length = self.size // 32 elif dwords: length = max(dwords.keys()) + 1 else: length = 0 return (dwords, length) def emit_pack_function(self, dwords, length, repack=False): for index in range(length): # Handle MBZ dwords if not index in dwords: print("") print(" dw[%d] = 0;" % index) continue # For 64 bit dwords, we aliased the two dword entries in the dword # dict it occupies. Now that we're emitting the pack function, # skip the duplicate entries. dw = dwords[index] if index > 0 and index - 1 in dwords and dw == dwords[index - 1]: continue # Special case: only one field and it's a struct at the beginning # of the dword. In this case we pack directly into the # destination. This is the only way we handle embedded structs # larger than 32 bits. if len(dw.fields) == 1: field = dw.fields[0] name = field.name + field.dim if field.is_struct_type() and field.start % 32 == 0: print("") if repack: if self.parser.opencl: print(" %s_repack(&dw[%d], &origin[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, index, name)) else: print(" %s_pack(data, &dw[%d], &origin[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, index, name)) else: if self.parser.opencl: print(" %s_pack(&dw[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, name)) else: print(" %s_pack(data, &dw[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, name)) continue # Pack any fields of struct type first so we have integer values # to the dword for those fields. field_index = 0 for field in dw.fields: if isinstance(field, Field) and field.is_struct_type(): name = field.name + field.dim print("") print(" uint32_t v%d_%d;" % (index, field_index)) if repack: if self.parser.opencl: print(" %s_repack(&v%d_%d, &origin[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, field_index, index, name)) else: print(" %s_repack(data, &v%d_%d, &origin[%d], &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, field_index, index, name)) else: if self.parser.opencl: print(" %s_pack(&v%d_%d, &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, field_index, name)) else: print(" %s_pack(data, &v%d_%d, &values->%s);" % (self.parser.gen_prefix(safe_name(field.type)), index, field_index, name)) field_index = field_index + 1 print("") dword_start = index * 32 if dw.address == None: address_count = 0 else: address_count = 1 # Assert in dont_use values for field in dw.fields: for value in field.values: if value.dont_use: print(" assert(values->%s != %s);" % (field.name, field.prefix + "_" + value.name)) if dw.size == 32 and dw.address == None: v = None print(" dw[%d] =" % index) elif len(dw.fields) > address_count or repack: v = "v%d" % index print(" const uint%d_t %s =" % (dw.size, v)) else: v = "0" field_index = 0 non_address_fields = [] if repack: non_address_fields.append("origin[%d]" % index) if dw.size > 32: non_address_fields.append("((uint64_t)origin[%d] << 32)" % (index + 1)) for field in dw.fields: if field.type != "mbo" and field.type != "mbz" and field.type != "repack": name = field.name + field.dim nz = "_nonzero" if field.nonzero else "" if field.type == "repack": non_address_fields.append("origin[%d]" % index) elif field.type == "mbo": non_address_fields.append("util_bitpack_ones(%d, %d)" % \ (field.start - dword_start, field.end - dword_start)) elif field.type == "mbz": assert not field.nonzero elif field.type == "address": pass elif field.type == "uint": non_address_fields.append("util_bitpack_uint%s(values->%s, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start)) elif field.is_enum_type(): non_address_fields.append("util_bitpack_uint%s(values->%s, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start)) elif field.type == "int": non_address_fields.append("util_bitpack_sint%s(values->%s, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start)) elif field.type == "bool": non_address_fields.append("util_bitpack_uint%s(values->%s, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start)) elif field.type == "float": non_address_fields.append("util_bitpack_float%s(values->%s)" % (nz, name)) elif field.type == "offset": non_address_fields.append("__gen_offset%s(values->%s, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start)) elif field.type == 'ufixed': non_address_fields.append("util_bitpack_ufixed%s(values->%s, %d, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start, field.fractional_size)) elif field.type == 'sfixed': non_address_fields.append("util_bitpack_sfixed%s(values->%s, %d, %d, %d)" % \ (nz, name, field.start - dword_start, field.end - dword_start, field.fractional_size)) elif field.is_struct_type(): non_address_fields.append("util_bitpack_uint(v%d_%d, %d, %d)" % \ (index, field_index, field.start - dword_start, field.end - dword_start)) field_index = field_index + 1 else: non_address_fields.append("/* unhandled field %s, type %s */\n" % \ (name, field.type)) if non_address_fields: print(" |\n".join(" " + f for f in non_address_fields) + ";") if dw.size == 32: if dw.address: if self.parser.opencl: print(" dw[%d] = __gen_address(values->%s, %d, %d) | %s;" % (index, dw.address.name + field.dim, dw.address.start - dword_start, dw.address.end - dword_start, v)) else: print(" dw[%d] = __gen_address(data, &dw[%d], values->%s, %s, %d, %d);" % (index, index, dw.address.name + field.dim, v, dw.address.start - dword_start, dw.address.end - dword_start)) continue if dw.address: v_address = "v%d_address" % index if self.parser.opencl: print(" const uint64_t %s =\n __gen_address(values->%s, %d, %d) | %s;" % (v_address, dw.address.name + field.dim, dw.address.start - dword_start, dw.address.end - dword_start, v)) else: print(" const uint64_t %s =\n __gen_address(data, &dw[%d], values->%s, %s, %d, %d);" % (v_address, index, dw.address.name + field.dim, v, dw.address.start - dword_start, dw.address.end - dword_start)) if len(dw.fields) > address_count: print(" dw[%d] = %s;" % (index, v_address)) print(" dw[%d] = (%s >> 32) | (%s >> 32);" % (index + 1, v_address, v)) continue else: v = v_address print(" dw[%d] = %s;" % (index, v)) print(" dw[%d] = %s >> 32;" % (index + 1, v)) class Value(object): def __init__(self, attrs): self.name = safe_name(attrs["name"]) self.value = ast.literal_eval(attrs["value"]) self.dont_use = int(attrs["dont_use"]) != 0 if "dont_use" in attrs else False class Parser(object): def __init__(self, opencl, repack): self.instruction = None self.structs = {} # Set of enum names we've seen. self.enums = set() self.registers = {} self.opencl = opencl self.repack = repack def gen_prefix(self, name): if name[0] == "_": return 'GFX%s%s' % (self.gen, name) return 'GFX%s_%s' % (self.gen, name) def gen_guard(self): if self.opencl: return self.gen_prefix("{0}_CL_PACK_H".format(self.platform)) return self.gen_prefix("{0}_PACK_H".format(self.platform)) def process_item(self, item): name = item.tag assert name != "genxml" attrs = item.attrib if name in ("instruction", "struct", "register"): if name == "instruction": self.instruction = safe_name(attrs["name"]) self.length_bias = int(attrs["bias"]) elif name == "struct": self.struct = safe_name(attrs["name"]) self.structs[attrs["name"]] = 1 elif name == "register": self.register = safe_name(attrs["name"]) self.reg_num = num_from_str(attrs["num"]) self.registers[attrs["name"]] = 1 if "length" in attrs: self.length = int(attrs["length"]) size = self.length * 32 else: self.length = None size = 0 self.group = Group(self, None, 0, 1, size) elif name == "group": group = Group(self, self.group, int(attrs["start"]), int(attrs["count"]), int(attrs["size"])) self.group.fields.append(group) self.group = group elif name == "field": self.group.fields.append(Field(self, attrs)) self.values = [] elif name == "enum": self.values = [] self.enum = safe_name(attrs["name"]) self.enums.add(attrs["name"]) if "prefix" in attrs: self.prefix = safe_name(attrs["prefix"]) else: self.prefix = None elif name == "value": self.values.append(Value(attrs)) elif name in ("import", "exclude"): pass else: assert False for child_item in item: self.process_item(child_item) if name == "instruction": self.emit_instruction() self.instruction = None self.group = None elif name == "struct": self.emit_struct() self.struct = None self.group = None elif name == "register": self.emit_register() self.register = None self.reg_num = None self.group = None elif name == "group": self.group = self.group.parent elif name == "field": self.group.fields[-1].values = self.values elif name == "enum": self.emit_enum() self.enum = None elif name in ("import", "exclude", "value"): pass else: assert False def emit_template_struct(self, name, group): print("struct %s {" % self.gen_prefix(name)) group.emit_template_struct("") print("};\n") def emit_pack_function(self, name, group, repack=False): name = self.gen_prefix(name) if repack: if self.opencl: print(textwrap.dedent("""\ static inline __attribute__((always_inline)) void %s_repack(__attribute__((unused)) global void * restrict dst, %s__attribute__((unused)) global const uint32_t * origin, %s__attribute__((unused)) private const struct %s * restrict values) {""") % (name, ' ' * len(name), ' ' * len(name), name)) else: print(textwrap.dedent("""\ static inline __attribute__((always_inline)) void %s_repack(__attribute__((unused)) __gen_user_data *data, %s__attribute__((unused)) void * restrict dst, %s__attribute__((unused)) global const uint32_t * origin, %s__attribute__((unused)) const struct %s * restrict values) {""") % (name, ' ' * len(name), ' ' * len(name), ' ' * len(name), name)) else: if self.opencl: print(textwrap.dedent("""\ static inline __attribute__((always_inline)) void %s_pack(__attribute__((unused)) global void * restrict dst, %s__attribute__((unused)) private const struct %s * restrict values) {""") % (name, ' ' * len(name), name)) else: print(textwrap.dedent("""\ static inline __attribute__((always_inline)) void %s_pack(__attribute__((unused)) __gen_user_data *data, %s__attribute__((unused)) void * restrict dst, %s__attribute__((unused)) const struct %s * restrict values) {""") % (name, ' ' * len(name), ' ' * len(name), name)) (dwords, length) = group.collect_dwords_and_length(repack) if length: # Cast dst to make header C++ friendly type_name = "global uint32_t *" if self.opencl else "uint32_t * restrict" print(" %s dw = (%s) dst;" % (type_name, type_name)) group.emit_pack_function(dwords, length, repack) print("}\n") def emit_instruction(self): name = self.instruction if not self.length is None: print('#define %-33s %6d' % (self.gen_prefix(name + "_length"), self.length)) print('#define %-33s %6d' % (self.gen_prefix(name + "_length_bias"), self.length_bias)) default_fields = [] for field in self.group.fields: if not isinstance(field, Field): continue if field.default is None: continue if field.is_builtin_type(): default_fields.append(" .%-35s = %6d" % (field.name, field.default)) else: # Default values should not apply to structures assert field.is_enum_type() default_fields.append(" .%-35s = (enum %s) %6d" % (field.name, self.gen_prefix(safe_name(field.type)), field.default)) if default_fields: print('#define %-40s\\' % (self.gen_prefix(name + '_header'))) print(", \\\n".join(default_fields)) print('') self.emit_template_struct(self.instruction, self.group) self.emit_pack_function(self.instruction, self.group) if self.repack: self.emit_pack_function(self.instruction, self.group, repack=True) def emit_register(self): name = self.register if not self.reg_num is None: print('#define %-33s 0x%04x' % (self.gen_prefix(name + "_num"), self.reg_num)) if not self.length is None: print('#define %-33s %6d' % (self.gen_prefix(name + "_length"), self.length)) self.emit_template_struct(self.register, self.group) self.emit_pack_function(self.register, self.group) def emit_struct(self): name = self.struct if not self.length is None: print('#define %-33s %6d' % (self.gen_prefix(name + "_length"), self.length)) self.emit_template_struct(self.struct, self.group) self.emit_pack_function(self.struct, self.group) if self.repack: self.emit_pack_function(self.struct, self.group, repack=True) def emit_enum(self): print('enum %s {' % self.gen_prefix(self.enum)) for value in self.values: if self.prefix: name = self.prefix + "_" + value.name else: name = value.name print(' %-36s = %6d,' % (name.upper(), value.value)) print('};\n') def emit_genxml(self, genxml): root = genxml.et.getroot() self.platform = root.attrib["name"] self.gen = root.attrib["gen"].replace('.', '') print(pack_header % {'license': license, 'platform': self.platform, 'guard': self.gen_guard()}) for item in root: self.process_item(item) print('#endif /* %s */' % self.gen_guard()) def parse_args(): p = argparse.ArgumentParser() p.add_argument('xml_source', metavar='XML_SOURCE', help="Input xml file") p.add_argument('--engines', nargs='?', type=str, default='render', help="Comma-separated list of engines whose instructions should be parsed (default: %(default)s)") p.add_argument('--include-symbols', nargs='?', type=str, action='store', help="List of instruction/structures to generate") p.add_argument('--opencl', action='store_true', help="Generate OpenCL code") p.add_argument('--repack', action='store_true', help="Emit repacking code") pargs = p.parse_args() if pargs.engines is None: print("No engines specified") sys.exit(1) return pargs def main(): pargs = parse_args() engines = set(pargs.engines.split(',')) valid_engines = [ 'render', 'blitter', 'video' ] if engines - set(valid_engines): print("Invalid engine specified, valid engines are:\n") for e in valid_engines: print("\t%s" % e) sys.exit(1) genxml = intel_genxml.GenXml(pargs.xml_source) genxml.merge_imported() genxml.filter_engines(engines) if pargs.include_symbols: genxml.filter_symbols(pargs.include_symbols.split(',')) p = Parser(pargs.opencl, pargs.repack) p.emit_genxml(genxml) if __name__ == '__main__': main()