"""Generate opcode metadata.
Reads the instruction definitions from bytecodes.c.
Writes the metadata to pycore_opcode_metadata.h by default.
"""
import argparse
from analyzer import (
Analysis,
Instruction,
PseudoInstruction,
analyze_files,
Uop,
)
from generators_common import (
DEFAULT_INPUT,
ROOT,
write_header,
cflags,
)
from cwriter import CWriter
from typing import TextIO
from stack import get_stack_effect
# Constants used instead of size for macro expansions.
# Note: 1, 2, 4 must match actual cache entry sizes.
OPARG_KINDS = {
"OPARG_FULL": 0,
"OPARG_CACHE_1": 1,
"OPARG_CACHE_2": 2,
"OPARG_CACHE_4": 4,
"OPARG_TOP": 5,
"OPARG_BOTTOM": 6,
"OPARG_SAVE_RETURN_OFFSET": 7,
# Skip 8 as the other powers of 2 are sizes
"OPARG_REPLACED": 9,
}
FLAGS = [
"ARG",
"CONST",
"NAME",
"JUMP",
"FREE",
"LOCAL",
"EVAL_BREAK",
"DEOPT",
"ERROR",
"ESCAPES",
"EXIT",
"PURE",
"PASSTHROUGH",
"OPARG_AND_1",
"ERROR_NO_POP",
]
def generate_flag_macros(out: CWriter) -> None:
for i, flag in enumerate(FLAGS):
out.emit(f"#define HAS_{flag}_FLAG ({1<<i})\n")
for i, flag in enumerate(FLAGS):
out.emit(
f"#define OPCODE_HAS_{flag}(OP) (_PyOpcode_opcode_metadata[OP].flags & (HAS_{flag}_FLAG))\n"
)
out.emit("\n")
def generate_oparg_macros(out: CWriter) -> None:
for name, value in OPARG_KINDS.items():
out.emit(f"#define {name} {value}\n")
out.emit("\n")
def emit_stack_effect_function(
out: CWriter, direction: str, data: list[tuple[str, str]]
) -> None:
out.emit(f"extern int _PyOpcode_num_{direction}(int opcode, int oparg);\n")
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit(f"int _PyOpcode_num_{direction}(int opcode, int oparg) {{\n")
out.emit("switch(opcode) {\n")
for name, effect in data:
out.emit(f"case {name}:\n")
out.emit(f" return {effect};\n")
out.emit("default:\n")
out.emit(" return -1;\n")
out.emit("}\n")
out.emit("}\n\n")
out.emit("#endif\n\n")
def generate_stack_effect_functions(analysis: Analysis, out: CWriter) -> None:
popped_data: list[tuple[str, str]] = []
pushed_data: list[tuple[str, str]] = []
def add(inst: Instruction | PseudoInstruction) -> None:
stack = get_stack_effect(inst)
popped = (-stack.base_offset).to_c()
pushed = (stack.top_offset - stack.base_offset).to_c()
popped_data.append((inst.name, popped))
pushed_data.append((inst.name, pushed))
for inst in analysis.instructions.values():
add(inst)
for pseudo in analysis.pseudos.values():
add(pseudo)
emit_stack_effect_function(out, "popped", sorted(popped_data))
emit_stack_effect_function(out, "pushed", sorted(pushed_data))
def generate_is_pseudo(analysis: Analysis, out: CWriter) -> None:
"""Write the IS_PSEUDO_INSTR macro"""
out.emit("\n\n#define IS_PSEUDO_INSTR(OP) ( \\\n")
for op in analysis.pseudos:
out.emit(f"((OP) == {op}) || \\\n")
out.emit("0")
out.emit(")\n\n")
def get_format(inst: Instruction) -> str:
if inst.properties.oparg:
format = "INSTR_FMT_IB"
else:
format = "INSTR_FMT_IX"
if inst.size > 1:
format += "C"
format += "0" * (inst.size - 2)
return format
def generate_instruction_formats(analysis: Analysis, out: CWriter) -> None:
# Compute the set of all instruction formats.
formats: set[str] = set()
for inst in analysis.instructions.values():
formats.add(get_format(inst))
# Generate an enum for it
out.emit("enum InstructionFormat {\n")
next_id = 1
for format in sorted(formats):
out.emit(f"{format} = {next_id},\n")
next_id += 1
out.emit("};\n\n")
def generate_deopt_table(analysis: Analysis, out: CWriter) -> None:
out.emit("extern const uint8_t _PyOpcode_Deopt[256];\n")
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit("const uint8_t _PyOpcode_Deopt[256] = {\n")
deopts: list[tuple[str, str]] = []
for inst in analysis.instructions.values():
deopt = inst.name
if inst.family is not None:
deopt = inst.family.name
deopts.append((inst.name, deopt))
for name, deopt in sorted(deopts):
out.emit(f"[{name}] = {deopt},\n")
out.emit("};\n\n")
out.emit("#endif // NEED_OPCODE_METADATA\n\n")
def generate_cache_table(analysis: Analysis, out: CWriter) -> None:
out.emit("extern const uint8_t _PyOpcode_Caches[256];\n")
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit("const uint8_t _PyOpcode_Caches[256] = {\n")
for inst in analysis.instructions.values():
if inst.family and inst.family.name != inst.name:
continue
if inst.name.startswith("INSTRUMENTED"):
continue
if inst.size > 1:
out.emit(f"[{inst.name}] = {inst.size-1},\n")
out.emit("};\n")
out.emit("#endif\n\n")
def generate_name_table(analysis: Analysis, out: CWriter) -> None:
table_size = 256 + len(analysis.pseudos)
out.emit(f"extern const char *_PyOpcode_OpName[{table_size}];\n")
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit(f"const char *_PyOpcode_OpName[{table_size}] = {{\n")
names = list(analysis.instructions) + list(analysis.pseudos)
for name in sorted(names):
out.emit(f'[{name}] = "{name}",\n')
out.emit("};\n")
out.emit("#endif\n\n")
def generate_metadata_table(analysis: Analysis, out: CWriter) -> None:
table_size = 256 + len(analysis.pseudos)
out.emit("struct opcode_metadata {\n")
out.emit("uint8_t valid_entry;\n")
out.emit("int8_t instr_format;\n")
out.emit("int16_t flags;\n")
out.emit("};\n\n")
out.emit(
f"extern const struct opcode_metadata _PyOpcode_opcode_metadata[{table_size}];\n"
)
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit(
f"const struct opcode_metadata _PyOpcode_opcode_metadata[{table_size}] = {{\n"
)
for inst in sorted(analysis.instructions.values(), key=lambda t: t.name):
out.emit(
f"[{inst.name}] = {{ true, {get_format(inst)}, {cflags(inst.properties)} }},\n"
)
for pseudo in sorted(analysis.pseudos.values(), key=lambda t: t.name):
flags = cflags(pseudo.properties)
for flag in pseudo.flags:
if flags == "0":
flags = f"{flag}_FLAG"
else:
flags += f" | {flag}_FLAG"
out.emit(f"[{pseudo.name}] = {{ true, -1, {flags} }},\n")
out.emit("};\n")
out.emit("#endif\n\n")
def generate_expansion_table(analysis: Analysis, out: CWriter) -> None:
expansions_table: dict[str, list[tuple[str, int, int]]] = {}
for inst in sorted(analysis.instructions.values(), key=lambda t: t.name):
offset: int = 0 # Cache effect offset
expansions: list[tuple[str, int, int]] = [] # [(name, size, offset), ...]
if inst.is_super():
pieces = inst.name.split("_")
assert len(pieces) == 4, f"{inst.name} doesn't look like a super-instr"
name1 = "_".join(pieces[:2])
name2 = "_".join(pieces[2:])
assert name1 in analysis.instructions, f"{name1} doesn't match any instr"
assert name2 in analysis.instructions, f"{name2} doesn't match any instr"
instr1 = analysis.instructions[name1]
instr2 = analysis.instructions[name2]
assert (
len(instr1.parts) == 1
), f"{name1} is not a good superinstruction part"
assert (
len(instr2.parts) == 1
), f"{name2} is not a good superinstruction part"
expansions.append((instr1.parts[0].name, OPARG_KINDS["OPARG_TOP"], 0))
expansions.append((instr2.parts[0].name, OPARG_KINDS["OPARG_BOTTOM"], 0))
elif not is_viable_expansion(inst):
continue
else:
for part in inst.parts:
size = part.size
if part.name == "_SAVE_RETURN_OFFSET":
size = OPARG_KINDS["OPARG_SAVE_RETURN_OFFSET"]
if isinstance(part, Uop):
# Skip specializations
if "specializing" in part.annotations:
continue
if "replaced" in part.annotations:
size = OPARG_KINDS["OPARG_REPLACED"]
expansions.append((part.name, size, offset if size else 0))
offset += part.size
expansions_table[inst.name] = expansions
max_uops = max(len(ex) for ex in expansions_table.values())
out.emit(f"#define MAX_UOP_PER_EXPANSION {max_uops}\n")
out.emit("struct opcode_macro_expansion {\n")
out.emit("int nuops;\n")
out.emit(
"struct { int16_t uop; int8_t size; int8_t offset; } uops[MAX_UOP_PER_EXPANSION];\n"
)
out.emit("};\n")
out.emit(
"extern const struct opcode_macro_expansion _PyOpcode_macro_expansion[256];\n\n"
)
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit("const struct opcode_macro_expansion\n")
out.emit("_PyOpcode_macro_expansion[256] = {\n")
for inst_name, expansions in expansions_table.items():
uops = [
f"{{ {name}, {size}, {offset} }}" for (name, size, offset) in expansions
]
out.emit(
f'[{inst_name}] = {{ .nuops = {len(expansions)}, .uops = {{ {", ".join(uops)} }} }},\n'
)
out.emit("};\n")
out.emit("#endif // NEED_OPCODE_METADATA\n\n")
def is_viable_expansion(inst: Instruction) -> bool:
"An instruction can be expanded if all its parts are viable for tier 2"
for part in inst.parts:
if isinstance(part, Uop):
# Skip specializing and replaced uops
if "specializing" in part.annotations:
continue
if "replaced" in part.annotations:
continue
if part.properties.tier == 1 or not part.is_viable():
return False
return True
def generate_extra_cases(analysis: Analysis, out: CWriter) -> None:
out.emit("#define EXTRA_CASES \\\n")
valid_opcodes = set(analysis.opmap.values())
for op in range(256):
if op not in valid_opcodes:
out.emit(f" case {op}: \\\n")
out.emit(" ;\n")
def generate_pseudo_targets(analysis: Analysis, out: CWriter) -> None:
table_size = len(analysis.pseudos)
max_targets = max(len(pseudo.targets) for pseudo in analysis.pseudos.values())
out.emit("struct pseudo_targets {\n")
out.emit(f"uint8_t targets[{max_targets + 1}];\n")
out.emit("};\n")
out.emit(
f"extern const struct pseudo_targets _PyOpcode_PseudoTargets[{table_size}];\n"
)
out.emit("#ifdef NEED_OPCODE_METADATA\n")
out.emit(
f"const struct pseudo_targets _PyOpcode_PseudoTargets[{table_size}] = {{\n"
)
for pseudo in analysis.pseudos.values():
targets = ["0"] * (max_targets + 1)
for i, target in enumerate(pseudo.targets):
targets[i] = target.name
out.emit(f"[{pseudo.name}-256] = {{ {{ {', '.join(targets)} }} }},\n")
out.emit("};\n\n")
out.emit("#endif // NEED_OPCODE_METADATA\n")
out.emit("static inline bool\n")
out.emit("is_pseudo_target(int pseudo, int target) {\n")
out.emit(f"if (pseudo < 256 || pseudo >= {256+table_size}) {{\n")
out.emit(f"return false;\n")
out.emit("}\n")
out.emit(
f"for (int i = 0; _PyOpcode_PseudoTargets[pseudo-256].targets[i]; i++) {{\n"
)
out.emit(
f"if (_PyOpcode_PseudoTargets[pseudo-256].targets[i] == target) return true;\n"
)
out.emit("}\n")
out.emit(f"return false;\n")
out.emit("}\n\n")
def generate_opcode_metadata(
filenames: list[str], analysis: Analysis, outfile: TextIO
) -> None:
write_header(__file__, filenames, outfile)
out = CWriter(outfile, 0, False)
with out.header_guard("Py_CORE_OPCODE_METADATA_H"):
out.emit("#ifndef Py_BUILD_CORE\n")
out.emit('# error "this header requires Py_BUILD_CORE define"\n')
out.emit("#endif\n\n")
out.emit("#include <stdbool.h> // bool\n")
out.emit('#include "opcode_ids.h"\n')
generate_is_pseudo(analysis, out)
out.emit('#include "pycore_uop_ids.h"\n')
generate_stack_effect_functions(analysis, out)
generate_instruction_formats(analysis, out)
table_size = 256 + len(analysis.pseudos)
out.emit("#define IS_VALID_OPCODE(OP) \\\n")
out.emit(f" (((OP) >= 0) && ((OP) < {table_size}) && \\\n")
out.emit(" (_PyOpcode_opcode_metadata[(OP)].valid_entry))\n\n")
generate_flag_macros(out)
generate_oparg_macros(out)
generate_metadata_table(analysis, out)
generate_expansion_table(analysis, out)
generate_name_table(analysis, out)
generate_cache_table(analysis, out)
generate_deopt_table(analysis, out)
generate_extra_cases(analysis, out)
generate_pseudo_targets(analysis, out)
arg_parser = argparse.ArgumentParser(
description="Generate the header file with opcode metadata.",
formatter_class=argparse.ArgumentDefaultsHelpFormatter,
)
DEFAULT_OUTPUT = ROOT / "Include/internal/pycore_opcode_metadata.h"
arg_parser.add_argument(
"-o", "--output", type=str, help="Generated code", default=DEFAULT_OUTPUT
)
arg_parser.add_argument(
"input", nargs=argparse.REMAINDER, help="Instruction definition file(s)"
)
if __name__ == "__main__":
args = arg_parser.parse_args()
if len(args.input) == 0:
args.input.append(DEFAULT_INPUT)
data = analyze_files(args.input)
with open(args.output, "w") as outfile:
generate_opcode_metadata(args.input, data, outfile)
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