#!/usr/bin/env python3 # SPDX-FileCopyrightText: © 2024 ZeldaRET # SPDX-License-Identifier: CC0-1.0 import argparse import collections from colorama import Fore, Style from dataclasses import dataclass import difflib import itertools import math from pathlib import Path import re import subprocess import sys import multiprocessing import multiprocessing.pool from typing import Dict, Iterator, List, Optional, Tuple def green(s: str) -> str: return f"{Fore.GREEN}{s}{Style.RESET_ALL}" def red(s: str) -> str: return f"{Fore.RED}{s}{Style.RESET_ALL}" # Make interrupting with ^C less jank # https://stackoverflow.com/questions/72967793/keyboardinterrupt-with-python-multiprocessing-pool def set_sigint_ignored(): import signal signal.signal(signal.SIGINT, signal.SIG_IGN) @dataclass class Inst: func_name: str mnemonic: str regs: List[str] imm: Optional[int] reloc_type: Optional[str] reloc_symbol: Optional[str] FUNC_RE = re.compile(r"([0-9a-f]+) <(.*)>:") def parse_func_name(line: str) -> str: match = FUNC_RE.match(line) if not match: raise Exception(f"could not parse function name from '{line}'") return match.group(2) def is_branch(mnemonic: str) -> bool: return mnemonic.startswith("b") and mnemonic != "break" def parse_inst(func_name: str, line: str) -> Inst: parts = line.split() addr = int(parts[0][:-1], 16) mnemonic = parts[2] regs = [] imm = None if len(parts) > 3: for part in parts[3].split(","): if "(" in part: # load/store offset_str, rest = part.split("(") regs.append(rest[:-1]) imm = int(offset_str, 10) elif is_branch(mnemonic): try: # convert branch targets to relative offsets offset = int(part, 16) imm = offset - addr - 4 except ValueError: regs.append(part) else: try: imm = int(part, 0) except ValueError: regs.append(part) return Inst(func_name, mnemonic, regs, imm, None, None) def run_objdump(path: Path, args: List[str]) -> str: if not path.exists(): raise Exception(f"file {path} does not exist") command = ["mips-linux-gnu-objdump"] + args + [str(path)] try: return subprocess.run( command, stdout=subprocess.PIPE, stderr=subprocess.PIPE, check=True, encoding="utf-8", ).stdout except subprocess.CalledProcessError as e: return "" def disassemble(path: Path) -> List[Inst]: lines = run_objdump(path, ["-drz", "-m", "mips:4300", "-j", ".text"]).splitlines() result = [] func_name = None i = 6 # skip preamble while i < len(lines): row = lines[i] i += 1 if not row: continue if not row.startswith(" "): func_name = parse_func_name(row) continue if not func_name: raise Exception(f"no function name for line '{row}'") inst = parse_inst(func_name, row) if i < len(lines) and lines[i].startswith("\t"): reloc = lines[i] i += 1 _, inst.reloc_type, inst.reloc_symbol = reloc.split() result.append(inst) # trim trailing nops while result and result[-1].mnemonic == "nop": result.pop() return result def pair_instructions( insts1: List[Inst], insts2: List[Inst] ) -> Iterator[Tuple[Optional[Inst], Optional[Inst]]]: differ = difflib.SequenceMatcher( a=[(inst.func_name, inst.mnemonic) for inst in insts1], b=[(inst.func_name, inst.mnemonic) for inst in insts2], autojunk=False, ) for tag, i1, i2, j1, j2 in differ.get_opcodes(): for inst1, inst2 in itertools.zip_longest(insts1[i1:i2], insts2[j1:j2]): yield (inst1, inst2) def has_diff(inst1: Inst, inst2: Inst) -> bool: if ( inst1.func_name != inst2.func_name or inst1.mnemonic != inst2.mnemonic or inst1.regs != inst2.regs ): return True if inst1.reloc_type == inst2.reloc_type and inst1.reloc_type in ( "R_MIPS_HI16", "R_MIPS_LO16", ): # ignore symbol differences return False return inst1 != inst2 def get_section_sizes(path: Path) -> Dict[str, int]: lines = run_objdump(path, ["-h"]).splitlines() if len(lines) < 5: return {} result = {} for i in range(5, len(lines), 2): parts = lines[i].split() name = parts[1] size = int(parts[2], 16) # Pad to 0x10-byte alignment result[parts[1]] = (size + 0xF) & ~0xF return result def get_section_hex_dump(path: Path, section: str) -> List[str]: lines = run_objdump(path, ["-s", "-j", section]).splitlines() return lines[4:] def parse_hex_dump(lines: List[str]) -> bytes: result = bytearray() for line in lines: data = line[6:41].replace(" ", "") result.extend(bytes.fromhex(data)) # pad to 0x10-byte alignment while len(result) % 0x10: result.append(0) return result def find_functions_with_diffs(version: str, c_path: str): object_path = Path(c_path).with_suffix(".o") expected_dir = Path("expected/build") / version build_dir = Path("build") / version insts1 = disassemble(expected_dir / object_path) insts2 = disassemble(build_dir / object_path) functions_with_diffs = collections.OrderedDict() for inst1, inst2 in pair_instructions(insts1, insts2): if inst1 is None and inst2 is not None: functions_with_diffs[inst2.func_name] = True elif inst1 is not None and inst2 is None: functions_with_diffs[inst1.func_name] = True elif inst1 is not None and inst2 is not None and has_diff(inst1, inst2): functions_with_diffs[inst1.func_name] = True functions_with_diffs[inst2.func_name] = True if not functions_with_diffs: print(f"{c_path} OK") return print(f"{c_path} functions with diffs:") for func_name in functions_with_diffs: print(f" {func_name}") def find_data_diffs(version: str, c_path: str): object_path = Path(c_path).with_suffix(".o") expected_dir = Path("expected/build") / version build_dir = Path("build") / version sizes1 = get_section_sizes(expected_dir / object_path) sizes2 = get_section_sizes(build_dir / object_path) rodata_dump1 = get_section_hex_dump(expected_dir / object_path, ".rodata") rodata_dump2 = get_section_hex_dump(build_dir / object_path, ".rodata") rodata1 = parse_hex_dump(rodata_dump1) rodata2 = parse_hex_dump(rodata_dump2) rodata_matches = rodata1 == rodata2 data_size_matches = sizes1.get(".data", 0) == sizes2.get(".data", 0) bss_size_matches = sizes1.get(".bss", 0) == sizes2.get(".bss", 0) if rodata_matches: print(f"{c_path} .rodata OK") else: print( f"{c_path} .rodata differs: expected size 0x{sizes1.get('.rodata', 0):04x} vs build size 0x{sizes2.get('.rodata', 0):04x}" ) print(f" expected:") print("\n".join(rodata_dump1)) print(f" build:") print("\n".join(rodata_dump2)) if data_size_matches: print(f"{c_path} .data size OK") else: print( f"{c_path} .data size differs: expected size 0x{sizes1.get('.data', 0):04x} vs build size 0x{sizes2.get('.data', 0):04x}" ) if bss_size_matches: print(f"{c_path} .bss size OK") else: print( f"{c_path} .bss size differs: expected size 0x{sizes1.get('.bss', 0):04x} vs build size 0x{sizes2.get('.bss', 0):04x}" ) @dataclass class ObjectDataForComparison: insts1: List[Inst] insts2: List[Inst] sizes1: Dict[str, int] sizes2: Dict[str, int] rodata1: bytes rodata2: bytes def get_object_data_for_comparison(object1: Path, object2: Path): insts1 = disassemble(object1) insts2 = disassemble(object2) sizes1 = get_section_sizes(object1) sizes2 = get_section_sizes(object2) rodata_dump1 = get_section_hex_dump(object1, ".rodata") rodata_dump2 = get_section_hex_dump(object2, ".rodata") rodata1 = parse_hex_dump(rodata_dump1) rodata2 = parse_hex_dump(rodata_dump2) return ObjectDataForComparison(insts1, insts2, sizes1, sizes2, rodata1, rodata2) def print_summary(version: str, csv: bool, only_not_ok: bool): expected_dir = Path("expected/build") / version build_dir = Path("build") / version expected_object_files = sorted(expected_dir.glob("src/**/*.o")) comparison_data_list: List[multiprocessing.pool.AsyncResult] = [] with multiprocessing.Pool(initializer=set_sigint_ignored) as p: for expected_object in expected_object_files: build_object = build_dir / expected_object.relative_to(expected_dir) comparison_data_list.append( p.apply_async( get_object_data_for_comparison, (expected_object, build_object), ) ) if csv: print("path,expected,actual,.text,.rodata,.data size,.bss size") for expected_object, data_async in zip( expected_object_files, comparison_data_list ): c_path = expected_object.relative_to(expected_dir).with_suffix(".c") data = data_async.get() insts1 = data.insts1 insts2 = data.insts2 added = 0 removed = 0 changed = 0 for inst1, inst2 in pair_instructions(insts1, insts2): if inst1 is None and inst2 is not None: added += 1 elif inst1 is not None and inst2 is None: removed += 1 elif inst1 is not None and inst2 is not None and has_diff(inst1, inst2): changed += 1 if insts1: text_progress = max(1.0 - (added + removed + changed) / len(insts1), 0) else: text_progress = 1.0 sizes1 = data.sizes1 sizes2 = data.sizes2 rodata1 = data.rodata1 rodata2 = data.rodata2 rodata_matches = rodata1 == rodata2 data_size_matches = sizes1.get(".data", 0) == sizes2.get(".data", 0) bss_size_matches = sizes1.get(".bss", 0) == sizes2.get(".bss", 0) if only_not_ok: if ( text_progress == 1 and rodata_matches and data_size_matches and bss_size_matches ): continue if csv: print( f"{c_path},{len(insts1)},{len(insts2)},{text_progress:.3f},{rodata_matches},{data_size_matches},{bss_size_matches}" ) else: ok = green("OK") diff = red("diff") text_progress_str = ( ok if text_progress == 1 else red(f"{math.floor(text_progress * 100):>2}%") ) rodata_str = ok if rodata_matches else diff data_size_str = ok if data_size_matches else diff bss_size_str = ok if bss_size_matches else diff print( f"text:{text_progress_str:<13} rodata:{rodata_str:<13} data size:{data_size_str:<13} bss size:{bss_size_str:<13} {c_path}" ) sys.stdout.flush() if __name__ == "__main__": parser = argparse.ArgumentParser(description="Calculate progress matching retail") parser.add_argument( "file", metavar="FILE", nargs="?", help="find functions with diffs in the given source file (if omitted, print summary of diffs for all files)", ) parser.add_argument( "-v", "--version", help="version to compare", default="gc-eu-mq" ) parser.add_argument( "--data", help="diff .data size, .bss size, and .rodata contents instead of text", action="store_true", ) parser.add_argument( "--not-ok", help="only print non-OK files", action="store_true", dest="only_not_ok", ) parser.add_argument("--csv", help="print summary CSV", action="store_true") args = parser.parse_args() if args.file is not None: if args.data: find_data_diffs(args.version, args.file) else: find_functions_with_diffs(args.version, args.file) else: print_summary(args.version, args.csv, args.only_not_ok)